The structure and dynamics of water confined in nanoscale pools: the dynamic crossover
Lead Research Organisation:
University of Glasgow
Department Name: School of Chemistry
Abstract
The peculiar behaviour of liquid and supercooled water has been baffling science for at least 236 years and is still seen as a major challenge facing chemistry today (Whitesides & Deutch, Nature 469, 21 (2011)). It was suggested that such strange behaviour might be caused by thermodynamic transitions, possibly even a second critical point. This second critical point would terminate a coexistence line between low- and high-density amorphous phases of water. Unfortunately, this second critical point (if it exists) and the associated polyamorphic liquid-liquid transition is difficult to study as it is thought to lie below the homogeneous nucleation temperature in a region known as "no man's land" (Angell, Science 319, 582 (2008)).
In recent preliminary femtosecond optical Kerr-effect spectroscopy experiments, we have shown that water in concentrated eutectic solutions forms nanometre scale pools in which it retains many if not most of its bulk liquid characteristics. Most importantly, such solutions can be cooled to below 200 K without crystallisation (typically forming a glass at lower temperatures) allowing one to explore "no man's land" in detail for the first time. Preliminary experiments combining femtosecond spectroscopy with NMR diffusion measurements have shown that water in these pools undergoes a liquid-liquid transition as predicted for bulk water.
Hence, it is proposed to use such nanopools as nanometre scale laboratories for the study of liquid and glassy water. A wide-ranging international collaboration has been set up to be able to study different critical aspects of the structure and dynamics of water. This includes cryogenic viscosity measurements, large dynamic-range (femtosecond to millisecond) optical Kerr-effect experiments, pulsed field gradient NMR, dielectric relaxation spectroscopy, terahertz time-domain spectroscopy, infrared pump-probe spectroscopy, and two-dimensional infrared spectroscopy. To ensure maximum impact of the experimental work, it is critical to have strong ties with experts in the theory and simulation of water and its thermodynamic behaviour. We have arranged collaboration with two international theory groups covering different aspects of the proposed work.
Although the proposed research is relatively fundamental in nature, it will have impact as described in more detail elsewhere. The research addresses EPSRC priorities in nanoscience (supramolecular structures in liquids), energy (proton transport and liquid structuring in electrolytes for batteries and fuel cells), life sciences (the role of water in and on biomolecules), and the chemistry-chemical engineering interface (the role of the structuring of water in crystal nucleation). Our strong links with theory collaborators will ensure that fundamental insights will indeed propagate to the 'users' of such information. The close working relationship between the PI and CI has made Glasgow a centre of excellence in advanced femtosecond spectroscopy. This project exploits this expertise and international collaborations to immerse PDRAs and PGRSs in internationally leading research using state-of-the-art previously funded equipment.
In recent preliminary femtosecond optical Kerr-effect spectroscopy experiments, we have shown that water in concentrated eutectic solutions forms nanometre scale pools in which it retains many if not most of its bulk liquid characteristics. Most importantly, such solutions can be cooled to below 200 K without crystallisation (typically forming a glass at lower temperatures) allowing one to explore "no man's land" in detail for the first time. Preliminary experiments combining femtosecond spectroscopy with NMR diffusion measurements have shown that water in these pools undergoes a liquid-liquid transition as predicted for bulk water.
Hence, it is proposed to use such nanopools as nanometre scale laboratories for the study of liquid and glassy water. A wide-ranging international collaboration has been set up to be able to study different critical aspects of the structure and dynamics of water. This includes cryogenic viscosity measurements, large dynamic-range (femtosecond to millisecond) optical Kerr-effect experiments, pulsed field gradient NMR, dielectric relaxation spectroscopy, terahertz time-domain spectroscopy, infrared pump-probe spectroscopy, and two-dimensional infrared spectroscopy. To ensure maximum impact of the experimental work, it is critical to have strong ties with experts in the theory and simulation of water and its thermodynamic behaviour. We have arranged collaboration with two international theory groups covering different aspects of the proposed work.
Although the proposed research is relatively fundamental in nature, it will have impact as described in more detail elsewhere. The research addresses EPSRC priorities in nanoscience (supramolecular structures in liquids), energy (proton transport and liquid structuring in electrolytes for batteries and fuel cells), life sciences (the role of water in and on biomolecules), and the chemistry-chemical engineering interface (the role of the structuring of water in crystal nucleation). Our strong links with theory collaborators will ensure that fundamental insights will indeed propagate to the 'users' of such information. The close working relationship between the PI and CI has made Glasgow a centre of excellence in advanced femtosecond spectroscopy. This project exploits this expertise and international collaborations to immerse PDRAs and PGRSs in internationally leading research using state-of-the-art previously funded equipment.
Planned Impact
Economy
This proposal concerns relatively fundamental physical-chemistry research. However, there are tangible routes to economic impact. The research addresses EPSRC priorities in nanoscience, energy, life sciences, and the chemistry-chemical engineering interface. Most relevant to the economy (e.g., pharmaceutical industry) are insights to be gained in the role of the structuring of water in crystal nucleation. The PI's membership in the CMAC-SPIRIT crystallisation science consortium (including GSK, NiTech, Pfizer, Astra Zeneca, Fujifilm, and others) facilitates the exploration of routes to impact. Our studies of transport phenomena in solutions will have a direct bearing on proton transport and liquid structuring in electrolytes for batteries and fuel cells addressing the EPSRC priority areas of energy and nanoscience. The salt solutions to be studied here are in many respects similar to room-temperature ionic liquids and show similar effects. One of the collaborators on the project (Seddon) is founder director of the Queen's University Ionic Liquid Laboratories (Quill) research centre, which has members from all sectors of the chemical industry including SHELL, Chevron, Eastman, Merck, and Procter and Gamble. Again, this will facilitate the exploration of routes to impact.
Knowledge
The knowledge generated by the proposed work will be communicated through standard routes: papers, conferences, etc. The team (PI + CI + collaborators) have had considerable impact in the past with numerous papers in high impact journals such as Nature, Science, PNAS, JACS, and PRL. The publication record of the applicants is strong and is expected to continue in this manner with targeting of the top tier journals such as Science and Nature with the collaborative work proposed here. In addition, the PI and CI are guest editors for a special issue of PCCP on Ultrafast Physical Chemistry and Chemical Physics to be published in 2012.
Other channels of knowledge transfer include the organisation of conferences in which the PI and CI have a strong track record. Two relevant conferences will be organised in Glasgow by the applicants during the proposed grant period. Furthermore, the PI is a member of a number of programme committees organising conferences in the area of the proposal.
People
The research proposal under consideration here is people centred and career development of the team members a key aim. A critical aspect of this is the ultrafast chemical physics collaboration between the PI at Glasgow University and the CI at Strathclyde University both in the City of Glasgow and separated only by a 10-minute journey. This local collaboration is a centre of excellence in advanced femtosecond spectroscopy. We host international researchers, organise a number of local meetings (see above), and provide a range of training opportunities for PDRAs and PGRSs.
Society
It will be attempted to communicate a flavour of the research enterprise and its results to the public. For this we will use modern channels of communication, such as video (through our YouTube channel 'ucpgroup'), Twitter (using our feed 'klaaswynne'), blog (the survival blog for scientists), and web. Finally, the PI is participating in the 'Capture a Chemist' crowd-sourced chemistry engagement arts project in conjunction with the International Year of Chemistry 2011 that brings the photographic and chemical communities together to share the stories of chemists across the world.
This proposal concerns relatively fundamental physical-chemistry research. However, there are tangible routes to economic impact. The research addresses EPSRC priorities in nanoscience, energy, life sciences, and the chemistry-chemical engineering interface. Most relevant to the economy (e.g., pharmaceutical industry) are insights to be gained in the role of the structuring of water in crystal nucleation. The PI's membership in the CMAC-SPIRIT crystallisation science consortium (including GSK, NiTech, Pfizer, Astra Zeneca, Fujifilm, and others) facilitates the exploration of routes to impact. Our studies of transport phenomena in solutions will have a direct bearing on proton transport and liquid structuring in electrolytes for batteries and fuel cells addressing the EPSRC priority areas of energy and nanoscience. The salt solutions to be studied here are in many respects similar to room-temperature ionic liquids and show similar effects. One of the collaborators on the project (Seddon) is founder director of the Queen's University Ionic Liquid Laboratories (Quill) research centre, which has members from all sectors of the chemical industry including SHELL, Chevron, Eastman, Merck, and Procter and Gamble. Again, this will facilitate the exploration of routes to impact.
Knowledge
The knowledge generated by the proposed work will be communicated through standard routes: papers, conferences, etc. The team (PI + CI + collaborators) have had considerable impact in the past with numerous papers in high impact journals such as Nature, Science, PNAS, JACS, and PRL. The publication record of the applicants is strong and is expected to continue in this manner with targeting of the top tier journals such as Science and Nature with the collaborative work proposed here. In addition, the PI and CI are guest editors for a special issue of PCCP on Ultrafast Physical Chemistry and Chemical Physics to be published in 2012.
Other channels of knowledge transfer include the organisation of conferences in which the PI and CI have a strong track record. Two relevant conferences will be organised in Glasgow by the applicants during the proposed grant period. Furthermore, the PI is a member of a number of programme committees organising conferences in the area of the proposal.
People
The research proposal under consideration here is people centred and career development of the team members a key aim. A critical aspect of this is the ultrafast chemical physics collaboration between the PI at Glasgow University and the CI at Strathclyde University both in the City of Glasgow and separated only by a 10-minute journey. This local collaboration is a centre of excellence in advanced femtosecond spectroscopy. We host international researchers, organise a number of local meetings (see above), and provide a range of training opportunities for PDRAs and PGRSs.
Society
It will be attempted to communicate a flavour of the research enterprise and its results to the public. For this we will use modern channels of communication, such as video (through our YouTube channel 'ucpgroup'), Twitter (using our feed 'klaaswynne'), blog (the survival blog for scientists), and web. Finally, the PI is participating in the 'Capture a Chemist' crowd-sourced chemistry engagement arts project in conjunction with the International Year of Chemistry 2011 that brings the photographic and chemical communities together to share the stories of chemists across the world.
Publications
Dhumal NR
(2017)
Dielectric Relaxation of the Ionic Liquid 1-Ethyl-3-methylimidazolium Ethyl Sulfate: Microwave and Far-IR Properties.
in The journal of physical chemistry. B
Farrell A
(2021)
Characterisation of the Boson Peak from the Glass into the Liquid
González Jiménez M
(2019)
Prediction of mosquito species and population age structure using mid-infrared spectroscopy and supervised machine learning
in Wellcome Open Research
González Jiménez M
(2019)
Prediction of mosquito species and population age structure using mid-infrared spectroscopy and supervised machine learning.
in Wellcome open research
González Jiménez M
(2019)
Prediction of mosquito species and population age structure using mid-infrared spectroscopy and supervised machine learning
in Wellcome Open Research
González-Jiménez M
(2021)
Low-frequency vibrational modes in G-quadruplexes reveal the mechanical properties of nucleic acids.
in Physical chemistry chemical physics : PCCP
González-Jiménez M
(2016)
Observation of coherent delocalized phonon-like modes in DNA under physiological conditions
in Nature Communications
González-Jiménez M
(2023)
Understanding the emergence of the boson peak in molecular glasses.
in Nature communications
Hithell G
(2017)
Ultrafast 2D-IR and optical Kerr effect spectroscopy reveal the impact of duplex melting on the structural dynamics of DNA.
in Physical chemistry chemical physics : PCCP
Lane PD
(2020)
Experimental observation of nanophase segregation in aqueous salt solutions around the predicted liquid-liquid transition in water.
in Physical chemistry chemical physics : PCCP
| Title | Control over phase separation and nucleation using a laser-tweezing potential |
| Description | |
| Type Of Material | Database/Collection of data |
| Year Produced | 2017 |
| Provided To Others? | Yes |
| Title | Experimental observation of nanophase segregation of aqueous salt solutions around the predicted liquid-liquid transition in water |
| Description | Data accompanying article at https://doi.org/10.1039/C9CP06082K |
| Type Of Material | Database/Collection of data |
| Year Produced | 2020 |
| Provided To Others? | Yes |
| URL | http://researchdata.gla.ac.uk/id/eprint/1001 |
| Title | Frustration vs. Prenucleation: Understanding the Surprising Stability of Supersaturated Sodium Thiosulfate Solutions |
| Description | |
| Type Of Material | Database/Collection of data |
| Year Produced | 2018 |
| Provided To Others? | Yes |
| Title | Low-frequency vibrational modes in G-quadruplexes reveal the mechanical properties of nucleic acids |
| Description | |
| Type Of Material | Database/Collection of data |
| Year Produced | 2021 |
| Provided To Others? | Yes |
| URL | http://researchdata.gla.ac.uk/id/eprint/1150 |
| Title | Observation of coherent delocalised phonon-like modes in DNA under physiological conditions |
| Description | |
| Type Of Material | Database/Collection of data |
| Year Produced | 2016 |
| Provided To Others? | Yes |
| Title | Polyamorphism mirrors polymorphism in the liquid-liquid transition of a molecular liquid |
| Description | Liquid-liquid transitions between two amorphous phases in a single-component liquid (polyamorphism) have defied explanation and courted controversy. All known examples of liquid-liquid transitions have been observed in the supercooled liquid suggesting an intimate connection with vitrification and locally favored structures inhibiting crystallization. However, there is precious little information about the local molecular packing in supercooled liquids meaning that the order parameter of the transition is still unknown. Here, we investigate the liquid-liquid transition in triphenyl phosphite and show that it is caused by the competition between liquid structures that mirror two crystal polymorphs. The liquid-liquid transition is found to be between a geometrically frustrated liquid to a dynamically frustrated glass. These results indicate a general link between polymorphism and polyamorphism and will lead to a much greater understanding of the physical basis of liquid-liquid transitions and allow the discovery of other examples. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2020 |
| Provided To Others? | Yes |
| URL | http://researchdata.gla.ac.uk/id/eprint/993 |
| Title | Prediction of malaria mosquito species and population age structure using mid-infrared spectroscopy and supervised machine learning |
| Description | Despite the global efforts made in the fight against malaria, the disease is resurging. One of the main causes is the resistance that Anopheles mosquitoes, vectors of the disease, have developed to insecticides. Anopheles must survive for at least 12 days to possibly transmit malaria. Therefore, to evaluate and improve malaria vector control interventions, it is imperative to monitor and accurately estimate the age distribution of mosquito populations as well as total population sizes. However, estimating mosquito age is currently a slow, imprecise, and labour-intensive process that can only distinguish under- from over-four-day-old female mosquitoes. Here, we demonstrate a machine-learning based approach that utilizes mid-infrared spectra of mosquitoes to characterize simultaneously, and with unprecedented accuracy, both age and species identity of females of the malaria vectors Anopheles gambiae and An. arabiensis mosquitoes within their respective populations. The prediction of the age structures was statistically indistinguishable from true modelled distributions. The method has a negligible cost per mosquito, does not require highly trained personnel, is substantially faster than current techniques, and so can be easily applied in both laboratory and field settings. Our results show that, with larger mid-infrared spectroscopy data sets, this technique can be further improved and expanded to vectors of other diseases such as Zika and Dengue. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2018 |
| Provided To Others? | Yes |
| Title | Understanding the emergence of the boson peak in molecular glasses |
| Description | Data used to make the figures in the manuscript |
| Type Of Material | Database/Collection of data |
| Year Produced | 2023 |
| Provided To Others? | Yes |
| URL | http://researchdata.gla.ac.uk/id/eprint/1381 |