Research field (2):
Theoretical studies related to particle-, nuclear-, cosmic ray and astro-physics
, Particle, nuclear, cosmic-ray, and astrophysics - experiment
Research theme for competitive and other funds (9):
2022 - 2026 International Antarctic balloon-borne experiment GAPS to open the next era of cosmic-ray observation and dark-matter search
2020 - 2023 Search for cosmic-ray heavy antiparticles with Antarctica balloon
2013 - 2017 Beam tests of the CALET cosmic-ray detector with a ground verification model at CERN-SPS
2012 - 2016 Development of CALET for the observation of cosmic-ray electron and positron
2011 - 2016 Deeping the analysis of the LHCf experiment and exploring the highest energy
2010 - 2011 Trigger system for high energy cosmic ray measurement
2007 - 2011 High sensitivity search forν_μtoν_e oscillations
2008 - 2010 Running the CERN LHCf experiment and validating nuclear interaction models at ultra high energies
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Papers (60):
N. Saffold, H. Fuke, Y. Shimizu. Passivation of Si(Li) detectors operated above cryogenic temperatures for space-based applications. Nuclear Instruments and Methods in Physics Research Section A. 2021. 997. 165015
N. Saffold, T. Aramaki, R. Bird, M. Boezio, S. E. Boggs, V. Bonvicini, D. Campana, W. W. Craig, P. von Doetinchem, E. Everson, et al. Cosmic antihelium-3 nuclei sensitivity of the GAPS experiment. Astroparticle Physics. 2021. 130. 102580
T. Wada, H. Fuke, Y. Shimizu, T. Yoshida. Application of Machine Learning to the Particle Identification of GAPS. Transactions of Japan Society for Aeronautical and Space Sciences. 2020. 18. 44-50
F. Rogers, S. Boggs, Y. Shimizu. Large-area Si(Li) detectors for X-ray spectrometry and particle tracking in the GAPS experiment. Journal of Instrumentation. 2019. 14. P10009
M. Kozai, H. Fuke, Y. Shimizu, al. Developing a mass-production model of large-area Si(Li) detectors with high operating temperatures. Nuclear Instruments and Methods in Physics Research A. 2019. 947. 162695