Acceleration gradient of a plasma wakefield accelerator

被引:3
|
作者
Uhm, Han S. [1 ]
机构
[1] Ajou Univ, Dept Mol Sci & Technol, Suwon 443749, South Korea
来源
APPLIED PHYSICS LETTERS | 2008年 / 92卷 / 08期
关键词
D O I
10.1063/1.2887877
中图分类号
O59 [应用物理学];
学科分类号
摘要
The phase velocity of the wakefield waves is identical to the electron beam velocity. A theoretical analysis indicates that the acceleration gradient of the wakefield accelerator normalized by the wave breaking amplitude is K(0)(xi)/K(1)(xi), where K(0)(xi) and K(1)(xi) are the modified Bessel functions of the second kind of order zero and one, respectively and xi is the beam parameter representing the beam intensity. It is also shown that the beam density must be considerably higher than the diffuse plasma density for the large radial velocity of plasma electrons that are required for a high acceleration gradient. (C) 2008 American Institute of Physics.
引用
收藏
页数:3
相关论文
共 50 条
  • [31] Plasma wakefield acceleration shows promise
    Miller, Johanna
    PHYSICS TODAY, 2015, 68 (01) : 11 - 13
  • [32] Laser Wakefield Acceleration in a Plasma Channel
    M. S. Dorozhkina
    K. V. Baluev
    D. D. Kutergin
    I. K. Lotov
    V. A. Minakov
    R. I. Spitsyn
    P. V. Tuev
    K. V. Lotov
    Bulletin of the Lebedev Physics Institute, 2023, 50 : S715 - S723
  • [33] Laser wakefield acceleration in magnetized plasma
    Jha, Pallavi
    Saroch, Akanksha
    Mishra, Rohit Kumar
    Upadhyay, Ajay Kumar
    PHYSICAL REVIEW SPECIAL TOPICS-ACCELERATORS AND BEAMS, 2012, 15 (08):
  • [34] Blowout regimes of plasma wakefield acceleration
    Lotov, KV
    PHYSICAL REVIEW E, 2004, 69 (04): : 13
  • [35] Field ionization as a plasma source for the plasma wakefield accelerator
    Muggli, P
    Oz, E
    Marsh, KA
    ADVANCED ACCELERATOR CONCEPTS, 2002, 647 : 620 - 627
  • [36] Plasma wakefield acceleration experiments at FACET
    Hogan, M. J.
    Raubenheimer, T. O.
    Seryi, A.
    Muggli, P.
    Katsouleas, T.
    Huang, C.
    Lu, W.
    An, W.
    Marsh, K. A.
    Mori, W. B.
    Clayton, C. E.
    Joshi, C.
    NEW JOURNAL OF PHYSICS, 2010, 12
  • [37] Progress in Hybrid Plasma Wakefield Acceleration
    Hidding, Bernhard
    Assmann, Ralph
    Bussmann, Michael
    Campbell, David
    Chang, Yen-Yu
    Corde, Sebastien
    Cabadag, Jurjen Couperus
    Debus, Alexander
    Doepp, Andreas
    Gilljohann, Max
    Goetzfried, J.
    Foerster, F. Moritz
    Haberstroh, Florian
    Habib, Fahim
    Heinemann, Thomas
    Hollatz, Dominik
    Irman, Arie
    Kaluza, Malte
    Karsch, Stefan
    Kononenko, Olena
    Knetsch, Alexander
    Kurz, Thomas
    Kuschel, Stephan
    Koehler, Alexander
    de la Ossa, Alberto Martinez
    Nutter, Alastair
    Pausch, Richard
    Raj, Gaurav
    Schramm, Ulrich
    Schoebel, Susanne
    Seidel, Andreas
    Steiniger, Klaus
    Ufer, Patrick
    Yeung, Mark
    Zarini, Omid
    Zepf, Matt
    PHOTONICS, 2023, 10 (02)
  • [38] Laser Wakefield Acceleration in a Plasma Channel
    Dorozhkina, M. S.
    Baluev, K. V.
    Kutergin, D. D.
    Lotov, I. K.
    Minakov, V. A.
    Spitsyn, R. I.
    Tuev, P. V.
    Lotov, K. V.
    BULLETIN OF THE LEBEDEV PHYSICS INSTITUTE, 2023, 50 (SUPPL 6) : S715 - S723
  • [39] Electron density gradient measurement for laser wakefield accelerator
    Kim, Jaehoon
    Jang, Hyojae
    Hur, Min Sup
    Kim, Jong-Uk
    ULTRAFAST PHENOMENA XVI, 2009, 92 : 944 - +
  • [40] A High Gradient THz Coaxial Dielectric Wakefield Accelerator
    Shchelkunov, S. V.
    Sotnikov, G. V.
    Marshall, T. C.
    Hirshfield, J. L.
    ADVANCED ACCELERATOR CONCEPTS, 2012, 1507 : 945 - 949
12345