1 |
ABU-ZAYYAD T, BELOV K, BIRD J D, et al.. Evidence for changing of cosmic ray composition between 1017 and 1018 eV from multicomponent measurements. Physical Review Letters, 2000, 84(19), 4276- 4279.
|
2 |
BOGDANOV A G, GROMUSHKIN D M, KOKOULIN R P, et al.. Investigation of the properties of the flux and interaction of ultrahigh-energy cosmic rays by the method of local-muon-density spectra. Physics of Atomic Nuclei, 2010, 73, 1852- 1869.
|
3 |
ENGEL R. Test of hadronic interaction models with data from the Pierre Auger Observatory [EB/OL]. (2007-06-13)[2023-03-01]. https://arxiv.org/abs/0706.1921.
|
4 |
ABBASI R U, ABE M, ABU-ZAYYAD T, et al.. Study of muons from ultrahigh energy cosmic ray air showers measured with the Telescope array experiment. Physical Review D, 2018, 98 (2): 022002.
|
5 |
BOGDANOV A G, KOKOULIN R P, MANNOCCHI G, et al.. Investigation of very high energy cosmic rays by means of inclined muon bundles. Astroparticle Physics, 2018, 98, 13- 20.
|
6 |
FOMIN Y A, KALMYKOV N N, KARPIKOV I S, et al.. No muon excess in extensive air showers at 100–500 PeV primary energy: EAS–MSU results. Astroparticle Physics, 2017, 92, 1- 6.
|
7 |
GONZALEZ J G. Measuring the muon content of air showers with IceTop [C]// EPJ Web of Conferences. [S.l.]: EDP Sciences, 2015, 99: 06002.
|
8 |
APEL W D, ARTEAGA-VELÁZQUEZ J C, BEKK K, et al.. Probing the evolution of the EAS muon content in the atmosphere with KASCADE-Grande. Astroparticle Physics, 2017, 95, 25- 43.
|
9 |
DEMBINSKI H P, ARTEAGA-VELÁZQUEZ J C, CAZON L, et al. Report on tests and measurements of hadronic interaction properties with air showers [C]// EPJ Web of Conferences. [S.l.]: EDP Sciences, 2019, 210: 02004.
|
10 |
CAZON L. Working group report on the combined analysis of muon density measurements from eight air shower experiments [EB/OL]. (2020-01-08)[2023-03-01]. https://arxiv.org/abs/2001.07508.
|
11 |
AAB A, ABREU P, AGLIETTA M, et al.. Muons in air showers at the Pierre Auger Observatory: Mean number in highly inclined events. Physical Review D, 2015, 91 (3): 032003.
|
12 |
AAB A, ABREU P, AGLIETTA M, et al.. Testing hadronic interactions at ultrahigh energies with air showers measured by the Pierre Auger Observatory. Physical Review Letters, 2016, 117 (19): 192001.
|
13 |
BELLIDO J A, CLAY R W, Kalmykov N N, et al.. Muon content of extensive air showers: Comparison of the energy spectra obtained by the Sydney University Giant Air-shower Recorder and by the Pierre Auger Observatory. Physical Review D, 2018, 98 (2): 023014.
|
14 |
ALBRECHT J, CAZON L, DEMBINSKI H, et al. The Muon Puzzle in air showers and its connection to the LHC [J/OL]. Proceedings of Science, 2021, ICRC2021. https://pos.sissa.it/395/037/pdf.
|
15 |
D’ENTERRIA D, PIEROG T, SUN G H.. Impact of QCD jets and heavy-quark production in cosmic-ray proton atmospheric showers up to 1020 eV. The Astrophysical Journal, 2019, 874 (2): 152.
|
16 |
ANCHORDOQUI L A, GOLDBERG H, WEILER T J.. Strange fireball as an explanation of the muon excess in Auger data. Physical Review D, 2017, 95 (6): 063005.
|
17 |
ANCHORDOQUI L A, CANAL C G, SCIUTTO S J, et al.. Through the looking-glass with ALICE into the quark-gluon plasma: A new test for hadronic interaction models used in air shower simulations. Physics Letters B, 2020, 810, 135837.
|
18 |
BAUR S, DEMBINSKI H, PERLIN M, et al.. Core-corona effect in hadron collisions and muon production in air showers. Physical Review D, 2023, 107 (9): 094031.
|
19 |
ALVAREZ-MUNIZ J, CAZON L, CONCEIÇÃO R, et al. Muon production and string percolation effects in cosmic rays at the highest energies [EB/OL]. (2012-09-28)[2023-03-01]. https://arxiv.org/abs/1209.6474.
|
20 |
FARRAR G R, ALLEN J D. A new physical phenomenon in ultra-high energy collisions [C]// EPJ Web of Conferences. [S.l.]: EDP Sciences, 2013, 53: 07007.
|
21 |
BROOIJMANS G, SCHICHTEL P, SPANNOWSKY M.. Cosmic ray air showers from sphalerons. Physics Letters B, 2016, 761, 213- 218.
|
22 |
ALLEN J, FARRAR G. Testing models of new physics with UHE air shower observations [EB/OL]. (2013-07-26)[2023-03-01]. https://arxiv.org/abs/1307.7131.
|
23 |
FARRAR G R, ALLEN J. Evidence for some new physical process in ultrahigh-energy collisions [C]// EPJ Web of Conferences. [S.l.]: EDP Sciences, 2013, 52: 07005.
|
24 |
ACHARYA S, ADAMOVÁ D, ADHYA S P, et al.. Multiplicity dependence of (multi-) strange hadron production in proton-proton collisions at $\sqrt {s} $ = 13 TeV. The European Physical Journal C, 2020, 80, 167.
|
25 |
ANCHORDOQUI L A, CANAL C G, KLING F, et al.. An explanation of the muon puzzle of ultrahigh-energy cosmic rays and the role of the forward physics facility for model improvement. Journal of High Energy Astrophysics, 2022, 34, 19- 32.
|
26 |
ZHU W, SHEN Z Q, RUAN J H.. Can a chaotic solution in the QCD evolution equation restrain high-energy collider physics?. Chinese Physics Letters, 2008, 25 (10): 3605- 3608.
|
27 |
ZHU W, SHEN Z Q, RUAN J H.. The chaotic effects in a nonlinear QCD evolution equation. Nuclear Physics B, 2016, 911, 1- 35.
|
28 |
ZHU W, LAN J S.. The gluon condensation at high energy hadron collisions. Nuclear Physics B, 2017, 916, 647- 668.
|
29 |
ZHU W, CHEN Q H, CUI Z Y, et al.. The gluon condensation in hadron collisions. Nuclear Physics B, 2022, 984, 115961.
|
30 |
ZHU W, LAN J S, RUAN J H.. The gluon condensation in high energy cosmic rays. International Journal of Modern Physics E, 2018, 27 (9): 1850073.
|
31 |
LIU P, RUAN J H.. A possible connection of the broken power-law between electron-and proton-spectra in cosmic rays. International Journal of Modern Physics E, 2019, 28 (9): 1950073.
|
32 |
ZHENG Z C, CUI Z Y, RUAN J H.. Research on the structure of cosmic-ray electron and positron fluxes in GeV–TeV energy range. International Journal of Modern Physics E, 2022, 31 (1): 2250012.
|
33 |
ZHU W, ZHENG Z C, LIU P, et al.. Looking for the possible gluon condensation signature in sub-TeV gamma-ray spectra: From active galactic nuclei to gamma ray bursts. Journal of Cosmology and Astroparticle Physics, 2021, (1): 038.
|
34 |
ZHU W, LIU P, RUAN J H, et al.. Anomalous bremsstrahlung and the structure of cosmic-ray electron–positron fluxes at the GeV–TeV energy range. The Astrophysical Journal, 2020, 896 (2): 106.
|
35 |
ZHU W, LIU P, RUAN J H, et al.. Possible evidence for the gluon condensation effect in cosmic positron and gamma-ray spectra. The Astrophysical Journal, 2020, 889 (2): 127.
|
36 |
ZHU W, LIU P, RUAN J H, et al.. The gluon condensation effect in the cosmic hadron spectra. Journal of Cosmology and Astroparticle Physics, 2020, (9): 011.
|
37 |
RUAN J H, ZHENG Z C, ZHU W.. Exploring the possible gluon condensation signature in gamma-ray emission from pulsars. Journal of Cosmology and Astroparticle Physics, 2021, 2021 (8): 065.
|
38 |
GRIBOV V N, LIPATOV L N. Deep inelastic ep-Scattering in a perturbation theory [R]. Institute of Nuclear Physics, Leningrad, 1972.
|
39 |
DOKSHITZER Y L.. Calculation of the structure functions for deep inelastic scattering and e+e– annihilation by perturbation theory in quantum chromodynamics. Zhurnal Eksperimentalnoi I Teoreticheskoi Fiziki, 1977, 73, 1216- 1240.
|
40 |
ALTARELLI G, PARISI G.. Asymptotic freedom in parton language. Nuclear Physics B, 1977, 126 (2): 298- 318.
|
41 |
LIPATOV L N.. Reggeization of the vector meson and the vacuum singularity in nonabelian gauge theories. Yadernaya Fizika, 1976, 23 (3): 642- 656.
|
42 |
FADIN V S, KURAEV E A, LIPATOV L N.. On the Pomeranchuk singularity in asymptotically free theories. Physics Letters B, 1975, 60 (1): 50- 52.
|
43 |
KURAEV E A, LIPATOV L N, FADIN V S.. Multireggeon processes in the Yang-Mills theory. Zhurnal Eksperimentalnoi I Teoreticheskoi Fiziki, 1976, 71, 840- 855.
|
44 |
KURAEV E A, LIPATOV L N, FADIN V S.. The Pomeranchuk singularity in nonabelian gauge theories. Zhurnal Eksperimentalnoi I Teoreticheskoi Fiziki, 1977, 72, 377- 389.
|
45 |
BALITSKY Y Y, LIPATOV L N.. The Pomeranchuk singularity in quantum chromodynamics. Soviet Journal of Nuclear Physics-Ussr, 1978, 28 (6): 822- 829.
|
46 |
GRIBOV L V, LEVIN E M, RYSKIN M G.. Semihard processes in QCD. Physics Reports, 1983, 100 (1/2): 1- 150.
|
47 |
MUELLER A H, QIU J W.. Gluon recombination and shadowing at small values of x. Nuclear Physics B, 1986, 268 (2): 427- 452.
|
48 |
BALITSKY I.. Operator expansion for high-energy scattering. Nuclear Physics B, 1996, 463 (1): 99- 157.
|
49 |
KOVCHEGOV Y V.. Small-x F2 structure function of a nucleus including multiple Pomeron exchanges. Physical Review D, 1999, 60 (3): 034008.
|
50 |
KOVCHEGOV Y V.. Unitarization of the BFKL pomeron on a nucleus. Physical Review D, 2000, 61 (7): 074018.
|
51 |
RAFELSKI J, MÜLLER B.. Strangeness production in the quark-gluon plasma. Physical Review Letters, 1982, 48 (16): 1066- 1069.
|
52 |
CANAL C A G, SCIUTTO S J, TARUTINA T.. Testing hadronic-interaction packages at cosmic-ray energies. Physical Review D, 2009, 79 (5): 054006.
|
53 |
FENG X T, ZHANG H Y, FENG C F, et al. Measuring the attenuation length of muon number in the air shower with muon detectors of 3/4 LHAASO array [EB/OL]. (2022-10-05)[2023-03-01]. https://arxiv.org/abs/2207.12117.
|