Sub-MeV Ion Generation by Standing Wave Excitation of Ionized Gases

Turnár, Szabolcs; Almási, Gabor; Hebling, János; Korpa, Csaba; Mechler, Matyas; Pálfalvi, Laszlo; Tibai, Zoltan

doi:10.18429/JACoW-IPAC2021-WEPAB143

Joint Accelerator Conferences Website

The Joint Accelerator Conferences Website (JACoW) is an international collaboration that publishes the proceedings of accelerator conferences held around the world.

RIS citation export for WEPAB143: Sub-MeV Ion Generation by Standing Wave Excitation of Ionized Gases

TY  - CONF
AU  - Turnár, Sz.
AU  - Almási, G.
AU  - Hebling, J.
AU  - Korpa, Cs.
AU  - Mechler, M.I.
AU  - Pálfalvi, L.
AU  - Tibai, Z.
ED  - Liu, Lin
ED  - Byrd, John M.
ED  - Neuenschwander, Regis T.
ED  - Picoreti, Renan
ED  - Schaa, Volker R. W.
TI  - Sub-MeV Ion Generation by Standing Wave Excitation of Ionized Gases
J2  - Proc. of IPAC2021, Campinas, SP, Brazil, 24-28 May 2021
CY  - Campinas, SP, Brazil
T2  - International Particle Accelerator Conference
T3  - 12
LA  - english
AB  - Many ion acceleration techniques have been suggested and thoroughly studied in the last two decades*. One of the promising techniques is the Coulomb explosion acceleration (CEA)**. Using CEA in clusters could result in symmetric acceleration if there are not any other significant mechanisms. We proposed a THz-driven accelerator scheme that is based on CEA in proton, deuterium and heavy water gas plasmas. Two counter-propagating THz pulses are focused to the ionized region of the gas jet. Following the ripping of the electrons from the gas plasmas by ultrafast standing waves, the Coulomb explosion accelerates the positive ions. According to our calculation, using 2 x 34 mJ THz pulses electrons and protons with 1.1 nC charge are accelerated up to 0.4 MeV and 0.1 MeV, respectively. The total energy of the particles is 0.7 % of the energy of the THz pulses. We examined the effect of the initial bunch charge, bunch size and shape on the final energy spectra and the directional distribution of the particles. Our presented technique is scalable from a few µm to a few thousand µm driving wavelengths and can be used for electron and heavy-ion acceleration.
PB  - JACoW Publishing
CP  - Geneva, Switzerland
SP  - 2951
EP  - 2953
KW  - electron
KW  - acceleration
KW  - plasma
KW  - laser
KW  - simulation
DA  - 2021/08
PY  - 2021
SN  - 2673-5490
SN  - 978-3-95450-214-1
DO  - doi:10.18429/JACoW-IPAC2021-WEPAB143
UR  - https://jacow.org/ipac2021/papers/wepab143.pdf
ER  -