Machine Learning for Multi-messenger Probes of New Physics and Cosmology: A Review and Perspective

Author(s)

Addazi, Andrea, Belotsky, Konstantin, Beylin, Vitaly, Bikbaev, Timur, Chen, Deen, Fabrocini, Filippo, Giagu, Stefano, Jinklub, Krid, Kharakhashyan, Artem, Khlopov, Maxim, Korchagin, Vladimir, Krasnov, Maxim, Mahajan, Atharv, Marciano, Antonino, Mayorov, Andrey, Morais, Antonio, Pasechnik, Roman, Levi Said, Jackson, Sopin, Danila, Stasenko, Viktor, Trivedi, Oem

Abstract

The multi-messenger exploration of dark matter and physics beyond the Standard Model has emerged as a central direction in modern astro-particle physics, particularly following the discovery of gravitational waves. In this work, we present a comprehensive review and forward-looking perspective on machine-learning-enhanced multi-messenger approaches, combining information from gravitational waves, cosmic rays, gamma rays, neutrinos, and collider experiments. We summarize the current state of the field, discuss recent methodological developments, and outline a coherent research program aimed at integrating heterogeneous datasets within a unified inference framework. Our collaboration proposes here a plan for forthcoming analyses aiming at extracting information on the properties and interactions of dark matter, and finally on its genesis, combining multi-messenger astronomy techniques and inputs from laboratory physics. The main objectives planned in this line of research comprise: i) the multi-messenger analysis of new physics in cosmology, including mainly, but not only, several different models of dark matter; ii) the phenomenology of new physics signatures in ground-based cosmic rays experiments, with cross-correlation to the corresponding physical, astrophysical and cosmological observations; iii) the development of machine learning methods for data analysis in ground-based cosmic rays experiments, in light of the new physics signatures. We note that several groups have explored the use of multi-messenger observations, including gravitational waves, to probe alternative dark matter candidates. The present work builds on these developments by focusing on the role of machine learning in integrating heterogeneous datasets. We foresee that such a cross-fertilizing approach will represent the right path to extract information about the main questions left in fundamental physics.

Figures

Caption

Demonstration of likelihood-free inference (LFI) using a simulation-based approximate posterior in a 1D toy cosmological parameter estimation task. Unlike traditional Bayesian inference, which requires an analytical likelihood, this approach uses distance-weighted simulation outputs to recover the posterior around the true parameter value. Such methods are foundational in machine learning-based cosmological inference pipelines where forward simulations are available but explicit likelihoods are intractable.

Caption

Convolutional Neural Network (CNN) trained to estimate the cosmological parameter $\Omega_m$ directly from synthetic 2D "sky map" images. The left panel shows the training and validation mean squared error (MSE) loss over epochs, indicating successful learning. The right panel compares predicted and true $\Omega_m$ values on held-out data, demonstrating the model’s strong regression performance. This illustrates the potential of CNN-based inference in cosmology.

Caption

Figure 6, from \cite{BENTO2025139690}, shows a schematic representation of the PINN structure. This is relevant to tackle inverse problems while modeling the Boltzmann equation for freeze-in DM particle yield, in alternative cosmology.

References

[1] Planck Collaboration, Astronomy & Astrophysics 641, A1 (2020), 1807.06205.
[2] ACT Collaboration, Journal of Cosmology and Astroparticle Physics 12, 047 (2020), 2007.07288.
[3] H. Li et al., National Science Review 6, 145 (2019).
[4] A. Addazi, K. Belotsky, V. Beylin, et al., in 37th International Cosmic Ray Conference (ICRC 2021) (2021), p. 474.
[5] HAWC Collaboration, Astrophysical Journal 843, 39 (2017), 1701.01778.
[6] H.E.S.S. Collaboration, Astronomy & Astrophysics 457, 899 (2006), astro-ph/0607333.
[7] M. G. Aartsen, M. Ackermann, et al., Physical Review Letters 113, 101101 (2014), 1405.5303.
[8] L. Evans and P. Bryant, Journal of Instrumentation 3, S08001 (2008).
[9] G. Apollinari et al., CERN Yellow Reports: Monographs 4 (2017).
[10] CEPC Study Group, arXiv:1811.10545 (2018).
[11] B. P. Abbott, R. Abbott, et al., Physical Review Letters 116, 061102 (2016).
[12] P. Amaro-Seoane et al., Laser interferometer space antenna (2017), 1702.00786.
[13] S. Kawamura et al., Classical and Quantum Gravity 28, 094011 (2011).
[14] J. Crowder and N. J. Cornish, Physical Review D 72, 083005 (2005).
[15] R. Nan et al., International Journal of Modern Physics D 20, 989 (2011).
[16] P. E. Dewdney et al., Proceedings of the IEEE 97, 1482 (2009).
[17] G. Hobbs et al., Classical and Quantum Gravity 27, 084013 (2010).
[18] G. Di Sciascio, Nuclear and Particle Physics Proceedings 279-281, 166 (2016), 1602.07600.
[19] X. Bai, B. Y. Bi, X. J. Bi, Z. Cao, et al., The large high altitude air shower observatory (lhaaso) science white paper (2019), 1905.02773.
[20] G. G. Madejski and M. Sikora, Annual Review of Astronomy and Astrophysics 54, 725 (2016).
[21] M. Ajello et al., Astrophysical Journal Supplement Series (2022), 2209.12070.
[22] A. Addazi, S. Ketov, M. Khlopov, and A. Marciano, International Journal of Modern Physics D 27, 1841011 (2018).
[23] R. D. Peccei and H. R. Quinn, Physical Review Letters 38, 1440 (1977).
[24] F. Wilczek, Physical Review Letters 40, 279 (1978).
[25] S. Weinberg, Physical Review Letters 40, 223 (1978).
[26] J. E. Kim, Physical Review Letters 43, 103 (1979).
[27] M. A. Shifman, A. I. Vainshtein, and V. I. Zakharov, Nuclear Physics B 166, 493 (1980).
[28] A. R. Zhitnitsky, Soviet Journal of Nuclear Physics 31, 260 (1980).
[29] F. Wilczek, Physical Review Letters 49, 1549 (1982).
[30] Z. G. Berezhiani and M. Y. Khlopov, Zeitschrift für Physik C 49, 73 (1991).
[31] Y. Chikashige, R. N. Mohapatra, and R. D. Peccei, Physics Letters B 98, 265 (1981).
[32] G. B. Gelmini and M. Roncadelli, Physics Letters B 99, 411 (1981).
[33] Z. Berezhiani, European Physical Journal C 76, 705 (2016), 1507.05478.
[34] E. Witten, Physics Letters B 149, 351 (1984).
[35] J. P. Conlon, Journal of High Energy Physics 05, 078 (2006), hep-th/0602233.
[36] P. Svrcek and E. Witten, Journal of High Energy Physics 06, 051 (2006), hep-th/0605206.
[37] R. D. Peccei and H. R. Quinn, Physical Review Letters 38, 1440 (1977).
[38] R. D. Peccei and H. R. Quinn, Physical Review D 16, 1791 (1977).
[39] S. Weinberg, Physical Review Letters 40, 223 (1978).
[40] F. Wilczek, Physical Review Letters 40, 279 (1978).
[41] D. A. Dicus et al., Physical Review D 18, 1829 (1978).
[42] G. Raffelt and L. Stodolsky, Physical Review D 37, 1237 (1988).
[43] S. Andriamonje et al., Journal of Cosmology and Astroparticle Physics 0704, 010 (2007).
[44] A. De Angelis, M. Roncadelli, and O. Mansutti, Physical Review D 76, 121301 (2007).
[45] A. De Angelis, O. Mansutti, M. Persic, and M. Roncadelli, Monthly Notices of the Royal Astronomical Society 394, L21 (2009).
[46] A. Mirizzi and D. Montanino, Journal of Cosmology and Astroparticle Physics 12, 004 (2009).
[47] M. Simet, D. Hooper, and P. D. Serpico, Physical Review D 77, 063001 (2008).
[48] A. Mirizzi, G. G. Raffelt, and P. D. Serpico, Lecture Notes in Physics 741, 115 (2008).
[49] A. Nikishov, Soviet Physics JETP 14, 393 (1962).
[50] G. G. Fazio and F. W. Stecker, Nature 226, 135 (1970).
[51] F. Aharonian, Very High Energy Cosmic Gamma Radiation (World Scientific, Singapore, 2004).
[52] A. Dolgov and K. Freese, Physical Review D 51, 2693 (1995).
[53] A. Dolgov, K. Freese, R. Rangarajan, and M. Srednicki, Physical Review D 56, 6155 (1997).
[54] A. G. Cohen and D. B. Kaplan, Nuclear Physics B 308, 913 (1988).
[55] Y. B. Zeldovich and I. D. Novikov, Astronomicheskii Zhurnal 10, 602 (1967).
[56] S. W. Hawking, Monthly Notices of the Royal Astronomical Society 152, 75 (1971).
[57] B. J. Carr and S. W. Hawking, Monthly Notices of the Royal Astronomical Society 168, 399 (1974).
[58] S. W. Hawking, I. G. Moss, and J. M. Stewart, Physical Review D 26, 2681 (1982).
[59] B. Carr and F. Kühnel, Annual Review of Nuclear and Particle Science 70, 355 (2020).
[60] B. Carr, K. Kohri, Y. Sendouda, and J. Yokoyama, Reports on Progress in Physics 84, 116902 (2021).
[61] V. De Luca, V. Desjacques, G. Franciolini, and A. Riotto, Journal of Cosmology and Astroparticle Physics 11, 028 (2020).
[62] K. M. Belotsky, V. I. Dokuchaev, Y. N. Eroshenko, E. A. Esipova, M. Y. Khlopov, L. A. Khromykh, A. A. Kirillov, V. V. Nikulin, S. G. Rubin, and I. V. Svadkovsky, European Physical Journal C 79, 246 (2019).
[63] V. Berezin, V. Dokuchaev, Y. Eroshenko, and A. Smirnov, Universe 6, 158 (2020).
[64] J. Garcı́a-Bellido and S. Clesse, Physics of the Dark Universe 19, 144 (2018).
[65] J. Calcino, J. Garcı́a-Bellido, and T. M. Davis, Monthly Notices of the Royal Astronomical Society 479, 2889 (2018).
[66] S. W. Hawking, Physics Letters B 231, 237 (1989).
[67] J. Garcı́a-Bellido, A. Linde, and D. Wands, Physical Review D 54, 6040 (1996).
[68] S. G. Rubin, A. S. Sakharov, and M. Y. Khlopov, Journal of Experimental and Theoretical Physics 92, 921 (2001).
[69] J. Garcı́a-Bellido et al., Classical and Quantum Gravity 36, 143001 (2019).
[70] V. V. Nikulin, M. A. Krasnov, and S. G. Rubin, Frontiers in Astronomy and Space Sciences 9 (2022), URL https: //www.frontiersin.org/articles/10.3389/fspas.2022.927144.
[71] S. Capozziello and M. De Laurentis, Annalen der Physik 524 (2012).
[72] A. De Felice and S. Tsujikawa, Living Reviews in Relativity 13 (2010).
[73] S. Capozziello and M. De Laurentis, Physics Reports 509, 167 (2011), URL https://www.sciencedirect.com/science/ article/pii/S0370157311002432.
[74] M. Krasnov and K. Belotsky, Physics of Atomic Nuclei 86, 1533 (2023).
[75] K. Belotsky, M. Krasnov, and S. Pugachev, International Journal of Modern Physics D 33, 2340010 (2024).
[76] R. Pasechnik, V. Beylin, V. Kuksa, and G. Vereshkov, Physical Review D 88, 075009 (2013).
[77] N. Volchanskiy, V. Kuksa, and V. Beylin, International Journal of Modern Physics D 28, 1941002 (2018).
[78] R. Pasechnik, V. Beylin, V. Kuksa, and G. Vereshkov, International Journal of Modern Physics A 31, 1650036 (2016).
[79] V. Kuksa and V. Beylin, International Journal of Modern Physics D 30, 2140006 (2021).
[80] J. Aalbers et al., Physical Review Letters 131, 041002 (2023).
[81] E. Aprile et al., Physical Review Letters 119, 181301 (2017).
[82] V. Kuksa and V. Beylin, Symmetry 12, 1906 (2020).
[83] V. Beylin and V. Kuksa, Symmetry 12, 567 (2020).
[84] V. Kuksa and V. Beylin, Universe 6, 84 (2020).
[85] V. Beylin, M. Bezuglov, V. Kuksa, and N. Volchanskiy, Advances in High Energy Physics p. 1765340 (2017).
[86] V. Beylin, M. Bezuglov, V. Kuksa, and E. Tretiakov, Symmetry 12, 708 (2020).
[87] V. Beylin and M. Bezuglov, International Journal of Modern Physics D 30, 2140009 (2021).
[88] V. Beylin and M. Bezuglov, Physics of Particles and Nuclei Letters 20, 495 (2023).
[89] V. Beylin, M. Khlopov, V. Kuksa, and N. Volchanskiy, Universe 6, 196 (2020).
[90] G. F. Giudice and M. McCullough, Journal of High Energy Physics 02, 036 (2017).
[91] K. M. Patel, Physical Review D 96, 115013 (2017), 1711.05393.
[92] M. Y. Khlopov, International Journal of Modern Physics A 28, 1330042 (2013), 1311.2468.
[93] E. Aprile and S. Profumo, New Journal of Physics 11, 105002 (2009).
[94] J. L. Feng, Annual Review of Astronomy and Astrophysics 48, 495 (2010), 1003.0904.
[95] M. Khlopov, Symmetry 8, 81 (2016).
[96] M. Y. Khlopov and C. Kouvaris, Physical Review D 77, 065002 (2008), 0710.2189.
[97] M. Y. Khlopov and C. Kouvaris, Physical Review D 78, 065040 (2008), 0806.1191.
[98] S. L. Glashow, A sinister extension of the standard model to su(3) × su(2) × su(2) × u(1) (2005), hep-ph/0504287.
[99] D. Fargion and M. Y. Khlopov, Gravitation and Cosmology 19, 219 (2013), hep-ph/0507087.
[100] M. Y. Khlopov, JETP Letters 83, 1 (2006), astro-ph/0511796.
[101] D. Fargion, M. Khlopov, and C. A. Stephan, Classical and Quantum Gravity 23, 7305 (2006), astro-ph/0511789.
[102] M. Khlopov, Journal of Physics: Conference Series 1312, 012011 (2019).
[103] Y. B. Zeldovich and M. Y. Khlopov, Soviet Physics Uspekhi 24, 755 (1981).
[104] S. I. Blinnikov and M. Y. Khlopov, Soviet Journal of Nuclear Physics 36, 472 (1982).
[105] S. I. Blinnikov and M. Y. Khlopov, Soviet Astronomy 27, 371 (1983).
[106] M. Y. Khlopov, G. M. Beskin, N. G. Bochkarev, L. A. Pustilnik, and S. A. Pustilnik, Soviet Astronomy 35, 21 (1991).
[107] Z. Berezhiani, D. Comelli, and F. Villante, Physics Letters B 503, 362 (2001).
[108] Z. Berezhiani, International Journal of Modern Physics A 19, 3775 (2004).
[109] C. Bozzaa, A. Calivàa, A. De Caro, et al., Generative artificial intelligence for air shower simulation (2025), 2510.26316.
[110] V. Beylin, in Proceedings of the 25th Workshop “What Comes Beyond the Standard Model” (Bled, Slovenia, 2022), 2211.09054.
[111] A. Abdul Halim, P. Abreu, M. Aglietta, et al., Physical Review Letters 134, 021001 (2025).
[112] O. Adriani et al., An anomalous positron abundance in cosmic rays with energies 1.5-100 gev (2008), 0810.4995.
[113] AMS Collaboration, Physical Review Letters 113, 121101 (2014).
[114] M. Ackermann et al., Physical Review Letters 108, 011103 (2012).
[115] DAMPE Collaboration, Nature 552, 63 (2017).
[116] M. Y. Khlopov, Fundamentals of Cosmic Particle Physics (CISP-Springer, Cambridge, UK, 2012).
[117] A. Neronov and D. Semikoz, Lhaaso sensitivity for diffuse gamma-ray signals from the galaxy (2020), 2001.11881.
[118] P. Huang, A. J. Long, and L. T. Wang, Physical Review D 94, 075008 (2016), 1608.06619.
[119] A. Alves, T. Ghosh, H. K. Guo, and K. Sinha, Journal of High Energy Physics 12, 070 (2018), 1808.08974.
[120] A. Alves, D. Gonçalves, T. Ghosh, H. K. Guo, and K. Sinha, Journal of High Energy Physics 03, 053 (2020), 1909.05268.
[121] A. P. Morais and R. Pasechnik, Journal of Cosmology and Astroparticle Physics 2004, 036 (2020), 1910.00717.
[122] A. Addazi, A. Marcianò, A. P. Morais, R. Pasechnik, R. Srivastava, and J. W. F. Valle, Physics Letters B 807, 135577 (2020), 1909.09740.
[123] T. Vieu, A. P. Morais, and R. Pasechnik, Journal of Cosmology and Astroparticle Physics 1807, 014 (2018), 1801.02670.
[124] J. Gonçalves, D. Marfatia, A. P. Morais, and R. Pasechnik, Journal of High Energy Physics 02, 110 (2025), 2412.02645.
[125] J. Gonçalves, D. Marfatia, A. P. Morais, and R. Pasechnik, Physics Letters B 869, 139829 (2025), 2501.11619.
[126] M. Bertenstam, M. Finetti, A. P. Morais, R. Pasechnik, and J. Rathsman, Journal of Cosmology and Astroparticle Physics 08, 077 (2025), 2501.01286.
[127] S. Balaji, J. Gonçalves, D. Marfatia, A. P. Morais, and R. Pasechnik, Journal of Cosmology and Astroparticle Physics 10, 064 (2025), 2505.08011.
[128] A. Addazi, A. Marcianò, and R. Pasechnik, Physics 1, 92 (2019), 1811.09074.
[129] J. E. Camargo-Molina, A. P. Morais, A. Ordell, R. Pasechnik, and J. Wessén, Physical Review D 99, 035041 (2019), 1711.05199.
[130] J. E. Camargo-Molina, A. P. Morais, A. Ordell, R. Pasechnik, M. O. P. Sampaio, and J. Wessén, Physical Review D 95, 075031 (2017), 1610.03642.
[131] K. K. Y. Ng, G. Franciolini, E. Berti, P. Pani, A. Riotto, and S. Vitale, Astrophysical Journal Letters 933, L41 (2022), 2204.11864.
[132] K. K. Y. Ng, B. Goncharov, S. Chen, S. Borhanian, U. Dupletsa, G. Franciolini, M. Branchesi, J. Harms, M. Maggiore, A. Riotto, et al., Physical Review D 107, 024041 (2023), 2210.03132.
[133] G. Franciolini, F. Iacovelli, M. Mancarella, M. Maggiore, P. Pani, and A. Riotto, Physical Review D 108, 043506 (2023), 2304.03160.
[134] E. Bagui et al., Living Reviews in Relativity 28, 1 (2025), 2310.19857.
[135] B. P. Abbott et al., Physical Review Letters 116, 061102 (2016), 1602.03837.
[136] S. Bird, I. Cholis, J. B. Muñoz, Y. Ali-Haı̈moud, M. Kamionkowski, E. D. Kovetz, A. Raccanelli, and A. G. Riess, Physical Review Letters 116, 201301 (2016), 1603.00464.
[137] M. Sasaki, T. Suyama, T. Tanaka, and S. Yokoyama, Physical Review Letters 117, 061101 (2016), erratum: Phys. Rev. Lett. 121, no.5, 059901 (2018), 1603.08338.
[137] M. Sasaki, T. Suyama, T. Tanaka, and S. Yokoyama, Physical Review Letters 117, 061101 (2016), erratum: Phys. Rev. Lett. 121, no.5, 059901 (2018), 1603.08338.
[138] S. Clesse and J. Garcı́a-Bellido, Physics of the Dark Universe 15, 142 (2017), 1603.05234.
[139] S. Blinnikov, A. Dolgov, N. K. Porayko, and K. Postnov, Journal of Cosmology and Astroparticle Physics 11, 036 (2016), 1611.00541.
[140] Y. Ali-Haı̈moud, E. D. Kovetz, and M. Kamionkowski, Physical Review D 96, 123523 (2017), 1709.06576.
[141] M. Raidal, C. Spethmann, V. Vaskonen, and H. Veermäe, Journal of Cosmology and Astroparticle Physics 02, 018 (2019), 1812.01930.
[142] T. Nakamura, M. Sasaki, T. Tanaka, and K. S. Thorne, Astrophysical Journal Letters 487, L139 (1997), astro-ph/9708060.
[143] K. Ioka, T. Chiba, T. Tanaka, and T. Nakamura, Physical Review D 58, 063003 (1998), astro-ph/9807018.
[144] G. Franciolini, K. Kritos, E. Berti, and J. Silk, Physical Review D 106, 083529 (2022), 2205.15340.
[145] N. Afshordi, P. McDonald, and D. N. Spergel, Astrophysical Journal Letters 594, L71 (2003), astro-ph/0302035.
[146] D. Inman and Y. Ali-Haı̈moud, Physical Review D 100, 083528 (2019), 1907.08129.
[147] M. Tkachev, S. Pilipenko, and G. Yepes, Monthly Notices of the Royal Astronomical Society 499, 4854 (2020), 2009.07813.
[148] M. A. Amin, M. S. Delos, and M. Mirbabayi, Structure formation with warm white noise: Effects of finite number density and velocity dispersion in particle and wave dark matter (2025), 2503.20881.
[149] V. Vaskonen and H. Veermäe, Physical Review D 101, 043015 (2020), 1908.09752.
[150] K. Jedamzik, Journal of Cosmology and Astroparticle Physics 09, 022 (2020), 2006.11172.
[151] M. S. Delos, A. Rantala, S. Young, and F. Schmidt, Journal of Cosmology and Astroparticle Physics 12, 005 (2024), 2410.01876.
[152] V. Stasenko and K. Belotsky, Monthly Notices of the Royal Astronomical Society 526, 4308 (2023), 2307.12924.
[153] V. Stasenko, Physical Review D 109, 123546 (2024), 2403.11325.
[154] V. Stasenko, Physics of Particles and Nuclei 56, 152 (2025).
[155] S. G. Rubin, A. S. Sakharov, and M. Y. Khlopov, Journal of Experimental and Theoretical Physics 91, 921 (2001), hep-ph/0106187.
[156] M. Y. Khlopov, S. G. Rubin, and A. S. Sakharov, Astroparticle Physics 23, 265 (2005), astro-ph/0401532.
[157] S. Young and C. T. Byrnes, Journal of Cosmology and Astroparticle Physics 04, 034 (2015), 1503.01505.
[158] T. Suyama and S. Yokoyama, Progress of Theoretical and Experimental Physics 2019, 103E02 (2019), 1906.04958.
[159] Q. Ding, T. Nakama, J. Silk, and Y. Wang, Physical Review D 100, 103003 (2019), 1903.07337.
[160] T. Bringmann, P. F. Depta, V. Domcke, and K. Schmidt-Hoberg, Physical Review D 99, 063532 (2019), 1808.05910.
[161] S. Young and C. T. Byrnes, Journal of Cosmology and Astroparticle Physics 03, 004 (2020), 1910.06077.
[162] V. D. Stasenko and A. A. Kirillov, Physics 3, 372 (2021), 2105.14523.
[163] V. D. Stasenko, A. A. Kirillov, and K. M. Belotsky, Universe 8, 41 (2022), 2111.13451.
[164] Y. Eroshenko and V. Stasenko, Symmetry 15, 637 (2023), 2302.05167.
[165] V. Stasenko, Physics of Atomic Nuclei 88, 524 (2025).
[166] V. Stasenko, Physics of the Dark Universe 50, 102138 (2025), 2506.11290.
[167] M. Braglia, J. Garcia-Bellido, and S. Kuroyanagi, Journal of Cosmology and Astroparticle Physics 12, 012 (2021), 2110.07488.
[168] J. Garcı́a-Bellido, S. Jaraba, and S. Kuroyanagi, Physics of the Dark Universe 36, 101009 (2022), 2109.11376.
[169] S. Mukherjee and J. Silk, Monthly Notices of the Royal Astronomical Society 506, 3977 (2021), 2105.11139.
[170] V. Atal, J. J. Blanco-Pillado, A. Sanglas, and N. Triantafyllou, Physical Review D 105, 123522 (2022), 2201.12218.
[171] B. J. Kavanagh, D. Gaggero, and G. Bertone, Physical Review D 98, 023536 (2018), 1805.09034.
[172] S. Pilipenko, M. Tkachev, and P. Ivanov, Physical Review D 105, 123504 (2022), 2205.10792.
[173] P. Jangra, B. J. Kavanagh, and J. M. Diego, Journal of Cosmology and Astroparticle Physics 11, 069 (2023), 2304.05892.
[174] V. D. Stasenko and Y. N. Eroshenko, Astronomy Letters 50, 431 (2024), 2412.20859.
[175] L. Berezhiani, G. Cintia, V. De Luca, and J. Khoury, Journal of Cosmology and Astroparticle Physics 06, 024 (2024), 2311.07672.
[176] K. Kadota, J. H. Kim, P. Ko, and X. Y. Yang, Physical Review D 109, 015022 (2024), 2306.10828.
[177] M. S. Fischer and L. Sagunski, Astronomy and Astrophysics 690, A299 (2024), 2405.19392.
[178] J. C. Aurrekoetxea, J. Marsden, K. Clough, and P. G. Ferreira, Physical Review D 110, 083011 (2024), 2409.01937.
[179] G. Alonso-Álvarez, J. M. Cline, and C. Dewar, Physical Review Letters 133, 021401 (2024), 2401.14450.
[180] J. Luo et al., Classical and Quantum Gravity 33, 035010 (2016), 1512.02076.
[181] D. Reitze, R. X. Adhikari, S. Ballmer, B. Barish, L. Barsotti, G. Billingsley, D. A. Brown, Y. Chen, D. Coyne, R. Eisenstein, et al., Bulletin of the American Astronomical Society 51, 035 (2019), 1907.04833.
[182] M. Maggiore et al., Journal of Cosmology and Astroparticle Physics 03, 050 (2020), 1912.02622.
[183] A. Abac et al., The science of the einstein telescope (2025), 2503.12263.
[184] E. Witten, Communications in Mathematical Physics 121, 351 (1989).
[185] V. F. R. Jones, in Fields Medallists’ Lectures (1997), pp. 448–458.
[186] F. Jaeger, D. L. Vertigan, and D. J. Welsh, in Mathematical Proceedings of the Cambridge Philosophical Society (Cambridge University Press, 1990), vol. 108, pp. 35–53.
[187] E. Bernstein and U. Vazirani, SIAM Journal on Computing 26, 1411 (1997).
[188] R. Raz and A. Tal, in Proceedings of the 51st Annual ACM SIGACT Symposium on Theory of Computing (2019), pp. 13–23.
[189] F. M. Neto, T. B. Ludermir, W. R. Oliveira, and A. J. Silva, in 2015 Brazilian Conference on Intelligent Systems (BRACIS) (IEEE, 2015), pp. 258–263.
[190] D. Ruppert, M. P. Wand, and R. J. Carroll, Semiparametric Regression (Cambridge University Press, 2003).
[191] P. Battaglia, R. Pascanu, M. Lai, D. Jimenez Rezende, and K. Kavukcuoglu, Interaction networks for learning about objects, relations and physics (2016).
[192] H. Dai, Y. Tian, B. Dai, S. Skiena, and L. Song, Syntax-directed variational autoencoder for structured data (2018), 1802.08786.
[193] A. Ciardiello, M. Asai, B. Caccia, G. A. P. Cirrone, M. Colonna, A. Dotti, R. Faccini, S. Giagu, A. Messina, P. Napolitani, et al., Physica Medica 73, 65 (2020), 2004.04961.
[194] N. Steinle and S. Safi-Harb, Phys. Rev. D 112, 103038 (2025), URL https://link.aps.org/doi/10.1103/tf4z-71rt.
[195] J. Lin, W. Bhimji, and B. Nachman, Journal of High Energy Physics 05, 181 (2019), 1903.02556.
[196] G. Aad et al., Search for direct production of electroweakinos in final states with one lepton, missing transverse momentum and a higgs boson decaying into two b-jets in pp collisions at √ s = 13 tev with the atlas detector (2019), 1909.09226.
[197] G. E. Karniadakis, I. G. Kevrekidis, L. Lu, P. Perdikaris, S. Wang, and L. Yang, Nature Reviews Physics 3, 422 (2021).
[198] D. Guest, K. Cranmer, and D. Whiteson, Annual Review of Nuclear and Particle Science 68, 161 (2018), 1806.11484.
[199] A. Radovic, M. Williams, D. Rousseau, M. Kagan, D. Bonacorsi, A. Himmel, A. Aurisano, K. Terao, and T. Wongjirad, Nature 560, 41 (2018).
[200] K. Zhou, L. Wang, L. G. Pang, and S. Shi, Progress in Particle and Nuclear Physics 135, 104084 (2024), 2303.15136.
[201] P. Shanahan, K. Terao, D. Whiteson, G. Aarts, A. Adelmann, N. Akchurin, A. Alexandru, O. Amram, A. Andreassen, A. Apresyan, et al., Snowmass 2021 computational frontier compf03 topical group report: Machine learning (2022), 2209.07559.
[202] L. Smith, M. Scialpi, F. di Clemente, and M. Bejger, Pinngrape: Physics informed neural network for gravitational wave parameter estimation (2025), 2510.02858, URL https://arxiv.org/abs/2510.02858.
[203] A. K. Mishra and E. Tolley, The Astrophysical Journal 988, 114 (2025), URL https://doi.org/10.3847/1538-4357/ ade43e.
[204] M. Bento, H. Câmara, and J. Seabra, Physics Letters B 868, 139690 (2025), ISSN 0370-2693, URL https://www. sciencedirect.com/science/article/pii/S0370269325004514.
[205] P. Humphreys, The Oxford Handbook of Philosophy of Science (Oxford University Press, 2016).
[206] K. Popper, The Logic of Scientific Discovery (Routledge, 2005).
[207] R. Roscher, B. Bohn, M. F. Duarte, and J. Garcke, IEEE Access 8, 42200 (2020).
[208] L. Wang, Physical Review B 94, 195105 (2016).
[209] G.-W. Yuan, M. Calzà, and D. Pedrotti, Physics of the Dark Universe 50, 102078 (2025), ISSN 2212-6864, URL https: //www.sciencedirect.com/science/article/pii/S2212686425002717.
[210] G. Futia and A. Vetrò, Information 11, 122 (2020).
[211] P. Napolitani, M. Colonna, and M. Di Prima, Journal of Physics: Conference Series 515, 012014 (2014), 1402.4121.
[212] J. Duarte et al., Journal of Instrumentation 13, P07027 (2018).
[213] S. Francescato, S. Giagu, F. Riti, G. Russo, L. Sabetta, and F. Tortonesi, European Physical Journal C 81, 969 (2021).
[214] V. Belis, P. Odagiu, and T. K. Aarrestad, Reviews in Physics 12, 100091 (2024).
[215] F. Riehn, R. Engel, A. Fedynitch, T. K. Gaisser, and T. Stanev, The hadronic interaction model sibyll 2.3c and extensive air showers (2019), 1912.03300.
[216] S. Ostapchenko, Physical Review D 83, 014018 (2011), 1010.1869.
[217] T. Pierog, I. Karpenko, J. M. Katzy, E. Yatsenko, and K. Werner, Physical Review C 92, 034906 (2015), 1306.0121.
[218] M. Cranmer, A. Sanchez-Gonzalez, P. Battaglia, R. Xu, K. Cranmer, D. Spergel, and S. Ho, Discovering symbolic models from deep learning with inductive biases (2020), 2006.11287.
[219] S. R. Coleman, Physical Review D 15, 2929 (1977).
[220] E. Witten, Physical Review D 30, 272 (1984).
[221] A. Kosowsky, M. S. Turner, and R. Watkins, Physical Review D 45, 4514 (1992).
[222] C. L. Wainwright, Computer Physics Communications 183, 2006 (2012), 1109.4189.
[223] P. Athron, C. Balázs, A. Fowlie, and Y. Zhang, European Physical Journal C 80, 567 (2020), 2003.02859.
[224] A. Marciano, D. Chen, F. Fabrocini, C. Fields, E. Greco, N. Gresnigt, K. Jinklub, M. Lulli, K. Terzidis, and E. Zappala, Neural Networks 153, 164 (2022), 2007.00142.
[225] C. Fields, J. F. Glazebrook, and A. Marciano, Fortschritte der Physik p. 2200104 (2022), 2205.13184.
[226] A. Marciano, D. Chen, F. Fabrocini, C. Fields, M. Lulli, and E. Zappala, Deep neural networks as the semi-classical limit of topological quantum neural networks: The problem of generalisation (2022), 2210.13741.
[227] A. S. Cattaneo, P. Cotta-Ramusino, F. Fucito, M. Martellini, M. Rinaldi, A. Tanzini, and M. Zeni, Communications in Mathematical Physics 197, 571 (1998), hep-th/9705123.
[228] M. Creutz, Quarks, Gluons and Lattices (Cambridge University Press, 1984).
[229] K. Beer, D. Bondarenko, T. Farrelly, T. J. Osborne, R. Salzmann, D. Scheiermann, and R. Wolf, Nature Communications 11, 1 (2020).
[230] R. Laureijs et al., Euclid definition study report (2011), 1110.3193.
[231] Z. Ivezić et al., Astrophysical Journal 873, 111 (2019), 0805.2366.
[232] M. Abdul Karim et al., Desi dr2 results ii: Measurements of baryon acoustic oscillations and cosmological constraints (2025), 2503.14738.
[233] M. Ho, M. M. Rau, M. Ntampaka, A. Farahi, H. Trac, and B. Poczos, Astrophysical Journal 887, 25 (2019), 1902.05950.
[234] A. Peel, F. Lalande, J. L. Starck, V. Pettorino, J. Merten, C. Giocoli, M. Meneghetti, and M. Baldi, Physical Review D 100, 023508 (2019), 1810.11030.
[235] J. Caldeira, W. L. K. Wu, B. Nord, C. Avestruz, S. Trivedi, and K. T. Story, Astronomy and Computing 28, 100307 (2019), 1810.01483.
[236] S. He, Y. Li, Y. Feng, S. Ho, S. Ravanbakhsh, W. Chen, and B. Póczos, Proceedings of the National Academy of Sciences 116, 13825 (2019), 1811.06533.
[237] S. Ravanbakhsh, F. Lanusse, R. Mandelbaum, J. Schneider, and B. Poczos, Enabling dark energy science with deep generative models of galaxy images (2016), 1609.05796.
[238] C. Escamilla-Rivera, M. A. C. Quintero, and S. Capozziello, Journal of Cosmology and Astroparticle Physics 03, 008 (2020), 1910.02788.
[239] G. Narayan et al., Astrophysical Journal Supplement Series 236, 9 (2018), 1801.07323.
[240] F. Lanusse, Q. Ma, N. Li, T. E. Collett, C. Li, S. Ravanbakhsh, R. Mandelbaum, and B. Poczos, Monthly Notices of the Royal Astronomical Society 473, 3895 (2018), 1703.02642.
[241] E. Di Valentino et al., The cosmoverse white paper: Addressing observational tensions in cosmology with systematics and fundamental physics (2025), 2504.01669.
[242] Y. C. Wang, Y. B. Xie, T. J. Zhang, H. C. Huang, T. Zhang, and K. Liu, Astrophysical Journal Supplement Series 254, 43 (2021), 2005.10628.
[243] G. J. Wang, C. Cheng, Y. Z. Ma, J. Q. Xia, A. Abebe, and A. Beesham, Astrophysical Journal Supplement Series 268, 7 (2023), 2306.11102.
[244] I. Gómez-Vargas, R. M. Esquivel, R. Garcı́a-Salcedo, and J. A. Vázquez, European Physical Journal C 83, 304 (2023), 2104.00595.
[245] A. Manrique-Yus and E. Sellentin, Monthly Notices of the Royal Astronomical Society 491, 2655 (2020), 1907.05881.
[246] A. Spurio Mancini, D. Piras, J. Alsing, B. Joachimi, and M. P. Hobson, Monthly Notices of the Royal Astronomical Society 511, 1771 (2022), 2106.03846.
[247] J. Albers, C. Fidler, J. Lesgourgues, N. Schöneberg, and J. Torrado, Journal of Cosmology and Astroparticle Physics 09, 028 (2019), 1907.05764.
[248] T. Auld, M. Bridges, M. P. Hobson, and S. F. Gull, Monthly Notices of the Royal Astronomical Society 376, L11 (2007), astro-ph/0608174.
[249] G. J. Wang, S. Y. Li, and J. Q. Xia, Astrophysical Journal Supplement Series 249, 25 (2020), 2005.07089.
[250] S. Günther, J. Lesgourgues, G. Samaras, N. Schöneberg, F. Stadtmann, C. Fidler, and J. Torrado, Journal of Cosmology and Astroparticle Physics 11, 035 (2022), 2207.05707.
[251] C. G. Sabiu, K. Kadota, J. Asorey, and I. Park, Journal of Cosmology and Astroparticle Physics 01, 020 (2022), 2108.07972.
[252] J. Asorey, M. Crocce, E. Gaztanaga, and A. Lewis, Monthly Notices of the Royal Astronomical Society 427, 1891 (2012).
[253] M. Andrés-Carcasona, M. Martinez, and L. M. Mir, Monthly Notices of the Royal Astronomical Society 527, 2887 (2023), 2309.04303.
[254] G. Papamakarios, E. Nalisnick, D. J. Rezende, S. Mohamed, and B. Lakshminarayanan, Journal of Machine Learning Research 22, 1 (2021).
[255] H. T. J. Bevins, W. J. Handley, P. Lemos, P. H. Sims, E. de Lera Acedo, A. Fialkov, and J. Alsing, Monthly Notices of the Royal Astronomical Society 526, 4613 (2023), 2205.12841.
[256] R. Friedman and S. Hassan, Higlow: Conditional normalizing flows for high-fidelity hi map modeling (2022), 2211.12724.
[257] A. Mootoovaloo, C. Garcı́a-Garcı́a, D. Alonso, and J. Ruiz-Zapatero, Monthly Notices of the Royal Astronomical Society 536, 190 (2024), 2409.01407.
[258] R. Friedman and S. Hassan, Higlow: Conditional normalizing flows for high-fidelity hi map modeling (2022), 2211.12724.
[259] J. Sohl-Dickstein, E. Weiss, N. Maheswaranathan, and S. Ganguli, in Proceedings of the 32nd International Conference on Machine Learning (2015), pp. 2256–2265.
[260] J. Song, C. Meng, and S. Ermon, Denoising diffusion implicit models (2020), 2010.02502.
[261] N. Mudur, C. Cuesta-Lazaro, and D. P. Finkbeiner, in 37th Conference on Neural Information Processing Systems (2023), 2312.07534.
[262] N. Mudur, C. Cuesta-Lazaro, and D. P. Finkbeiner, Astrophysical Journal 978, 64 (2025), 2405.05255.
[263] A. Koloniari et al., Mach. Learn.: Sci. Technol. 6, 015054 (2024), 2407.07820.
[264] P. Thakur, A. Taridalu, I. A. Rather, T. Klangburam, and C. Pongkitivanichkul, Phys. Rev. D 113, 023001 (2026), URL https://link.aps.org/doi/10.1103/j3mm-zjsv.
[265] H. Einsle, M. A. Bizouard, T. Regimbau, and M. Sakellariadou, Phys. Rev. D 112, 063056 (2025), URL https://link. aps.org/doi/10.1103/hs9b-drwx.
[266] H. Iwanaga, M. Matsuyama, and Y. Itoh, Phys. Rev. D 112, 083020 (2025), URL https://link.aps.org/doi/10.1103/ blfk-7k9f.
[267] J.-Q. Jiang, H.-L. Huang, J. He, Y.-T. Wang, and Y.-S. Piao, A fast deep-learning approach to probing primordial black hole populations in gravitational wave events (2025), 2505.15530, URL https://arxiv.org/abs/2505.15530.
[268] A. Delaunoy, M. de la Brassinne Bonardeaux, S. Mishra-Sharma, and G. Louppe, Low-budget simulation-based inference with bayesian neural networks (2024), 2408.15136.
[269] K. Cranmer, J. Brehmer, and G. Louppe, Proceedings of the National Academy of Sciences 117, 30055 (2020), 1911.01429.
[270] J. Alsing, T. Charnock, S. Feeney, and B. Wandelt, Monthly Notices of the Royal Astronomical Society 488, 4440 (2019).
[271] N. Jeffrey, L. Whiteway, M. Gatti, J. Williamson, J. Alsing, A. Porredon, J. Prat, C. Doux, B. Jain, C. Chang, et al., Monthly Notices of the Royal Astronomical Society 536, 1303 (2025).
[272] B. Wang, J. Leja, V. A. Villar, and J. S. Speagle, Astrophysical Journal Letters 952, L10 (2023), 2305.01594.
[273] N. Mediato-Diaz and W. Handley, Cosmological parameter estimation with sequential linear simulation-based inference (2025), 2501.03921.
[274] F. Zhong, N. R. Napolitano, J. Comparat, K. Dolag, C. Heneka, Z. Huang, X. Li, W. Lin, G. Longo, M. Radovich, et al., Machine-learning cosmological parameters by erosita data (2026), 2602.20483.
[275] L. Rojas, S. Espinoza, E. Gonzalez, C. Maldonado, and F. Luo, Galaxies 13, 114 (2025).
[276] H. Kojima and T. Ikegami, Neural Networks 152, 234 (2022).
[277] I. Higgins, L. Matthey, A. Pal, C. P. Burgess, X. Glorot, M. M. Botvinick, S. Mohamed, and A. Lerchner, in International Conference on Learning Representations (ICLR) (Toulon, 2017).
[278] R. T. Q. Chen, X. Li, R. Grosse, and D. Duvenaud, in Advances in Neural Information Processing Systems (2018), vol. 31, pp. 2615–2625.
[279] ATLAS Collaboration, European Physical Journal C 80, 450 (2020).
[280] J. Zhou et al., Graph neural networks: A review of methods and applications (2018), 1812.08434.