The John Adams Institute for Accelerator Science
Lead Research Organisation:
Royal Holloway University of London
Department Name: Physics
Abstract
The John Adams Institute for Accelerator Science (JAI) is a centre of excellence for advanced accelerator science and technology. We perform R&D and training, provide expertise, and promote accelerator applications in science and society. The JAI currently comprises 20 faculty, 23 staff, and 38 PhD students from the Physics Departments of Oxford University (UOXF), Royal Holloway University of London (RHUL), and Imperial College London (ICL). An additional 33 staff from the UK's national laboratories and CERN are affiliated with our research and teaching programmes. We have six guiding principles:
a) Develop, support and engagement of accelerator science facilities and R&D programmes of strategic importance for the UK;
b) Develop worldwide collaborations that enhance the capabilities available to us;
c) Develop novel acceleration and compact light source techniques and their applications;
d) Deliver a world leading training programme to develop the next generation of leaders in the field;
e) Communicate developments in the field to the public and decision makers;
f) Strengthen the links among the partner universities to deliver a programme that is greater than the sum of its parts.
For the period 2021-2025, we have focused on research areas that have the greatest benefit to national priorities:
* Low-emittance, high-brightness electron beams, including next-generation electron-positron colliders (ILC, CLIC), the Diamond Light Source (DLS) and its upgrade, and a future UK FEL.
* High-energy/high-intensity hadron beams, including current and future energy-frontier proton colliders (LHC, HL-LHC, FCC), and ISIS and its upgrade.
* Advanced acceleration techniques, including laser- and beam-driven plasma-wakefield acceleration.
* Particle-beam therapy applications using electron, proton and ion beams.
Through this programme we are supporting the UK's accelerator strategy by taking lead roles in both our national and overseas facilities including: DLS, ISIS and CLF at STFC/RAL, CLARA at STFC/DL, LHC, HL-LHC, CLIC, FCC and AWAKE at CERN, FLASHforward at DESY, and ATF/ATF2 at KEK.
These themes position us optimally to support our core goals of supporting major national and international accelerator developments; motivating our researchers and giving them skills in state-of-the-art technologies; and being able to transfer our knowledge to major collaborative developments and to industry.
a) Develop, support and engagement of accelerator science facilities and R&D programmes of strategic importance for the UK;
b) Develop worldwide collaborations that enhance the capabilities available to us;
c) Develop novel acceleration and compact light source techniques and their applications;
d) Deliver a world leading training programme to develop the next generation of leaders in the field;
e) Communicate developments in the field to the public and decision makers;
f) Strengthen the links among the partner universities to deliver a programme that is greater than the sum of its parts.
For the period 2021-2025, we have focused on research areas that have the greatest benefit to national priorities:
* Low-emittance, high-brightness electron beams, including next-generation electron-positron colliders (ILC, CLIC), the Diamond Light Source (DLS) and its upgrade, and a future UK FEL.
* High-energy/high-intensity hadron beams, including current and future energy-frontier proton colliders (LHC, HL-LHC, FCC), and ISIS and its upgrade.
* Advanced acceleration techniques, including laser- and beam-driven plasma-wakefield acceleration.
* Particle-beam therapy applications using electron, proton and ion beams.
Through this programme we are supporting the UK's accelerator strategy by taking lead roles in both our national and overseas facilities including: DLS, ISIS and CLF at STFC/RAL, CLARA at STFC/DL, LHC, HL-LHC, CLIC, FCC and AWAKE at CERN, FLASHforward at DESY, and ATF/ATF2 at KEK.
These themes position us optimally to support our core goals of supporting major national and international accelerator developments; motivating our researchers and giving them skills in state-of-the-art technologies; and being able to transfer our knowledge to major collaborative developments and to industry.
Publications
Karataev P
(2022)
Indicators of upcoming electric breakdown in a pyroelectric accelerator
in Applied Physics Express
Walker S
(2022)
Pyg4ometry: A Python library for the creation of Monte Carlo radiation transport physical geometries
in Computer Physics Communications
Oleinik A
(2023)
I-V curve of the electron flow generated during a pyroelectric effect in lithium tantalate single crystal in vacuum conditions
in Europhysics Letters
Oleinik A
(2022)
Peculiarities of the pyroelectric current generated using a LiNbO3 single crystal driven by low-frequency sinusoidal temperature variation
in Journal of Applied Physics
Fedorov K
(2022)
Compact Remote Spectral Terahertz Imager
in Journal of Infrared, Millimeter, and Terahertz Waves
Feng J
(2023)
The Forward Physics Facility at the High-Luminosity LHC
in Journal of Physics G: Nuclear and Particle Physics
Ramoisiaux E
(2023)
Concrete shielding activation for proton therapy systems using BDSIM and FISPACT-II
in Journal of Physics: Conference Series
Gnacadja E
(2023)
Upgrade of a proton therapy eye treatment nozzle using a cylindrical beam stopping device for enhanced dose rate performances
in Journal of Physics: Conference Series
Metzger F
(2024)
Kaon beam simulations employing conventional hadron beam concepts and the RF separation technique at the CERN M2 beamline for the future AMBER experiment
in Journal of Physics: Conference Series
Abreu H
(2022)
The tracking detector of the FASER experiment
in Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment