Compact Thomson parabola spectrometer with variability of energy range and measurability of angular distribution for low-energy laser-driven accelerated ions

• Published in: Review of scientific instruments Vol. 91; no. 5; pp. 053305 - 53315
• Main Authors: Kojima, Sadaoki, Inoue, Shunsuke, Dinh, Thanh Hung, Hasegawa, Noboru, Mori, Michiaki, Sakaki, Hironao, Yamamoto, Yoichi, Sasaki, Teru, Shiokawa, Keiichiro, Kondo, Kotaro, Yamanaka, Takashi, Hashida, Masaki, Sakabe, Shuji, Nishikino, Masaharu, Kondo, Kiminori
• Format: Journal Article
• Language: English
• Published: Melville American Institute of Physics 01.05.2020
• Subjects: Angular distribution; Annuli; Configurations; Electric fields; Electrodes; Energy; Energy distribution; Energy resolution; Energy spectra; Lorentz force; Magnetic circuits; Magnetic fields; Magnetic flux; Permanent magnets; Pinholes; Scientific apparatus & instruments; Wedges; Yokes
• ISSN: 0034-6748; 1089-7623; 1089-7623
• DOI: 10.1063/5.0005450

This article reports the development of a compact Thomson parabola spectrometer for laser-accelerated ions that can measure angular distribution with a high energy resolution and has a variable measurable energy range. The angular-resolved energy spectra for different ion species can be measured in a single shot, and the sampling angle can be selected from outside the vacuum region. The electric and magnetic fields are applied to the ion dispersion by using a permanent magnetic circuit and annulus sector-shaped electrodes with a wedge configuration. The compact magnetic circuit consists of permanent magnets, fixed yokes, and movable yokes. The magnetic flux is intentionally leaked to the movable yokes, allowing the magnetic field to be adjusted from 53 mT to 259 mT. The annulus sector-shaped electrodes with a wedge configuration provide better trace separation for high-energy ions, retain the lower-energy part of the ion signal, and subject ions passing through all pinholes to an equivalent Lorentz force. The magnetic and electric fields are designed for measuring protons and carbon ions with an energy range of 0.1–5 MeV. The spectrometer allows for the adjustment of the observable energy range afterward according to the parameters of the accelerated ion.