A comprehensive calculation of the Primakoff process and the solar axion flux

被引:3
|
作者
Wu, Quan-feng [1 ,2 ]
Xu, Xun-Jie [1 ]
机构
[1] Chinese Acad Sci, Inst High Energy Phys, Beijing 100049, Peoples R China
[2] Univ Chinese Acad Sci, Beijing 100049, Peoples R China
来源
JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS | 2024年 / 07期
基金
中国国家自然科学基金;
关键词
axions; dark matter experiments; solar physics; CONVERSION; SEARCH; BOUNDS;
D O I
10.1088/1475-7516/2024/07/013
中图分类号
P1 [天文学];
学科分类号
0704 ;
摘要
The Primakoff process plays a crucial role in axion production in astrophysical environments and laboratories. Given the rising interest in axion physics and many ongoing experimental activities, we conduct a comprehensive calculation of this process and carefully examine several aspects that have been neglected in the literature. In particular, our calculation is valid for axions with significantly large masses, which would be of importance to axion searches utilizing crystal and liquid xenon detectors. We present the most updated calculation of the Primakoff solar axion flux, with a simple parametrization that is applicable to a broad range of axion masses up to a few tens of keV. Our code is publicly available at GitHub.
引用
收藏
页数:27
相关论文
共 50 条
  • [21] Axion helioscopes as solar thermometers
    Hoof, Sebastian
    Jaeckelc, Joerg
    Thormaehlenc, Lennert J.
    JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS, 2023, (10):
  • [22] Axion helioscopes as solar magnetometers
    O'Hare, Ciaran A. J.
    Caputo, Andrea
    Millar, Alexander J.
    Vitagliano, Edoardo
    PHYSICAL REVIEW D, 2020, 102 (04):
  • [23] The CERN axion solar telescope
    Hasinoff, MD
    Andriamonje, S
    Arik, E
    Autiero, D
    Avignone, F
    Barth, K
    Bingol, E
    Brauninger, H
    Brodzinski, R
    Carmona, J
    Chesi, E
    Cebrian, S
    Cetin, S
    Collar, J
    Creswick, R
    Dafni, T
    De Oliveira, R
    Dedoussis, S
    Delbart, A
    Di Lella, L
    Eleftheriadis, C
    Fanourakis, G
    Farach, H
    Fischer, H
    Formenti, F
    Geralis, T
    Giomataris, I
    Gninenko, S
    Goloubev, N
    Hartmann, R
    Hofmann, D
    Irastorza, IG
    Jacoby, J
    Kang, D
    Konigsmann, K
    Kotthaus, R
    Krcmar, M
    Kuster, M
    Lakic, B
    Liolios, A
    Ljubicic, A
    Lutz, G
    Luzon, G
    Miley, H
    Morales, A
    Morales, J
    Mutterer, M
    Nikolaidis, A
    Ortiz, A
    Papaevangelou, T
    NEW WORLDS IN ASTROPARTICLE PHYSICS, 2003, : 103 - 109
  • [24] Constraints on the axion-electron coupling for solar axions produced by a Compton process and bremsstrahlung
    Derbin, A. V.
    Kayunov, A. S.
    Muratova, V. V.
    Semenov, D. A.
    Unzhakov, E. V.
    PHYSICAL REVIEW D, 2011, 83 (02):
  • [25] A tool for fast flux distribution calculation of parabolic trough solar concentrators
    Song, Jifeng
    Tong, Kai
    Li, Lei
    Luo, Geng
    Yang, Lijun
    Zhao, Jin
    SOLAR ENERGY, 2018, 173 : 291 - 303
  • [26] SIMPLE MODEL FOR CALCULATION OF FLUX OF SOLAR-RADIATION THROUGH ATMOSPHERE
    SHAPIRO, R
    APPLIED OPTICS, 1972, 11 (04): : 760 - &
  • [27] AXION FLUX FROM NASCENT NEUTRON STARS
    HATSUDA, T
    YOSHIMURA, M
    PHYSICS LETTERS B, 1988, 203 (04) : 469 - 473
  • [28] Calculation for flux distribution on focal line of parabolic trough solar concentrators
    Xu, Chengmu
    Li, Ming
    Ji, Xu
    Zhang, Peng
    Taiyangneng Xuebao/Acta Energiae Solaris Sinica, 2015, 36 (03): : 568 - 574
  • [29] Solar flux density calculation for a heliostat with an elliptical Gaussian distribution source
    Huang, Weidong
    Sun, Lulening
    APPLIED ENERGY, 2016, 182 : 434 - 441
  • [30] Axion stabilization in type IIB flux compactifications
    Hristov, Kiril
    JOURNAL OF HIGH ENERGY PHYSICS, 2009, (01):
12345