Literature DB >> 25373678

High-efficiency acceleration of an electron beam in a plasma wakefield accelerator.

M Litos1, E Adli2, W An3, C I Clarke1, C E Clayton4, S Corde1, J P Delahaye1, R J England1, A S Fisher1, J Frederico1, S Gessner1, S Z Green1, M J Hogan1, C Joshi4, W Lu5, K A Marsh4, W B Mori3, P Muggli6, N Vafaei-Najafabadi4, D Walz1, G White1, Z Wu1, V Yakimenko1, G Yocky1.   

Abstract

High-efficiency acceleration of charged particle beams at high gradients of energy gain per unit length is necessary to achieve an affordable and compact high-energy collider. The plasma wakefield accelerator is one concept being developed for this purpose. In plasma wakefield acceleration, a charge-density wake with high accelerating fields is driven by the passage of an ultra-relativistic bunch of charged particles (the drive bunch) through a plasma. If a second bunch of relativistic electrons (the trailing bunch) with sufficient charge follows in the wake of the drive bunch at an appropriate distance, it can be efficiently accelerated to high energy. Previous experiments using just a single 42-gigaelectronvolt drive bunch have accelerated electrons with a continuous energy spectrum and a maximum energy of up to 85 gigaelectronvolts from the tail of the same bunch in less than a metre of plasma. However, the total charge of these accelerated electrons was insufficient to extract a substantial amount of energy from the wake. Here we report high-efficiency acceleration of a discrete trailing bunch of electrons that contains sufficient charge to extract a substantial amount of energy from the high-gradient, nonlinear plasma wakefield accelerator. Specifically, we show the acceleration of about 74 picocoulombs of charge contained in the core of the trailing bunch in an accelerating gradient of about 4.4 gigavolts per metre. These core particles gain about 1.6 gigaelectronvolts of energy per particle, with a final energy spread as low as 0.7 per cent (2.0 per cent on average), and an energy-transfer efficiency from the wake to the bunch that can exceed 30 per cent (17.7 per cent on average). This acceleration of a distinct bunch of electrons containing a substantial charge and having a small energy spread with both a high accelerating gradient and a high energy-transfer efficiency represents a milestone in the development of plasma wakefield acceleration into a compact and affordable accelerator technology.

Entities:  

Year:  2014        PMID: 25373678     DOI: 10.1038/nature13882

Source DB:  PubMed          Journal:  Nature        ISSN: 0028-0836            Impact factor:   49.962


  7 in total

1.  Acceleration of electrons by the interaction of a bunched electron beam with a plasma.

Authors: 
Journal:  Phys Rev Lett       Date:  1985-02-18       Impact factor: 9.161

2.  Experimental observation of plasma wake-field acceleration.

Authors: 
Journal:  Phys Rev Lett       Date:  1988-07-04       Impact factor: 9.161

3.  Multi-GeV energy gain in a plasma-wakefield accelerator.

Authors:  M J Hogan; C D Barnes; C E Clayton; F J Decker; S Deng; P Emma; C Huang; R H Iverson; D K Johnson; C Joshi; T Katsouleas; P Krejcik; W Lu; K A Marsh; W B Mori; P Muggli; C L O'Connell; E Oz; R H Siemann; D Walz
Journal:  Phys Rev Lett       Date:  2005-07-28       Impact factor: 9.161

4.  Nonlinear theory for relativistic plasma wakefields in the blowout regime.

Authors:  W Lu; C Huang; M Zhou; W B Mori; T Katsouleas
Journal:  Phys Rev Lett       Date:  2006-04-26       Impact factor: 9.161

5.  Energy doubling of 42 GeV electrons in a metre-scale plasma wakefield accelerator.

Authors:  Ian Blumenfeld; Christopher E Clayton; Franz-Josef Decker; Mark J Hogan; Chengkun Huang; Rasmus Ischebeck; Richard Iverson; Chandrashekhar Joshi; Thomas Katsouleas; Neil Kirby; Wei Lu; Kenneth A Marsh; Warren B Mori; Patric Muggli; Erdem Oz; Robert H Siemann; Dieter Walz; Miaomiao Zhou
Journal:  Nature       Date:  2007-02-15       Impact factor: 49.962

6.  Beam loading in the nonlinear regime of plasma-based acceleration.

Authors:  M Tzoufras; W Lu; F S Tsung; C Huang; W B Mori; T Katsouleas; J Vieira; R A Fonseca; L O Silva
Journal:  Phys Rev Lett       Date:  2008-09-29       Impact factor: 9.161

7.  Physical mechanisms in the plasma wake-field accelerator.

Authors: 
Journal:  Phys Rev A Gen Phys       Date:  1986-03
  7 in total
  19 in total

1.  Multi-gigaelectronvolt acceleration of positrons in a self-loaded plasma wakefield.

Authors:  S Corde; E Adli; J M Allen; W An; C I Clarke; C E Clayton; J P Delahaye; J Frederico; S Gessner; S Z Green; M J Hogan; C Joshi; N Lipkowitz; M Litos; W Lu; K A Marsh; W B Mori; M Schmeltz; N Vafaei-Najafabadi; D Walz; V Yakimenko; G Yocky
Journal:  Nature       Date:  2015-08-27       Impact factor: 49.962

2.  Accelerator physics: Surf's up at SLAC.

Authors:  Mike Downer; Rafal Zgadzaj
Journal:  Nature       Date:  2014-11-06       Impact factor: 49.962

3.  2014 Editors' choice.

Authors: 
Journal:  Nature       Date:  2014-12-18       Impact factor: 49.962

4.  Free-electron lasing with compact beam-driven plasma wakefield accelerator.

Authors:  R Pompili; D Alesini; M P Anania; S Arjmand; M Behtouei; M Bellaveglia; A Biagioni; B Buonomo; F Cardelli; M Carpanese; E Chiadroni; A Cianchi; G Costa; A Del Dotto; M Del Giorno; F Dipace; A Doria; F Filippi; M Galletti; L Giannessi; A Giribono; P Iovine; V Lollo; A Mostacci; F Nguyen; M Opromolla; E Di Palma; L Pellegrino; A Petralia; V Petrillo; L Piersanti; G Di Pirro; S Romeo; A R Rossi; J Scifo; A Selce; V Shpakov; A Stella; C Vaccarezza; F Villa; A Zigler; M Ferrario
Journal:  Nature       Date:  2022-05-25       Impact factor: 49.962

5.  Plasmas primed for rapid pulse production.

Authors:  Michael Litos
Journal:  Nature       Date:  2022-03       Impact factor: 49.962

6.  Demonstration of a compact plasma accelerator powered by laser-accelerated electron beams.

Authors:  T Kurz; T Heinemann; M F Gilljohann; Y Y Chang; J P Couperus Cabadağ; A Debus; O Kononenko; R Pausch; S Schöbel; R W Assmann; M Bussmann; H Ding; J Götzfried; A Köhler; G Raj; S Schindler; K Steiniger; O Zarini; S Corde; A Döpp; B Hidding; S Karsch; U Schramm; A Martinez de la Ossa; A Irman
Journal:  Nat Commun       Date:  2021-05-17       Impact factor: 14.919

7.  High-intensity double-pulse X-ray free-electron laser.

Authors:  A Marinelli; D Ratner; A A Lutman; J Turner; J Welch; F-J Decker; H Loos; C Behrens; S Gilevich; A A Miahnahri; S Vetter; T J Maxwell; Y Ding; R Coffee; S Wakatsuki; Z Huang
Journal:  Nat Commun       Date:  2015-03-06       Impact factor: 14.919

8.  Capturing relativistic wakefield structures in plasmas using ultrashort high-energy electrons as a probe.

Authors:  C J Zhang; J F Hua; X L Xu; F Li; C-H Pai; Y Wan; Y P Wu; Y Q Gu; W B Mori; C Joshi; W Lu
Journal:  Sci Rep       Date:  2016-07-11       Impact factor: 4.379

9.  Demonstration of a positron beam-driven hollow channel plasma wakefield accelerator.

Authors:  Spencer Gessner; Erik Adli; James M Allen; Weiming An; Christine I Clarke; Chris E Clayton; Sebastien Corde; J P Delahaye; Joel Frederico; Selina Z Green; Carsten Hast; Mark J Hogan; Chan Joshi; Carl A Lindstrøm; Nate Lipkowitz; Michael Litos; Wei Lu; Kenneth A Marsh; Warren B Mori; Brendan O'Shea; Navid Vafaei-Najafabadi; Dieter Walz; Vitaly Yakimenko; Gerald Yocky
Journal:  Nat Commun       Date:  2016-06-02       Impact factor: 14.919

10.  High-field plasma acceleration in a high-ionization-potential gas.

Authors:  S Corde; E Adli; J M Allen; W An; C I Clarke; B Clausse; C E Clayton; J P Delahaye; J Frederico; S Gessner; S Z Green; M J Hogan; C Joshi; M Litos; W Lu; K A Marsh; W B Mori; N Vafaei-Najafabadi; D Walz; V Yakimenko
Journal:  Nat Commun       Date:  2016-06-17       Impact factor: 14.919
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.