Imaging Chemical Dynamics with Ultrafast Laser Spectroscopy
Lead Research Organisation:
University of Oxford
Department Name: Oxford Chemistry
Abstract
This programme reveals how molecules change on the femtosecond timescale and is motivated by the principle that chemical function depends on form. Observing structural dynamics during chemical reactions reveals information that can infer molecular behaviour or be used to synthesise new pharmaceuticals and catalysts. Such measurements conventionally use spectroscopy, which characterizes molecules according to the light they absorb at different frequencies. These 'fingerprint' spectra are observed over time to follow a reaction. However, molecules do not necessarily absorb light at easily accessible frequencies, meaning that important chemistry is often spectroscopically dark.
The emergence of a new technique in physics, Coulomb explosion imaging, opens the exciting possibility of investigating this dark chemistry directly. This method uses an intense and ultrafast laser pulse (35 fs) to quickly remove binding electrons from a molecule, leaving many positively charged sites that explode into fragments due to Coulomb's law. Measuring and correlating the relative velocities of these fragments as a function of time allows the shape of the molecule before the explosion to be reconstructed at different stages of a reaction.
This research will initiate photochemical reactions and probe their structural changes using Coulomb explosion imaging. Its key aim will be to observe complete reactions, particularly as they pass through short-lived structures, including intermediates and transition states that are of fundamental importance to controlling the reactivity of a molecule, and for predicting such behaviour computationally. This programme will also be the first to directly image spectroscopically dark biological photochemistry, and could reveal information on vital reactions, such as the stability of DNA with respect to UV light. Revealing this unknown chemistry will enable greater control of these mechanisms, leading to new light-driven chemistry or devices in the life and physical sciences.
The milestones outlined above will be reached through three projects. The first will develop a Coulomb explosion imaging experiment at the University of Oxford for the analysis of biomolecules isolated through electrospray ionisation. This will create a unique pathway to image structural biology that does not require crystallography, and which will be used as a starting point for investigating biomolecular dynamics. These will be investigated through the remaining two projects. One will develop a purpose-built tabletop instrument at Oxford to record 'molecular movies' of fundamental chemistry using time-resolved Coulomb explosion imaging. The final project will be undertaken using the FLASH free electron laser at the Deutsches Elektronen Synchrotron (DESY), which allows molecular structures to be site-selectively ionised. My group will collaborate with researchers at DESY to use this selectivity to study charge transport in nucleobases and aromatic amino acids, revealing new insights into their essential chemistry.
The emergence of a new technique in physics, Coulomb explosion imaging, opens the exciting possibility of investigating this dark chemistry directly. This method uses an intense and ultrafast laser pulse (35 fs) to quickly remove binding electrons from a molecule, leaving many positively charged sites that explode into fragments due to Coulomb's law. Measuring and correlating the relative velocities of these fragments as a function of time allows the shape of the molecule before the explosion to be reconstructed at different stages of a reaction.
This research will initiate photochemical reactions and probe their structural changes using Coulomb explosion imaging. Its key aim will be to observe complete reactions, particularly as they pass through short-lived structures, including intermediates and transition states that are of fundamental importance to controlling the reactivity of a molecule, and for predicting such behaviour computationally. This programme will also be the first to directly image spectroscopically dark biological photochemistry, and could reveal information on vital reactions, such as the stability of DNA with respect to UV light. Revealing this unknown chemistry will enable greater control of these mechanisms, leading to new light-driven chemistry or devices in the life and physical sciences.
The milestones outlined above will be reached through three projects. The first will develop a Coulomb explosion imaging experiment at the University of Oxford for the analysis of biomolecules isolated through electrospray ionisation. This will create a unique pathway to image structural biology that does not require crystallography, and which will be used as a starting point for investigating biomolecular dynamics. These will be investigated through the remaining two projects. One will develop a purpose-built tabletop instrument at Oxford to record 'molecular movies' of fundamental chemistry using time-resolved Coulomb explosion imaging. The final project will be undertaken using the FLASH free electron laser at the Deutsches Elektronen Synchrotron (DESY), which allows molecular structures to be site-selectively ionised. My group will collaborate with researchers at DESY to use this selectivity to study charge transport in nucleobases and aromatic amino acids, revealing new insights into their essential chemistry.
Planned Impact
Beyond academic impact, this programme will benefit the UK by developing intellectual property and high-quality personnel in the following areas, supporting the EPSRC's 'Productive nation' prosperity outcome.
1. Creating intellectual property: Mass spectrometers are versatile tools that mix different ionisation, analysis, and detection procedures to suit diverse applications. This programme will achieve technical and innovative leadership in each of these aspects by developing advanced methods for particle detection and universal initiation. These will foster partnerships with both academic and commercial researchers. For example, multi-mass ion imaging offers a high-throughput alternative for mass spectrometry surface analysis that could be used to rapidly analyse biomarkers in clinical samples. Intense and ultrafast laser pulses may also become a robust post-ionisation source for laser desorption or secondary ion mass spectrometry. To facilitate the uptake of these outcomes by end users, this programme will be supported by Oxford University Innovation (OUI), who help patent and commercialize Oxford-based intellectual property. This will ensure that patentable technologies created through this programme will be widely disseminated.
2. Developing high-quality researchers: As outlined above, the proposed research will initiate a new field at the forefront of mass spectrometry that incorporates state-of-the-art methods from chemistry and physics. A direct benefit will be the development of early stage researchers and postdoctoral research associates, providing a competitive pool of talented mass spectrometrists that will meet the needs of UK companies. During this fellowship, I will train at least two PDRAs in instrument design, computer assisted modeling, programming, data acquisition, and analysis. These broadly transferable skills will prepare them for roles in industry or academia. Planned collaborations with researchers at DESY and conference participation will also enhance the outlook and international profiles of the PDRAs, and will help prepare the next generation of independent scientists in the UK.
3. Benefits to the public: This programme will engage young students with contemporary and inventive research. 'Molecular movies' acquired using Coulomb explosion imaging provide a clear and easily understandable way to watch chemistry in action, and such movies can be combined with simple tools, such as molecular modeling kits or visual aids, to communicate the underlying science in a straightforward way. Based on public interest generated through an article published by this PI in Periodic, Oxford Chemistry's alumni magazine (circulation: 8,000), these outcomes will be publicised through animated video podcasts prepared in collaboration with Oxford Sparks, a public outreach project at the University of Oxford aimed at students in Key Stages 3-5 and supported by Oxford Chemistry's Outreach team.
1. Creating intellectual property: Mass spectrometers are versatile tools that mix different ionisation, analysis, and detection procedures to suit diverse applications. This programme will achieve technical and innovative leadership in each of these aspects by developing advanced methods for particle detection and universal initiation. These will foster partnerships with both academic and commercial researchers. For example, multi-mass ion imaging offers a high-throughput alternative for mass spectrometry surface analysis that could be used to rapidly analyse biomarkers in clinical samples. Intense and ultrafast laser pulses may also become a robust post-ionisation source for laser desorption or secondary ion mass spectrometry. To facilitate the uptake of these outcomes by end users, this programme will be supported by Oxford University Innovation (OUI), who help patent and commercialize Oxford-based intellectual property. This will ensure that patentable technologies created through this programme will be widely disseminated.
2. Developing high-quality researchers: As outlined above, the proposed research will initiate a new field at the forefront of mass spectrometry that incorporates state-of-the-art methods from chemistry and physics. A direct benefit will be the development of early stage researchers and postdoctoral research associates, providing a competitive pool of talented mass spectrometrists that will meet the needs of UK companies. During this fellowship, I will train at least two PDRAs in instrument design, computer assisted modeling, programming, data acquisition, and analysis. These broadly transferable skills will prepare them for roles in industry or academia. Planned collaborations with researchers at DESY and conference participation will also enhance the outlook and international profiles of the PDRAs, and will help prepare the next generation of independent scientists in the UK.
3. Benefits to the public: This programme will engage young students with contemporary and inventive research. 'Molecular movies' acquired using Coulomb explosion imaging provide a clear and easily understandable way to watch chemistry in action, and such movies can be combined with simple tools, such as molecular modeling kits or visual aids, to communicate the underlying science in a straightforward way. Based on public interest generated through an article published by this PI in Periodic, Oxford Chemistry's alumni magazine (circulation: 8,000), these outcomes will be publicised through animated video podcasts prepared in collaboration with Oxford Sparks, a public outreach project at the University of Oxford aimed at students in Key Stages 3-5 and supported by Oxford Chemistry's Outreach team.
Organisations
- University of Oxford (Fellow, Lead Research Organisation)
- University of Hyogo (Collaboration)
- Deutsches Electronen-Synchrotron (DESY) (Collaboration)
- Stony Brook University (Collaboration)
- Tokyo University of Agriculture (Collaboration)
- University of Kyoto (Collaboration)
- University of Ottawa (Collaboration)
- DIAMOND LIGHT SOURCE (Collaboration)
- National Research Council Canada (Collaboration)
- Goethe University Frankfurt (Collaboration)
- Stanford University (Collaboration)
- Brown University (Collaboration)
- Tokyo University of Agriculture and Technology (Collaboration)
- UNIVERSITY OF SOUTHAMPTON (Collaboration)
- University of Bristol (Collaboration)
- Hiroshima University (Collaboration)
- Aarhus University (Collaboration)
- University College London (Collaboration)
- European XFEL (Collaboration)
- University of Nebraska-Lincoln (Collaboration)
- Nagoya University (Collaboration)
- ShanghaiTech University (Collaboration)
- University of Turku (Collaboration)
- UNIVERSITY OF OXFORD (Collaboration)
- National Institutes of Natural Sciences (Collaboration)
- Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy; Research Network Berlin (Collaboration)
- Japan Synchrotron Radiation Research Institute RIKEN (Collaboration)
- Lund University (Collaboration)
- Daikin Industries, Ltd (Collaboration)
- Kansas State University (Collaboration)
- National Institutes for Quantum and Radiological Science and Technology (Collaboration)
- Daresbury Laboratory (Collaboration)
- Tohoku University (Collaboration)
- German Elektronen Synchrotron (DESY) (Project Partner)
Publications
Allum F
(2022)
A localized view on molecular dissociation via electron-ion partial covariance.
in Communications chemistry
Walmsley T
(2023)
Characterizing the multi-dimensional reaction dynamics of dihalomethanes using XUV-induced Coulomb explosion imaging
in The Journal of Chemical Physics
Allum F
(2023)
Direct momentum imaging of charge transfer following site-selective ionization
in Physical Review A
McManus JW
(2022)
Disentangling sequential and concerted fragmentations of molecular polycations with covariant native frame analysis.
in Physical chemistry chemical physics : PCCP
Garg D
(2022)
Fragmentation Dynamics of Fluorene Explored Using Ultrafast XUV-Vis Pump-Probe Spectroscopy
in Frontiers in Physics
Guo A
(2020)
High-Resolution Ion Microscope Imaging over Wide Mass Ranges Using Electrodynamic Postextraction Differential Acceleration.
in Journal of the American Society for Mass Spectrometry
Wood D
(2022)
Ion Microscope Imaging Mass Spectrometry Using a Timepix3-Based Optical Camera.
in Journal of the American Society for Mass Spectrometry
Allum F
(2022)
Photoionization and Photofragmentation Dynamics of I2 in Intense Laser Fields: A Velocity-Map Imaging Study.
in The journal of physical chemistry. A
Allum F
(2020)
Post extraction inversion slice imaging for 3D velocity map imaging experiments
in Molecular Physics
Minion L
(2022)
Predicting Coulomb explosion fragment angular distributions using molecular ground-state vibrational motion.
in Physical chemistry chemical physics : PCCP
Lee JWL
(2022)
The kinetic energy of PAH dication and trication dissociation determined by recoil-frame covariance map imaging.
in Physical chemistry chemical physics : PCCP
Lee JWL
(2021)
Time-resolved relaxation and fragmentation of polycyclic aromatic hydrocarbons investigated in the ultrafast XUV-IR regime.
in Nature communications
Forbes R
(2020)
Time-resolved site-selective imaging of predissociation and charge transfer dynamics: the CH 3 I B-band
in Journal of Physics B: Atomic, Molecular and Optical Physics
Gabalski I
(2023)
Time-Resolved X-ray Photoelectron Spectroscopy: Ultrafast Dynamics in CS2 Probed at the S 2p Edge.
in The journal of physical chemistry letters
Pickering
(2021)
Ultrafast Lasers and Optics for Experimentalists
Köckert H
(2022)
UV-induced dissociation of CH 2 BrI probed by intense femtosecond XUV pulses
in Journal of Physics B: Atomic, Molecular and Optical Physics
Unwin J
(2023)
X-ray induced Coulomb explosion imaging of transient excited-state structural rearrangements in CS2
in Communications Physics
Description | This programme is ongoing. We have so far constructed an imaging mass spectrometer to record 'ultrafast' chemical dynamics with timing precisions of about 50 fs. This is the same timescale at which chemical bonds break and form and will allow us to probe fundamental reactions in new ways. A key aspect of our research is the development of Coulomb explosion imaging mass spectrometry, both in our lab and at international facilities such as the FLASH and SACLA free electron lasers. Coulomb explosions allow molecules to be ionized more easily and hence provide a new approach to studying reaction dynamics that are otherwise difficult to observe, such as the biochemistry of vital reactions. This research therefore has the potential to greatly impact our understanding of these areas. |
Exploitation Route | The methodology and outcomes we are delivering are helping to establish the limitations of Coulomb explosion imaging mass spectrometry as a chemical dynamics tool. These include the size of the molecules that can be studied, methods for extracting quantitative results, and the importance of stable experimental conditions. These will all be put to use in future experiments, including those at competitive beamtimes at free electron laser facilities. More generally, these outcomes will also help to observe the changing structures of molecular isomers as a function of time. As inferring molecular function from shape is a guiding principle of chemical activity, evaluating these structural dynamics for complex natural systems could potentially benefit the design of catalysts, pharmaceuticals, and other chemical devices. |
Sectors | Chemicals,Energy,Environment,Manufacturing, including Industrial Biotechology |
Description | (CALIPSOplus) - Convenient Access to Light Sources Open to Innovation, Science and to the World - FLASH (2019-08-18 to 2019-08-26) |
Amount | € 2,969 (EUR) |
Funding ID | 730872, FLASH: F-20181206 EC |
Organisation | European Commission H2020 |
Sector | Public |
Country | Belgium |
Start | 07/2019 |
End | 08/2019 |
Description | Coulomb Explosion Imaging of Metal Ion-Ligand Clusters |
Amount | £19,842 (GBP) |
Funding ID | RGS/R2/212360 |
Organisation | The Royal Society |
Sector | Charity/Non Profit |
Country | United Kingdom |
Start | 11/2021 |
End | 11/2022 |
Description | Covid-19 Rebuilding Research Momentum Fund - Developing a user facility at the SACLA free electron laser |
Amount | £2,600 (GBP) |
Funding ID | 0011012 |
Organisation | University of Oxford |
Sector | Academic/University |
Country | United Kingdom |
Start | 08/2021 |
End | 02/2023 |
Description | Department of Chemistry - Exceptional Strategic Fund |
Amount | £2,406 (GBP) |
Organisation | University of Oxford |
Sector | Academic/University |
Country | United Kingdom |
Start | 03/2021 |
End | 04/2021 |
Description | Isomerisation of gas-phase structures with Coulomb explosion imaging. |
Amount | £69,897 (GBP) |
Funding ID | 2446334 |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 10/2020 |
End | 09/2023 |
Description | Jersey Postgraduate Bursary |
Amount | £18,000 (GBP) |
Organisation | Government of Jersey |
Sector | Public |
Country | Jersey |
Start | 10/2020 |
End | 09/2023 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | Aarhus University |
Country | Denmark |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | Brown University |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | Deutsches Electronen-Synchrotron (DESY) |
Country | Germany |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | Diamond Light Source |
Country | United Kingdom |
Sector | Private |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | European XFEL |
Country | Germany |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | Goethe University Frankfurt |
Country | Germany |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy; Research Network Berlin |
Country | Germany |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | Stanford University |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | University College London |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | University of Bristol |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | University of Nebraska-Lincoln |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | European XFEL Beamtime 2979 - Direct visualization of nuclear motion in thiophenone during and after ring opening |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite beamtime support at the Small Quantum Systems beamline at the European XFEL; responsible for data collection and instrument handling. |
Collaborator Contribution | Researchers from Kansas State University and the European XFEL were responsible for beamtime organization and instrumentation (PIs. D. Rolles, KSU; R. Boll, European XFEL). They were supported onsite by researchers from Oxford, Stanford, Frankfurt, DESY, and UCL. The remaining groups provided remote input. Students at KSU are now leading the data analysis with support from members of the collaboration. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | FLASH Beamtime F-20181206 EC - Imaging ultrafast photodynamics using site-selective X-ray ionization |
Organisation | Deutsches Electronen-Synchrotron (DESY) |
Country | Germany |
Sector | Academic/University |
PI Contribution | Principal investigator of a competitive beamtime at the FLASH free electron laser at DESY; lead author of the research proposal; responsible for overall research direction, data analysis, and publications. |
Collaborator Contribution | Stanford University - data analysis and publication preparation, ultrafast laser expertise. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor, mass spectrometer expertise, data analysis and publication preparation. |
Impact | R. Forbes et al., Journal of Physics B: Atomic, Molecular and Optical Physics (2020), 53, 224001; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2019 |
Description | FLASH Beamtime F-20181206 EC - Imaging ultrafast photodynamics using site-selective X-ray ionization |
Organisation | European XFEL |
Country | Germany |
Sector | Academic/University |
PI Contribution | Principal investigator of a competitive beamtime at the FLASH free electron laser at DESY; lead author of the research proposal; responsible for overall research direction, data analysis, and publications. |
Collaborator Contribution | Stanford University - data analysis and publication preparation, ultrafast laser expertise. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor, mass spectrometer expertise, data analysis and publication preparation. |
Impact | R. Forbes et al., Journal of Physics B: Atomic, Molecular and Optical Physics (2020), 53, 224001; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2019 |
Description | FLASH Beamtime F-20181206 EC - Imaging ultrafast photodynamics using site-selective X-ray ionization |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Principal investigator of a competitive beamtime at the FLASH free electron laser at DESY; lead author of the research proposal; responsible for overall research direction, data analysis, and publications. |
Collaborator Contribution | Stanford University - data analysis and publication preparation, ultrafast laser expertise. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor, mass spectrometer expertise, data analysis and publication preparation. |
Impact | R. Forbes et al., Journal of Physics B: Atomic, Molecular and Optical Physics (2020), 53, 224001; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2019 |
Description | FLASH Beamtime F-20181206 EC - Imaging ultrafast photodynamics using site-selective X-ray ionization |
Organisation | Lund University |
Country | Sweden |
Sector | Academic/University |
PI Contribution | Principal investigator of a competitive beamtime at the FLASH free electron laser at DESY; lead author of the research proposal; responsible for overall research direction, data analysis, and publications. |
Collaborator Contribution | Stanford University - data analysis and publication preparation, ultrafast laser expertise. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor, mass spectrometer expertise, data analysis and publication preparation. |
Impact | R. Forbes et al., Journal of Physics B: Atomic, Molecular and Optical Physics (2020), 53, 224001; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2019 |
Description | FLASH Beamtime F-20181206 EC - Imaging ultrafast photodynamics using site-selective X-ray ionization |
Organisation | Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy; Research Network Berlin |
Country | Germany |
Sector | Academic/University |
PI Contribution | Principal investigator of a competitive beamtime at the FLASH free electron laser at DESY; lead author of the research proposal; responsible for overall research direction, data analysis, and publications. |
Collaborator Contribution | Stanford University - data analysis and publication preparation, ultrafast laser expertise. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor, mass spectrometer expertise, data analysis and publication preparation. |
Impact | R. Forbes et al., Journal of Physics B: Atomic, Molecular and Optical Physics (2020), 53, 224001; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2019 |
Description | FLASH Beamtime F-20181206 EC - Imaging ultrafast photodynamics using site-selective X-ray ionization |
Organisation | Stanford University |
Country | United States |
Sector | Academic/University |
PI Contribution | Principal investigator of a competitive beamtime at the FLASH free electron laser at DESY; lead author of the research proposal; responsible for overall research direction, data analysis, and publications. |
Collaborator Contribution | Stanford University - data analysis and publication preparation, ultrafast laser expertise. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor, mass spectrometer expertise, data analysis and publication preparation. |
Impact | R. Forbes et al., Journal of Physics B: Atomic, Molecular and Optical Physics (2020), 53, 224001; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2019 |
Description | FLASH Beamtime F-20181206 EC - Imaging ultrafast photodynamics using site-selective X-ray ionization |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Principal investigator of a competitive beamtime at the FLASH free electron laser at DESY; lead author of the research proposal; responsible for overall research direction, data analysis, and publications. |
Collaborator Contribution | Stanford University - data analysis and publication preparation, ultrafast laser expertise. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor, mass spectrometer expertise, data analysis and publication preparation. |
Impact | R. Forbes et al., Journal of Physics B: Atomic, Molecular and Optical Physics (2020), 53, 224001; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2019 |
Description | FLASH Beamtime F-20191568 - Fragmentation dynamics of 1D and 2D polycyclic aromatic hydrocarbons |
Organisation | Deutsches Electronen-Synchrotron (DESY) |
Country | Germany |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning and data analysis. |
Collaborator Contribution | Deutsches Electronen-Synchrotron - data analysis and publication preparation, ultrafast laser expertise, beamline staff scientist time, instrumentation, access to FLASH, data acquisition, computational resources. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise, instrumentation. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor. |
Impact | D. Garg et al. Frontiers in Physics (2022), 10; further publications expected in 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20191568 - Fragmentation dynamics of 1D and 2D polycyclic aromatic hydrocarbons |
Organisation | European XFEL |
Country | Germany |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning and data analysis. |
Collaborator Contribution | Deutsches Electronen-Synchrotron - data analysis and publication preparation, ultrafast laser expertise, beamline staff scientist time, instrumentation, access to FLASH, data acquisition, computational resources. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise, instrumentation. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor. |
Impact | D. Garg et al. Frontiers in Physics (2022), 10; further publications expected in 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20191568 - Fragmentation dynamics of 1D and 2D polycyclic aromatic hydrocarbons |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning and data analysis. |
Collaborator Contribution | Deutsches Electronen-Synchrotron - data analysis and publication preparation, ultrafast laser expertise, beamline staff scientist time, instrumentation, access to FLASH, data acquisition, computational resources. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise, instrumentation. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor. |
Impact | D. Garg et al. Frontiers in Physics (2022), 10; further publications expected in 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20191568 - Fragmentation dynamics of 1D and 2D polycyclic aromatic hydrocarbons |
Organisation | Lund University |
Country | Sweden |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning and data analysis. |
Collaborator Contribution | Deutsches Electronen-Synchrotron - data analysis and publication preparation, ultrafast laser expertise, beamline staff scientist time, instrumentation, access to FLASH, data acquisition, computational resources. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise, instrumentation. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor. |
Impact | D. Garg et al. Frontiers in Physics (2022), 10; further publications expected in 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20191568 - Fragmentation dynamics of 1D and 2D polycyclic aromatic hydrocarbons |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning and data analysis. |
Collaborator Contribution | Deutsches Electronen-Synchrotron - data analysis and publication preparation, ultrafast laser expertise, beamline staff scientist time, instrumentation, access to FLASH, data acquisition, computational resources. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Lund University - mass spectrometer expertise, instrumentation. Max Born Institute - ultrafast laser expertise. University of Oxford - mass spectrometry imaging sensor. |
Impact | D. Garg et al. Frontiers in Physics (2022), 10; further publications expected in 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | Daresbury Laboratory |
Country | United Kingdom |
Sector | Private |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | Deutsches Electronen-Synchrotron (DESY) |
Country | Germany |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | European XFEL |
Country | Germany |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy; Research Network Berlin |
Country | Germany |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | National Research Council of Canada |
Country | Canada |
Sector | Public |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | Stanford University |
Department | SLAC National Accelerator Laboratory |
Country | United States |
Sector | Public |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | University of Ottawa |
Country | Canada |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20200773 - The sensitivity of inner-shell photoelectron spectroscopy to non-Born-Oppenheimer and photodissociation dynamics in polyatomic molecules |
Organisation | University of Southampton |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for FLASH BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | Stanford University - lead investigators, project planning, data analysis and publication preparation. Deutsches Electronen-Synchrotron - beamline staff scientist time, instrumentation, access to FLASH, data acquisition, ultrafast laser expertise, computational resources, publication contributions. European XFEL - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Kansas State University - ultrafast laser expertise, mass spectrometer expertise, publication contributions. Max Born Institute - ultrafast laser expertise. Daresbury Laboratory - data interpretation. University of Southampton - ultrafast laser expertise, data analysis and interpretation. University of Oxford - mass spectrometer expertise, data analysis and publication preparation. Max Born Institute - ultrafast laser and mass spectrometer expertise. University of Ottawa/NRC Ottawa - project planning and data interpretation. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | FLASH Beamtime F-20211752 - Exploring the stability of triply and quadruply charged polycyclic aromatic hydrocarbons |
Organisation | Deutsches Electronen-Synchrotron (DESY) |
Country | Germany |
Sector | Academic/University |
PI Contribution | Onsite and remote beamtime support for FLASH BL1; including beamtime planning, instrument installation, and data analysis. |
Collaborator Contribution | The beamtime was organized by researchers from DESY (PIs. J. Lee and M. Schnell). Instrumentation was provided by staff scientists at DESY as well as by researchers from Oxford and Lund. KSU supported the project remotely with ultrafast laser expertise. Data analysis and publication preparation is now being pushed forward in a collaboration between Oxford and DESY. |
Impact | Data analysis has only just begun, following the end of the beamtime in February 2023. Early results are promising and we anticipate two publications during 2024-2025. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2023 |
Description | FLASH Beamtime F-20211752 - Exploring the stability of triply and quadruply charged polycyclic aromatic hydrocarbons |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite and remote beamtime support for FLASH BL1; including beamtime planning, instrument installation, and data analysis. |
Collaborator Contribution | The beamtime was organized by researchers from DESY (PIs. J. Lee and M. Schnell). Instrumentation was provided by staff scientists at DESY as well as by researchers from Oxford and Lund. KSU supported the project remotely with ultrafast laser expertise. Data analysis and publication preparation is now being pushed forward in a collaboration between Oxford and DESY. |
Impact | Data analysis has only just begun, following the end of the beamtime in February 2023. Early results are promising and we anticipate two publications during 2024-2025. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2023 |
Description | FLASH Beamtime F-20211752 - Exploring the stability of triply and quadruply charged polycyclic aromatic hydrocarbons |
Organisation | Lund University |
Country | Sweden |
Sector | Academic/University |
PI Contribution | Onsite and remote beamtime support for FLASH BL1; including beamtime planning, instrument installation, and data analysis. |
Collaborator Contribution | The beamtime was organized by researchers from DESY (PIs. J. Lee and M. Schnell). Instrumentation was provided by staff scientists at DESY as well as by researchers from Oxford and Lund. KSU supported the project remotely with ultrafast laser expertise. Data analysis and publication preparation is now being pushed forward in a collaboration between Oxford and DESY. |
Impact | Data analysis has only just begun, following the end of the beamtime in February 2023. Early results are promising and we anticipate two publications during 2024-2025. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2023 |
Description | FLASH Beamtime F-20211752 - Exploring the stability of triply and quadruply charged polycyclic aromatic hydrocarbons |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite and remote beamtime support for FLASH BL1; including beamtime planning, instrument installation, and data analysis. |
Collaborator Contribution | The beamtime was organized by researchers from DESY (PIs. J. Lee and M. Schnell). Instrumentation was provided by staff scientists at DESY as well as by researchers from Oxford and Lund. KSU supported the project remotely with ultrafast laser expertise. Data analysis and publication preparation is now being pushed forward in a collaboration between Oxford and DESY. |
Impact | Data analysis has only just begun, following the end of the beamtime in February 2023. Early results are promising and we anticipate two publications during 2024-2025. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2023 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | Daikin Industries, Ltd |
Country | Japan |
Sector | Private |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | Goethe University Frankfurt |
Country | Germany |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | Japan Synchrotron Radiation Research Institute RIKEN |
Department | SPring-8 |
Country | Japan |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | National Institutes for Quantum and Radiological Science and Technology |
Country | Japan |
Sector | Public |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | National Institutes of Natural Sciences |
Department | UVSOR Synchrotron Facility |
Country | Japan |
Sector | Public |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | ShanghaiTech University |
Country | China |
Sector | Hospitals |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | Stanford University |
Country | United States |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | Tohoku University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | University of Kyoto |
Country | Japan |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | University of Southampton |
Department | Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8054 - Time-resolved Coulomb explosion imaging following core-level photoionization in disubstituted methane molecules |
Organisation | University of Turku |
Country | Finland |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and the University of Turku were responsible for beamtime organization and instrumentation (PI. K. Ueda, Tohoku University). Daikin provided proprietary fluorocarbon samples to be used as target molecules for the experiment. Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | Data analysis is ongoing with publications expected in the short term. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | Goethe University Frankfurt |
Country | Germany |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | Japan Synchrotron Radiation Research Institute RIKEN |
Department | SPring-8 |
Country | Japan |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | National Institutes of Natural Sciences |
Department | UVSOR Synchrotron Facility |
Country | Japan |
Sector | Public |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | ShanghaiTech University |
Country | China |
Sector | Hospitals |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | Stanford University |
Country | United States |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | Tohoku University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | University of Kyoto |
Country | Japan |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | University of Southampton |
Department | Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2019B8063 - Time resolved Coulomb explosion imaging of multi-channel non-adiabatic photodissociation dynamics in iodomethane and iodobenzene |
Organisation | University of Turku |
Country | Finland |
Sector | Academic/University |
PI Contribution | Interfacing a mass spectrometry imaging sensor with instrumentation at the SACLA free electron laser (SACLA BL1); beamtime planning; data acquisition and analysis. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). Stanford University and Kansas State University provided ultrafast laser expertise and beamtime experience. Oxford provided access to a state-of-the-art mass spectrometry imaging sensor, as well as technical support in interfacing it with the SACLA instrumentation. SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. |
Impact | F. Allum et al., Faraday Discussions (2021), 228, 571; further publications expected. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2020 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | Deutsches Electronen-Synchrotron (DESY) |
Country | Germany |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | Japan Synchrotron Radiation Research Institute RIKEN |
Department | SPring-8 |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | National Institutes for Quantum and Radiological Science and Technology |
Country | Japan |
Sector | Public |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | National Institutes of Natural Sciences |
Department | UVSOR Synchrotron Facility |
Country | Japan |
Sector | Public |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | Stanford University |
Department | SLAC National Accelerator Laboratory |
Country | United States |
Sector | Public |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | Tohoku University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | University of Bristol |
Department | School of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | University of Kyoto |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | University of Southampton |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021A8038 - Time-resolved Coulomb explosion imaging of the competition between ring-opening and direct dissociation in halo-cyclopropanes |
Organisation | University of Turku |
Country | Finland |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton and Stanford are now leading the data analysis. |
Impact | J. McManus et al., Physical Chemistry Chemical Physics (2022), 24, 22699; further publications expected in 2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | Deutsches Electronen-Synchrotron (DESY) |
Country | Germany |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | Japan Synchrotron Radiation Research Institute RIKEN |
Department | SPring-8 |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | National Institutes for Quantum and Radiological Science and Technology |
Country | Japan |
Sector | Public |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | National Institutes of Natural Sciences |
Department | UVSOR Synchrotron Facility |
Country | Japan |
Sector | Public |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | Stanford University |
Department | SLAC National Accelerator Laboratory |
Country | United States |
Sector | Public |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | Stony Brook University |
Country | United States |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | Tohoku University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | University of Bristol |
Department | School of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | University of Kyoto |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | University of Southampton |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2021B8052 - Time-resolved site-selective Coulomb explosion imaging of photodissociation and ring-opening in structural isomers of iodothiophene |
Organisation | University of Turku |
Country | Finland |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohuku University, Kyoto University, the UVSOR Synchrotron Facility, and QST provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Bristol, Southampton, Turku, DESY, and Kansas State participated, and groups from Oxford, Southampton, Stony Brook, and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2022-2023. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2021 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | Hiroshima University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | Nagoya University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | National Research Council of Canada |
Country | Canada |
Sector | Public |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | Stanford University |
Country | United States |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | Tohoku University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | Tokyo University of Agriculture and Technology |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | University of Hyogo |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | University of Kyoto |
Country | Japan |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | University of Southampton |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022A8011 - Time-resolved Coulomb explosion imaging of inner-shell excited state dynamics in bromoiodomethane and diiodomethane |
Organisation | University of Turku |
Country | Finland |
Sector | Academic/University |
PI Contribution | Remote beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Stanford University were responsible for beamtime organization and instrumentation (PI. R. Forbes, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University and Kyoto University, provided onsite ultrafast laser and instrumentation expertise. Due to Covid-19 restrictions, all other contributions were made remotely. Researchers from Stanford, Oxford, Southampton, Turku, and Kansas State participated, and groups from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis is ongoing with publications expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | Hiroshima University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | Nagoya University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | National Research Council of Canada |
Country | Canada |
Sector | Public |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | Stanford University |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | Tohoku University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | Tokyo University of Agriculture |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | University of Hyogo |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | University of Kyoto |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | University of Oxford |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | University of Southampton |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8043 - Time-resolved Coulomb explosion imaging of sequential photodissociation, transient structure and coherent motion in diiodoethanes |
Organisation | University of Turku |
Country | Finland |
Sector | Academic/University |
PI Contribution | Onsite beamtime support for SACLA BL1; including beamtime planning, data analysis, and publication preparation. |
Collaborator Contribution | The Japan-based groups, as well as Oxford University and Stanford University were responsible for beamtime organization and instrumentation (PI. F. Allum, Stanford PULSE Institute). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Oxford and Stanford are now leading the data analysis. |
Impact | Data analysis has begun but is at a very early stage, the results are encouraging and publications are expected in 2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | Kansas State University |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | Nagoya University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | National Institutes for Quantum and Radiological Science and Technology |
Country | Japan |
Sector | Public |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | National Research Council of Canada |
Country | Canada |
Sector | Public |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | Stanford University |
Country | United States |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | Tohoku University |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | Tokyo University of Agriculture and Technology |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | University of Hyogo |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | University of Kyoto |
Country | Japan |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | University of Oxford |
Department | Department of Chemistry |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | University of Southampton |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | SACLA Beamtime 2022B8048 - Site-selectively probing selenophene ring-opening dynamics using X-ray ionization |
Organisation | University of Turku |
Country | Finland |
Sector | Academic/University |
PI Contribution | Onsite beamtime management at SACLA BL1; including planning, data analysis, project supervision, and publication preparation. |
Collaborator Contribution | The Japan-based groups and Oxford University were responsible for beamtime organization and instrumentation (PIs. E. Warne and M. Burt, Oxford University). SPring-8 supported the project through beamline staff scientist time, access to the SACLA free electron laser, data acquisition support, computational resources, and ultrafast laser expertise. Researchers from Tohoku University, Kyoto University, and QST provided onsite ultrafast laser and instrumentation expertise. Researchers from the Burt group at Oxford Chemistry are now leading the data analysis and publication preparation. |
Impact | Data analysis is at a very early stage, the results are encouraging and we anticipate two or three publications will be put together over 2023-2024. The collaboration is multi-disciplinary: bridging atomic, molecular, and optical physics; physical chemistry; and mass spectrometry imaging. |
Start Year | 2022 |
Description | Graduate open day - Physical and Theoretical Chemistry Laboratory, Department of Chemistry, University of Oxford |
Form Of Engagement Activity | Participation in an open day or visit at my research institution |
Part Of Official Scheme? | No |
Geographic Reach | National |
Primary Audience | Postgraduate students |
Results and Impact | Poster session and individual discussions with prospective graduate students, helping them to determine a preferred supervisor in the Department. |
Year(s) Of Engagement Activity | 2019,2020,2021,2022 |
Description | MChem (Part II) open day - Physical and Theoretical Chemistry Laboratory, Department of Chemistry, University of Oxford |
Form Of Engagement Activity | Participation in an open day or visit at my research institution |
Part Of Official Scheme? | No |
Geographic Reach | Local |
Primary Audience | Undergraduate students |
Results and Impact | Poster session and individual discussions with undergraduates in the Department. This helped them to decide on their final year master's projects. This led to six students joining my research group; two in the 2020-2021 academic year, two in 2021-2022, and two in 2022-2023. |
Year(s) Of Engagement Activity | 2019,2021,2022 |