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Insertion of STC into TRT at the Department of Physics, Oxford
Credit: CERN

Philip Burrows

Professor of Physics

Sub department

  • Particle Physics
Philip.Burrows@physics.ox.ac.uk
Telephone: 01865 (2)73451
Denys Wilkinson Building, room 615a
  • About
  • Publications

Design and operation of a prototype interaction point beam collision feedback system for the International Linear Collider

(2018)

Authors:

RJ Apsimon, DR Bett, N Blaskovic Kraljevic, RM Bodenstein, T Bromwich, PN Burrows, GB Christian, BD Constance, MR Davis, C Perry, R Ramjiawan
More details from the publisher

The Compact Linear e$^+$e$^-$ Collider (CLIC): Accelerator and Detector

(2018)

Authors:

A Robson, PN Burrows, N Catalan Lasheras, L Linssen, M Petric, D Schulte, E Sicking, S Stapnes, W Wuensch
More details from the publisher

The Compact Linear e+e− Collider (CLIC): Accelerator and Detector

Cern European Organization for Nuclear Research -Reports- Cern (2018)
Details from ORA

The Compact Linear e+e− Collider (CLIC): Physics Potential

Cern European Organization for Nuclear Research -Reports- Cern CERN (2018)

Abstract:

The Compact Linear Collider, CLIC, is a proposed e+e− collider at the TeV scale whose physics potential ranges from high-precision measurements to extensive direct sensitivity to physics beyond the Standard Model. This document summarises the physics potential of CLIC, obtained in detailed studies, many based on full simulation of the CLIC detector. CLIC covers one order of magnitude of centre-of-mass energies from 350 GeV to 3 TeV, giving access to large event samples for a variety of SM processes, many of them for the first time in e+e− collisions or for the first time at all. The high collision energy combined with the large luminosity and clean environment of the e+e− collisions enables the measurement of the properties of Standard Model particles, such as the Higgs boson and the top quark, with unparalleled precision. CLIC might also discover indirect effects of very heavy new physics by probing the parameters of the Standard Model Effective Field Theory with an unprecedented level of precision. The direct and indirect reach of CLIC to physics beyond the Standard Model significantly exceeds that of the HL-LHC. This includes new particles detected in challenging non-standard signatures. With this physics programme, CLIC will decisively advance our knowledge relating to the open questions of particle physics.
Details from ORA

Design and operation of a prototype interaction point beam collision feedback system for the International Linear Collider

PHYSICAL REVIEW ACCELERATORS AND BEAMS 21:12 (2018) ARTN 122802

Authors:

RJ Apsimon, DR Bett, N Blaskovic Kraljevic, RM Bodenstein, T Bromwich, PN Burrows, GB Christian, BD Constance, MR Davis, C Perry, R Ramjiawan
More details from the publisher
Details from ORA
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