Title
| Chapter 4: High-gradient plasma and laser accelerators |
Author(s)
|
Assmann, R (DESY ; LNF, Dafne Light) ; Gschwendtner, E (CERN) ; Cassou, K (IJCLab, Orsay) ; Corde, S (Ec. Polytech., Palaiseau (main)) ; Corner, L (Nikhef, Amsterdam) ; Cros, B (LPGP, Orsay) ; Ferrario, M (LNF, Dafne Light) ; Hooker, S (JAI, UK) ; Ischebeck, R (PSI, Villigen) ; Latina, A (CERN) ; Lundh, O (IJCLab, Orsay) ; Muggli, P (Munich, Max Planck Inst.) ; Nghiem, P (Saclay) ; Osterhoff, J (DESY) ; Raubenheimer, T (SLAC ; Stanford U.) ; Specka, A (Ecole Polytechnique) ; Vieira, J (PSI, Villigen) ; Wing, M (U. Coll. London) Afficher les 18 auteurs |
Publication
| 2022 |
Number of pages
| 53 |
In:
| European Strategy for Particle Physics - Accelerator R&D Roadmap, pp.91-143 |
DOI
| 10.23731/CYRM-2022-001.91
|
Subject category
| Accelerators and Storage Rings |
Abstract
| Novel high-gradient accelerators have demonstrated acceleration of electrons and positrons with electric field strengths of 1 to > 100 GeV/m. This is about 10 to 1000 times higher than achieved in RF-based accelerators, and as such they have the potential to overcome the limitations associated with RF cavities. Plasma-based accelerators have produced multi-GeV bunches with parameters approaching those suitable for a linear collider. These accelerators offer the prospect of near term, compact and cost-effective particle physics experiments that provide new physics possibilities supporting precision studies and the search for new particles.
The expert panel has defined a long term R&D; roadmap towards a compact collider with attractive intermediate experiments and studies. A delivery plan for the required R&D; has been developed and includes work packages, deliverables, a minimal plan, connections to ongoing projects and an aspirational plan. |
Copyright/License
| © 2022-2024 CERN (License: CC-BY-4.0) |