Investigations into dual-grating THz-driven accelerators

Y.  Wei; R Ischebeck; M. Dehler; E Ferrari; N Hiller; S Jamison; Guoxing Xia; Kieran Hanahoe; Yangmei Li; J. D.A. Smith; C. P.  Welsch

doi:10.1016/j.nima.2017.09.050

Investigations into dual-grating THz-driven accelerators

Y. Wei, R Ischebeck, M. Dehler, E Ferrari, N Hiller, S Jamison, Guoxing Xia, Kieran Hanahoe, Yangmei Li, J. D.A. Smith, C. P. Welsch

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Abstract

Advanced acceleration technologies are receiving considerable interest in order to miniaturize future particle accelerators. One such technology is the dual-grating dielectric structures, which can support accelerating fields one to two orders of magnitude higher than the metal RF cavities in conventional accelerators. This opens up the possibility of enabling high accelerating gradients of up to several GV/m. This paper investigates numerically a quartz dual-grating structure which is driven by THz pulses to accelerate electrons. Geometry optimizations are carried out to achieve the trade-offs between accelerating gradient and vacuum channel gap. A realistic electron bunch available from the future Compact Linear Accelerator for Research and Applications (CLARA) is loaded into an optimized 100-period dual-grating structure for a detailed wakefield study. A THz pulse is then employed to interact with this CLARA bunch in the optimized structure. The computed beam quality is analyzed in terms of emittance, energy spread and loaded accelerating gradient. The simulations show that an accelerating gradient of 348 ± 12 MV/m with an emittance growth of 3.0% can be obtained.

Original language	English
Pages (from-to)	173-177
Number of pages	4
Journal	Nuclear Instruments & Methods in Physics Research. Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment
Volume	877
Early online date	5 Oct 2017
DOIs	https://doi.org/10.1016/j.nima.2017.09.050
Publication status	Published - 1 Jan 2018

Keywords

Dielectric dual-gratings
THz-driven
High gradient
Wakefield
THz-bunch interaction
Beam quality

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Wei, Y., Ischebeck, R., Dehler, M., Ferrari, E., Hiller, N., Jamison, S., Xia, G., Hanahoe, K., Li, Y., Smith, J. D. A., & Welsch, C. P. (2018). Investigations into dual-grating THz-driven accelerators. Nuclear Instruments & Methods in Physics Research. Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment , 877, 173-177. https://doi.org/10.1016/j.nima.2017.09.050

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title = "Investigations into dual-grating THz-driven accelerators",

abstract = "Advanced acceleration technologies are receiving considerable interest in order to miniaturize future particle accelerators. One such technology is the dual-grating dielectric structures, which can support accelerating fields one to two orders of magnitude higher than the metal RF cavities in conventional accelerators. This opens up the possibility of enabling high accelerating gradients of up to several GV/m. This paper investigates numerically a quartz dual-grating structure which is driven by THz pulses to accelerate electrons. Geometry optimizations are carried out to achieve the trade-offs between accelerating gradient and vacuum channel gap. A realistic electron bunch available from the future Compact Linear Accelerator for Research and Applications (CLARA) is loaded into an optimized 100-period dual-grating structure for a detailed wakefield study. A THz pulse is then employed to interact with this CLARA bunch in the optimized structure. The computed beam quality is analyzed in terms of emittance, energy spread and loaded accelerating gradient. The simulations show that an accelerating gradient of 348 ± 12 MV/m with an emittance growth of 3.0% can be obtained.",

keywords = "Dielectric dual-gratings, THz-driven, High gradient, Wakefield, THz-bunch interaction, Beam quality",

author = "Y. Wei and R Ischebeck and M. Dehler and E Ferrari and N Hiller and S Jamison and Guoxing Xia and Kieran Hanahoe and Yangmei Li and Smith, {J. D.A.} and Welsch, {C. P.}",

year = "2018",

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doi = "10.1016/j.nima.2017.09.050",

language = "English",

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pages = "173--177",

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Wei, Y, Ischebeck, R, Dehler, M, Ferrari, E, Hiller, N, Jamison, S, Xia, G, Hanahoe, K, Li, Y, Smith, JDA & Welsch, CP 2018, 'Investigations into dual-grating THz-driven accelerators', Nuclear Instruments & Methods in Physics Research. Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment , vol. 877, pp. 173-177. https://doi.org/10.1016/j.nima.2017.09.050

TY - JOUR

T1 - Investigations into dual-grating THz-driven accelerators

AU - Wei, Y.

AU - Ischebeck, R

AU - Dehler, M.

AU - Ferrari, E

AU - Hiller, N

AU - Jamison, S

AU - Xia, Guoxing

AU - Hanahoe, Kieran

AU - Li, Yangmei

AU - Smith, J. D.A.

AU - Welsch, C. P.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - Advanced acceleration technologies are receiving considerable interest in order to miniaturize future particle accelerators. One such technology is the dual-grating dielectric structures, which can support accelerating fields one to two orders of magnitude higher than the metal RF cavities in conventional accelerators. This opens up the possibility of enabling high accelerating gradients of up to several GV/m. This paper investigates numerically a quartz dual-grating structure which is driven by THz pulses to accelerate electrons. Geometry optimizations are carried out to achieve the trade-offs between accelerating gradient and vacuum channel gap. A realistic electron bunch available from the future Compact Linear Accelerator for Research and Applications (CLARA) is loaded into an optimized 100-period dual-grating structure for a detailed wakefield study. A THz pulse is then employed to interact with this CLARA bunch in the optimized structure. The computed beam quality is analyzed in terms of emittance, energy spread and loaded accelerating gradient. The simulations show that an accelerating gradient of 348 ± 12 MV/m with an emittance growth of 3.0% can be obtained.

AB - Advanced acceleration technologies are receiving considerable interest in order to miniaturize future particle accelerators. One such technology is the dual-grating dielectric structures, which can support accelerating fields one to two orders of magnitude higher than the metal RF cavities in conventional accelerators. This opens up the possibility of enabling high accelerating gradients of up to several GV/m. This paper investigates numerically a quartz dual-grating structure which is driven by THz pulses to accelerate electrons. Geometry optimizations are carried out to achieve the trade-offs between accelerating gradient and vacuum channel gap. A realistic electron bunch available from the future Compact Linear Accelerator for Research and Applications (CLARA) is loaded into an optimized 100-period dual-grating structure for a detailed wakefield study. A THz pulse is then employed to interact with this CLARA bunch in the optimized structure. The computed beam quality is analyzed in terms of emittance, energy spread and loaded accelerating gradient. The simulations show that an accelerating gradient of 348 ± 12 MV/m with an emittance growth of 3.0% can be obtained.

KW - Dielectric dual-gratings

KW - THz-driven

KW - High gradient

KW - Wakefield

KW - THz-bunch interaction

KW - Beam quality

U2 - 10.1016/j.nima.2017.09.050

DO - 10.1016/j.nima.2017.09.050

M3 - Article

SN - 0168-9002

VL - 877

SP - 173

EP - 177

JO - Nuclear Instruments & Methods in Physics Research. Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment

JF - Nuclear Instruments & Methods in Physics Research. Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment

ER -

Investigations into dual-grating THz-driven accelerators

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Keywords

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