Update of the atmospheric neutrino flux simulation ATMNC for next-generation neutrino experiment

被引：1

作者：

Sato, K. ^{[1
]}

Itow, Y. ^{[1
,2
]}

Menjo, H. ^{[1
]}

Honda, M. ^{[3
]}

机构：

[1] Nagoya Univ, Inst Space Earth Environm Res, Nagoya, Aichi 4648601, Japan

[2] Nagoya Univ, Kobayashi Maskawa Inst Origin Particles & Univers, Chikusa Ku, Furo Cho, Nagoya, Aichi 4648602, Japan

[3] Univ Tokyo, Inst Cosm Ray Res, 5-1-5 Kashiwa No Ha, Kashiwa, Chiba 2778582, Japan

来源：

16TH INTERNATIONAL CONFERENCE ON TOPICS IN ASTROPARTICLE AND UNDERGROUND PHYSICS (TAUP 2019) | 2020年 / 1468卷

关键词：

ABSORPTION CROSS-SECTIONS; PROTONS; NUCLEI; PIONS;

D O I：

10.1088/1742-6596/1468/1/012194

中图分类号：

P1 [天文学];

学科分类号：

0704 ;

摘要：

Atmospheric neutrino flux calculation ATMNC has greatly contributed to the physics of neutrino experiments including Super-Kamiokande. Since next-generation large-scale experiments, such as Hyper-Kamiokande, are expected a large improvement of statistical errors, it is desirable to reduce systematic errors associated with uncertainty of the flux calculation. The dominant uncertainty of the ATMNC calculation arises from insufficient understanding of the hadron interactions inside air showers caused by cosmic rays. In order to improve the accuracy of the hadron interaction model, many precision measurements for hadron production using accelerator beams have been performed or planned. In this report, we discuss a strategy to update ATMNC calculation to reduce its uncertainty by incorporating such measurements.

引用

页数：3

共 50 条

[41] Atmospheric neutrino flux calculation with FLUKA: update and first results on prompt contribution
Battistoni, G.
Bruno, A.
Cafagna, F.
Desiati, P.
Diaz-Velez, J. C.
Ferrari, A.
Montaruli, T.
Sala, P. R.
Tamburro, A.
PROCEEDINGS OF THE 29TH INTERNATIONAL COSMIC RAY CONFERENCE, VOL 6: HE 1.1, 1.2 & 1.3, 2005, : 309 - 312
[42] Status of RICE and preparations for the next generation radio neutrino experiment in Antarctica
Kravchenko, Ilya
NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2012, 692 : 233 - 235
[43] Development of a Liquid Scintillator Using Water for a Next Generation Neutrino Experiment
So, Sun Heang
Joo, Kyung Kwang
Kim, Ba Ro
Kim, Bong Keon
Kim, Seung Chan
Shin, Chang Dong
Yeo, In Sung
ADVANCES IN HIGH ENERGY PHYSICS, 2014, 2014
[44] Atmospheric neutrino oscillations in the MACRO experiment
Surdo, A
NUCLEAR PHYSICS B-PROCEEDINGS SUPPLEMENTS, 2002, 110 : 342 - 345
[45] MOON for next-generation neutrino-less double-beta decay experiment; present status and perspective
Shima, T.
Doe, P. J.
Ejiri, H.
Elliot, S. R.
Engel, J.
Finger, M., Jr.
Finger, M.
Fushimi, K.
Gehman, V. M.
Greenfield, M. B.
Hazama, R.
Imaseki, H.
Kavitov, P.
Kekelidze, V. D.
Kitamura, H.
Matsuoka, K.
Nakamura, H.
Nomachi, M.
Para, A.
Robertson, R. G. H.
Slunecka, M.
Shirkov, G. D.
Sissakian, A. N.
Titov, A. I.
Uchihori, Y.
Umehara, S.
Vaturin, V.
Voronov, V. V.
Wilkerson, J. F.
Will, D. I.
Yasuda, K.
Yoshida, S.
TAUP2007: TENTH INTERNATIONAL CONFERENCE ON TOPICS IN ASTROPARTICLE AND UNDERGROUND PHYSICS, 2008, 120
[46] Results from the mainz neutrino mass experiment and perspectives of the next generation experiment KATRIN
Bonn, J
PARTICLES AND FIELDS, PROCEEDINGS, 2002, 623 : 189 - 194
[47] Improving the prediction of the Atmospheric neutrino flux using the atmospheric muon flux
Honda, Morihiro
XX INTERNATIONAL SYMPOSIUM ON VERY HIGH ENERGY COSMIC RAY INTERACTIONS (ISVHECRI 2018), 2019, 208
[48] Effect of solar electron temperature on pep solar neutrino flux in the chlorine solar neutrino experiment and the gallium solar neutrino experiment
叶子飘
Journal of Chongqing University, 2005, (03) : 183 - 184
[49] Solar neutrino experiments: The next generation
Bahcall, JN
Calaprice, F
McDonald, AB
Totsuka, Y
PHYSICS TODAY, 1996, 49 (07) : 30 - 36
[50] Triangulation pointing to core-collapse supernovae with next-generation neutrino detectors
Linzer, N. B.
Scholberg, K.
PHYSICAL REVIEW D, 2019, 100 (10):

← 1 2 3 4 5 →