Neutrino Gravitational Interactions

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References

1 - Theory

[1-1]: Gravity limits the kinetic energy of a massive elementary particle, Justin C. Feng, arXiv:2401.05764, 2024.
[Feng:2024bei]
[1-2]: Quantum Field Theory of neutrino mixing in spacetimes with torsion, Antonio Capolupo, Giuseppe De Maria, Simone Monda, Aniello Quaranta, Raoul Serao, arXiv:2310.09309, 2023.
[Capolupo:2023igw]
[1-3]: Neutrino spin oscillations in a magnetized Polish doughnut, Maxim Dvornikov, JCAP 09 (2023) 039, arXiv:2307.10126.
[Dvornikov:2023tbz]
[1-4]: The neutrino pair annihilation ($\nu+\bar{\nu}\longrightarrow e^{-}+e^{+}$)around a Schwarzschild black hole in asymptotic safety, Yuxuan Shi, Hongbo Cheng, arXiv:2304.01154, 2023.
[Shi:2023kid]
[1-5]: Scattering of neutrinos by a rotating black hole accounting for the electroweak interaction with an accretion disk, Maxim Dvornikov, arXiv:2212.03479, 2022.
[Dvornikov:2022btx]
[1-6]: Gravitational Effects on Quantum Coherence in Neutrino Oscillation, M. M. Ettefaghi, R. Ramezani Arani, Z. S. Tabatabaei Lotfi, Phys.Rev.D 105 (2022) 095024, arXiv:2204.12314.
[Ettefaghi:2022nsq]
[1-7]: On the observability of gravitational source rotation in neutrino flavor oscillations, Himanshu Swami, Eur.Phys.J.C 82 (2022) 974, arXiv:2202.12310.
[Swami:2022xet]
[1-8]: Effects of gravitational lensing on neutrino oscillation in $ \gamma $-spacetime, Hrishikesh Chakrabarty, Debasish Borah, Ahmadjon Abdujabbarov, Daniele Malafarina, Bobomurat Ahmedov, Eur.Phys.J.C 82 (2022) 24, arXiv:2109.02395.
[Chakrabarty:2021bpr]
[1-9]: Interaction of supernova neutrinos with stochastic gravitational waves, Maxim Dvornikov, Phys.Rev.D 104 (2021) 043018, arXiv:2103.15464.
[Dvornikov:2021sac]
[1-10]: Neutrino scattering off a black hole surrounded by a magnetized accretion disk, Maxim Dvornikov, JCAP 2104 (2021) 005, arXiv:2102.00806.
[Dvornikov:2021hps]
[1-11]: Spinors and Scalars in curved spacetime: neutrino dark energy (DE$_\nu$), Ali Rida Khalifeh, Raul Jimenez, Phys.Dark Univ. 31 (2021) 100777, arXiv:2010.08181.
[Khalifeh:2020bdg]
[1-12]: Spin oscillations of neutrinos scattered off a rotating black hole, Maxim Dvornikov, Eur.Phys.J. C80 (2020) 474, arXiv:2006.01636.
[Dvornikov:2020oay]
[1-13]: Non-relativistic neutrinos and the weak equivalence principle violation, Massimo Blasone, Petr Jizba, Gaetano Lambiase, Luciano Petruzziello, Phys.Lett. B811 (2020) 135883, arXiv:2001.09974.
[Blasone:2020kqx]
[1-14]: Spin effects in neutrino gravitational scattering, Maxim Dvornikov, Phys.Rev. D101 (2020) 056018, arXiv:1911.08317.
[Dvornikov:2019fhi]
[1-15]: Elastic Scattering in General Relativistic Ray Tracing for Neutrinos, M. Brett Deaton et al., Phys.Rev. D98 (2018) 103014, arXiv:1806.10255.
[Deaton:2018ser]
[1-16]: Black hole interference patterns in flavour oscillations, Jean Alexandre, Katy Clough, Phys.Rev. D98 (2018) 043004, arXiv:1805.01874.
[Alexandre:2018crg]
[1-17]: Neutrinos propagating in curved spacetimes, Fan Zhang, Eur.Phys.J.Plus 132 (2017) 446, arXiv:1803.04253.
[Zhang:2017ink]
[1-18]: Gravity induced geometric phases and entanglement in spinors and neutrinos: Gravitational Zeeman effect, Banibrata Mukhopadhyay, Soumya Kanti Ganguly, Universe 6 (2020) 160, arXiv:1802.10377.
[Mukhopadhyay:2018oli]
[1-19]: Neutrino and Photon Lensing by Black Holes: Radiative Lens Equations and Post-Newtonian Contributions, Claudio Coriano, Antonio Costantini, Marta Dell'Atti, Luigi Delle Rose, JHEP 07 (2015) 160, arXiv:1504.01322.
[Coriano:2015mva]
[1-20]: Highly relativistic spin-gravity coupling for fermions, Roman Plyatsko, Mykola Fenyk, Phys. Rev. D91 (2015) 064033, arXiv:1503.08415.
[Plyatsko:2015bia]
[1-21]: Revising neutrino oscillations in a curved space-time, Luca Visinelli, Gen.Rel.Grav. 47 (2014) 5, arXiv:1410.1523.
[Visinelli:2014xsa]
[1-22]: Fermion Scattering in a Gravitational Background: Electroweak Corrections and Flavour Transitions, Claudio Coriano, Luigi Delle Rose, Emidio Gabrielli, Luca Trentadue, JHEP 1403 (2014) 136, arXiv:1312.7657.
[Coriano:2013iba]
[1-23]: Neutrino spin oscillations in matter under the influence of gravitational and electromagnetic fields, Maxim Dvornikov, JCAP 1306 (2013) 015, arXiv:1306.2659.
[Dvornikov:2013pta]
[1-24]: Highly relativistic circular orbits of spinning particle in the Kerr field, Roman Plyatsko, Mykola Fenyk, Phys. Rev. D87 (2013) 044019, arXiv:1303.4707.
[Plyatsko:2013xza]
[1-25]: Angular momentum non-conserving decays in isotropic media, Jose F. Nieves, Palash B. Pal, Eur. Phys. J. C63 (2009) 331-342, arXiv:0907.3000.
[Nieves:2009by]
[1-26]: Neutrino gravitational decay in a medium, Jose F. Nieves, Palash B. Pal, arXiv:0901.2982, 2009.
[Nieves:2009rw]
[1-27]: Interaction of Dirac and Majorana Neutrinos with Weak Gravitational Fields, A. Menon, Arun M. Thalapillil, Phys. Rev. D78 (2008) 113003, arXiv:0804.3833.
[Menon:2008wa]

2 - Theory - Talks

[2-1]: Neutrino oscillation caused by spacetime geometry, Indrajit Ghose, Riya Barick, Amitabha Lahiri, LHEP 2023 (2023) 349, arXiv:2302.10119. International Conference on Neutrinos and Dark Matter (NuDM-2022), Sharm El-Sheikh, Egypt, 25-28 September, 2022.
[Ghose:2023ttq]
[2-2]: Neutrino spin oscillations in curved space-time under the influence of external fields, Maxim Dvornikov, J.Phys.Conf.Ser. 938 (2017) 012043, arXiv:1710.05181. DSPIN-2017, September 11-15, 2017, Dubna, Russia.
[Dvornikov:2017blx]

3 - Theory - Neutrino Oscillations

[3-1]: Effect of torsion in long-baseline neutrino oscillation experiments, Papia Panda, Dinesh Kumar Singha, Monojit Ghosh, Rukmani Mohanta, arXiv:2403.09105, 2024.
[Panda:2024qsh]
[3-2]: Neutrino spin oscillations in gravitational fields in noncommutative higher dimensions, S. A. Alavi, T. Fallahi Serish, arXiv:2312.13142, 2023.
[Alavi:2023ijy]
[3-3]: Neutrino spin oscillation in screening models revisited, Faycal Hammad, Nicolas Fleury, Parvaneh Sadeghi, Phys. Rev. D 108 (2023) 083025, arXiv:2312.11741.
[Hammad:2023kse]
[3-4]: Effect of spacetime geometry on neutrino oscillations, Riya Barick, Indrajit Ghose, Amitabha Lahiri, arXiv:2302.10945, 2023.
[Barick:2023wxx]
[3-5]: Effects of gravitational lensing by Kaluza-Klein black holes on neutrino oscillations, Hrishikesh Chakrabarty, Auttakit Chatrabhuti, Daniele Malafarina, Bhuddhanubhap Silasan, Takol Tangphati, JCAP 08 (2023) 018, arXiv:2302.01564.
[Chakrabarty:2023kld]
[3-6]: Neutrino spin oscillations in gravitational fields in higher dimensions, S.A. Alavi, T. Fallahi.Serish, Mod.Phys.Lett.A 37 (2022) 2250200, arXiv:2206.01940.
[Alavi:2022kec]
[3-7]: Aspects of gravitational decoherence in neutrino lensing, Himanshu Swami, Kinjalk Lochan, Ketan M. Patel, Phys.Rev.D 104 (2021) 095007, arXiv:2106.07671.
[Swami:2021wbf]
[3-8]: Neutrino spin oscillations in conformally gravity coupling models and quintessence surrounding a black hole, Leonardo Mastrototaro, Gaetano Lambiase, Phys.Rev.D 104 (2021) 024021, arXiv:2106.07665.
[Mastrototaro:2021kmw]
[3-9]: Neutrino oscillations in gravitational and cosmological backgrounds, George Koutsoumbas, Dimitrios Metaxas, Gen.Rel.Grav. 52 (2020) 102, arXiv:1909.02735.
[Koutsoumbas:2019fkn]
[3-10]: Neutrino decoherence in presence of strong gravitational fields, Amelie Chatelain, Maria Cristina Volpe, Phys.Lett.B 801 (2020) 135150, arXiv:1906.12152.
[Chatelain:2019nkf]
[3-11]: Neutrino flavor oscillations in stochastic gravitational waves, Maxim Dvornikov, Phys.Rev. D100 (2019) 096014, arXiv:1906.06167.
[Dvornikov:2019jkc]
[3-12]: Neutrino oscillations in extended theories of gravity, Luca Buoninfante, Giuseppe Gaetano Luciano, Luciano Petruzziello, Luca Smaldone, Phys.Rev. D101 (2020) 024016, arXiv:1906.03131.
[Buoninfante:2019der]
[3-13]: Time-energy uncertainty relation for neutrino oscillations in curved spacetime, Massimo Blasone, Gaetano Lambiase, Giuseppe Gaetano Luciano, Luciano Petruzziello, Luca Smaldone, Class.Quant.Grav. 37 (2020) 155004, arXiv:1904.05261.
[Blasone:2019jtj]
[3-14]: Quantum correlations in neutrino oscillations in curved spacetime, Khushboo Dixit, Javid Naikoo, Banibrata Mukhopadhyay, Subhashish Banerjee, Phys.Rev. D100 (2019) 055021, arXiv:1903.05664.
[Dixit:2019lsg]
[3-15]: Neutrino spin oscillations in external fields in curved space-time, Maxim Dvornikov, Phys.Rev.D 99 (2019) 116021, arXiv:1902.11285.
[Dvornikov:2019sfo]
[3-16]: Three-generation neutrino oscillations in curved spacetime, Yu-Hao Zhang, Xue-Qian Li, Nucl. Phys. B911 (2016) 563-581, arXiv:1606.05960.
[Zhang:2016deq]
[3-17]: Quantum Gravity effect on neutrino oscillations in a strong gravitational field, Jonathan Miller, Roman Pasechnik, Adv. High Energy Phys. 2015 (2015) 381569, arXiv:1305.4430.
[Miller:2013wta]
[3-18]: Neutrino oscillations above black hole accretion disks: disks with electron-flavor emission, A. Malkus, J. P. Kneller, G. C. McLaughlin, R. Surman, Phys. Rev. D86 (2012) 085015, arXiv:1207.6648.
[Malkus:2012ts]
[3-19]: Neutrino spin oscillations in gravitational fields, S. A. Alavi, S. F. Hosseini, Grav.Cosmol. 19 (2013) 129-133, arXiv:1108.3593.
[Alavi:2011xd]
[3-20]: Neutrino oscillation phase dynamically induced by f(R)-gravity, S. Capozziello, M. De Laurentis, D. Vernieri, Mod. Phys. Lett. A25 (2010) 1163-1168, arXiv:1001.4173.
[Capozziello:2010yz]
[3-21]: Neutrino Oscillations in Gravitational Field, S. I. Godunov, G. S. Pastukhov, Phys. Atom. Nucl. 74 (2011) 302-305, arXiv:0906.5556.
[Godunov:2009ce]
[3-22]: Gravity induced neutrino-antineutrino oscillation: CPT and lepton number non-conservation under gravity, Banibrata Mukhopadhyay, Class. Quant. Grav. 24 (2007) 1433-1442, arXiv:gr-qc/0702062.
[Mukhopadhyay:2007vca]
[3-23]: Reply to Comment on 'Can gravity distinguish between Dirac and Majorana neutrinos?', Dinesh Singh, Nader Mobed, Giorgio Papini, Phys. Rev. Lett. 98 (2007) 069002, arXiv:gr-qc/0611016.
[Singh:2006fn]
[3-24]: Comment on 'Can gravity distinguish between Dirac and Majorana neutrinos?', Jose F. Nieves, Palash B. Pal, Phys. Rev. Lett. 98 (2007) 069001, arXiv:gr-qc/0610098.
[Nieves:2006tq]
[3-25]: General Relativistic Effects of Gravity in Quantum Mechanics - A Case of Ultra-Relativistic, Spin 1/2 Particles -, Kohkichi Konno, Masumi Kasai, Prog. Theor. Phys. 100 (1998) 1145, arXiv:gr-qc/0603035.
[Konno:1998kq]
[3-26]: Neutrino spin oscillations in gravitational fields, Maxim Dvornikov, Int. J. Mod. Phys. D15 (2006) 1017-1034, arXiv:hep-ph/0601095.
[Dvornikov:2006ji]
[3-27]: Neutrino optics and oscillations in gravitational fields, G. Lambiase, G. Papini, R. Punzi, G. Scarpetta, Phys. Rev. D71 (2005) 073011, arXiv:gr-qc/0503027.
[Lambiase:2005gt]
[3-28]: Neutrino Wave Packets in Weak Gravitational Fields, Dinesh Singh, Nader Mobed, Giorgio Papini, Phys. Lett. A351 (2006) 373, arXiv:gr-qc/0502098.
[Singh:2005ur]
[3-29]: Testing quantum gravity via cosmogenic neutrino oscillations, Joy Christian, Phys. Rev. D71 (2005) 024012, arXiv:gr-qc/0409077.
[Christian:2004xb]
[3-30]: Charge conjugation and Lense-Thirring Effect: A new Asymmetry, D. V. Ahluwalia-Khalilova, Gen. Rel. Grav. 36 (2004) 2581, arXiv:gr-qc/0405112.
[Ahluwalia:2004kv]
[3-31]: Neutrino oscillations in gravitational fields, Hisae Maiwa, Shigefumi Naka, arXiv:hep-ph/0401143, 2004.
[Maiwa:2004ym]
[3-32]: Neutrino Interferometry In Curved Spacetime, Roland M. Crocker, Carlo Giunti, Daniel J. Mortlock, Phys. Rev. D69 (2004) 063008, arXiv:hep-ph/0308168.
[Crocker:2003cw]
[3-33]: Cerenkov's effect and neutrino oscillations in loop quantum gravity, G. Lambiase, Mod. Phys. Lett. A18 (2003) 23-30, arXiv:gr-qc/0301058.
[Lambiase:2003bq]
[3-34]: General relativistic effects on quantum interference and the principle of equivalence, K. K. Nandi, Yuan-Zhong Zhang, Phys. Rev. D66 (2002) 063005, arXiv:gr-qc/0208050.
[Nandi:2002me]
[3-35]: Quantum phase shift and neutrino oscillations in a stationary, weak gravitational field, Pierre Teyssandier Bernard Linet, Mod. Phys. Lett. A26 (2011) 1737-1751, arXiv:gr-qc/0206056.
[Linet:2002wp]
[3-36]: Addendum on the mass neutrino oscillation in a gravitational field, J. G. Pereira, C. M. Zhang, Gen. Rel. Grav. 33 (2001) 2801, arXiv:gr-qc/0205030.
[Pereira:2001by]
[3-37]: Quantum systems in weak gravitational fields, G. Papini, NATO Sci.Ser.II 60 (2002) 317-338, arXiv:gr-qc/0110056.
[Papini:2001kb]
[3-38]: Neutrinos in a vacuum dominated cosmology, Manasse R. Mbonye, Gen. Rel. Grav. 34 (2002) 1865-1875, arXiv:astro-ph/0108167.
[Mbonye:2001rp]
[3-39]: Neutrino oscillations induced by gravitational recoil effects, G. Lambiase, Gen. Rel. Grav. 33 (2001) 2151-2156, arXiv:gr-qc/0107066.
[Lambiase:2001ib]
[3-40]: Matter waves in a gravitational field: An index of refraction for massive particles in general relativity, James C. Evans, Paul M. Alsing, Stefano Giorgetti, Kamal Kanti Nandi, Am. J. Phys. 69 (2001) 1103-1110, arXiv:gr-qc/0107063.
[Evans:2001hy]
[3-41]: Neutrino oscillations in Caianiello's quantum geometry model, V. Bozza, S. Capozziello, G. Lambiase, G. Scarpetta, Int. J. Theor. Phys. 40 (2001) 849-859, arXiv:hep-ph/0106234.
[Bozza:2001vc]
[3-42]: Quantum violations of the equivalence principle in a modified Schwarzschild geometry: Neutrino oscillations, V. Bozza, G. Lambiase, G. Papini, G. Scarpetta, Phys. Lett. A279 (2001) 163-168, arXiv:hep-ph/0012270.
[Bozza:2000mh]
[3-43]: Mass dependence of the gravitationally-induced wave- function phase, Jose Wudka, Phys. Rev. D64 (2001) 065009, arXiv:gr-qc/0010077.
[Wudka:2000rf]
[3-44]: The phase of a quantum mechanical particle in curved spacetime, P. M. Alsing, J. C. Evans, K. K. Nandi, Gen. Rel. Grav. 33 (2001) 1459-1487, arXiv:gr-qc/0010065.
[Alsing:2000ji]
[3-45]: The general treatment of high/low energy particle interference phase in a gravitational field, C. M. Zhang, Gen.Rel.Grav. 33 (2001) 1011-1025, arXiv:gr-qc/0004048.
[Zhang:2000mi]
[3-46]: On the Mass Neutrino Phase calculations along the geodesic line and the null line, C.M. Zhang, A. Beesham, Int.J.Mod.Phys. D12 (2003) 727-738, arXiv:gr-qc/0004047.
[Zhang:2003pn]
[3-47]: Some remarks on the neutrino oscillation phase in a gravitational field, J. G. Pereira, C. M. Zhang, Gen. Rel. Grav. 32 (2000) 1633-1637, arXiv:gr-qc/0002066.
[Pereira:2000kq]
[3-48]: Berry's phase of neutrino oscillations in the presence of torsion, S. Capozziello, G. Lambiase, Europhys. Lett. 52 (2000) 15-21.
[Capozziello:2000ue]
[3-49]: Neutrino oscillations in Brans-Dicke theory of gravity, S. Capozziello, G. Lambiase, Mod. Phys. Lett. A14 (1999) 2193, arXiv:gr-qc/9910026.
[Capozziello:1999qm]
[3-50]: Inertial effects on neutrino oscillations, S. Capozziello, G. Lambiase, Eur. Phys. J. C12 (2000) 343-347, arXiv:gr-qc/9910016.
[Capozziello:1999ww]
[3-51]: Interplay of gravitation and linear superposition of different mass eigenstates, D. V. Ahluwalia, C. Burgard, Phys. Rev. D57 (1998) 4724-4727, arXiv:gr-qc/9803013.
[Ahluwalia:1998jx]
[3-52]: Gravitational correction in neutrino oscillations, Yasufumi Kojima, Mod. Phys. Lett. A11 (1996) 2965-2970, arXiv:gr-qc/9612044.
[Kojima:1996vb]
[3-53]: Gravitational effects on the neutrino oscillation, N. Fornengo, C. Giunti, C. W. Kim, J. Song, Phys. Rev. D56 (1997) 1895-1902, arXiv:hep-ph/9611231.
[Fornengo:1996ef]
[3-54]: Neutrino oscillations in curved spacetime: An heuristic treatment, Christian Y. Cardall, George M. Fuller, Phys. Rev. D55 (1997) 7960-7966, arXiv:hep-ph/9610494.
[Cardall:1996cd]
[3-55]: Gravitationally induced neutrino oscillation phases in static space-times, Tanmoy Bhattacharya, Salman Habib, Emil Mottola, Phys. Rev. D59 (1996) 067301, arXiv:gr-qc/9605074.
[Bhattacharya:1996xb]
[3-56]: Neutrino Oscillations in Strong Gravitational Fields, Dardo Piriz, Mou Roy, Jose Wudka, Phys. Rev. D54 (1996) 1587-1599, arXiv:hep-ph/9604403.
[Piriz:1996mu]
[3-57]: Gravitationally Induced Quantum Mechanical Phases and Neutrino Oscillations in Astrophysical Environments, D. V. Ahluwalia, C. Burgard, Gen. Rel. Grav. 28 (1996) 1161-1170, arXiv:gr-qc/9603008.
[Ahluwalia:1996ev]
[3-58]: Neutrino Oscillations in the Presence of Torsion, V. De Sabbata, M. Gasperini, Nuovo Cim. A 65 (1981) 479-500.
[DeSabbata:1981ek]
[3-59]: MATTER AND LIGHT WAVE INTERFEROMETRY IN GRAVITATIONAL FIELDS, L. Stodolsky, Gen. Rel. Grav. 11 (1979) 391-405.
[Stodolsky:1979ks]

4 - Theory - Neutrino Oscillations - Talks

[4-1]: Spin oscillations in neutrino gravitational scattering, Mridupawan Deka, Maxim Dvornikov, arXiv:2311.14475, 2023. XIX Workshop on High Energy Spin Physics, DSPIN-23 (September 4-8, 2023, JINR, Dubna, Russia).
[Deka:2023ljj]
[4-2]: Neutrino physics in slowly rotating black hole spacetime and nonlinear electrodynamics, H. Mosquera Cuesta, G. Lambiase, J.P. Pereira, arXiv:2004.04964, 2020. NuPhys2019: Prospects in Neutrino Physics-Cavendish Conference Centre, London, 16-18 December 2019.
[MosqueraCuesta:2020crv]
[4-3]: Neutrino oscillations in gravitational waves, Maxim Dvornikov, J.Phys.Conf.Ser. 1435 (2020) 012005, arXiv:1910.01415. DSPIN-2019 (JINR, Dubna, Russia, September 2-6 2019).
[Dvornikov:2019xok]

5 - Theory - Models

[5-1]: Probing Schwarzschild-like Black Holes in Metric-Affine Bumblebee Gravity with Accretion Disk, Deflection Angle, Greybody Bounds, and Neutrino Propagation, G. Lambiase, L. Mastrototaro, Reggie C. Pantig, Ali Ovgun, JCAP 12 (2023) 026, arXiv:2309.13594.
[Lambiase:2023zeo]
[5-2]: Neutrino flavor oscillations inside matter in conformal coupling models, Faycal Hammad, Parvaneh Sadeghi, Nicolas Fleury, Phys.Rev.D 107 (2023) 104015, arXiv:2304.03746.
[Hammad:2023mbp]
[5-3]: Neutrino Spin Oscillations in a Black Hole Background in Noncommutative Spaces, S. A. Alavi, S. Nodeh, Phys.Scripta 90 (2015) 035301, arXiv:1301.5977.
[Alavi:2013lum]

6 - Theory - Accelerated States

[6-1]: On the beta-decay of the accelerated proton and neutrino oscillations: a three-flavor description with CP violation, Massimo Blasone, Gaetano Lambiase, Giuseppe Gaetano Luciano, Luciano Petruzziello, Eur.Phys.J. C80 (2020) 130, arXiv:2002.03351.
[Blasone:2020vtm]
[6-2]: Neutrino oscillations in accelerated frames, Massimo Blasone, Gaetano Lambiase, Giuseppe Gaetano Luciano, Luciano Petruzziello, EPL 124 (2018) 51001, arXiv:1812.09697.
[Blasone:2018iih]
[6-3]: Neutrino mixing and General Covariance in the inverse beta decay, M. Blasone, G. Lambiase, G. G. Luciano, L. Petruzziello, PoS CORFU2017 (2018) 198, arXiv:1804.11211.
[Blasone:2018gtg]
[6-4]: The Unruh effect for mixing neutrinos, Gabriel Cozzella, Stephen A. Fulling, Andre G. S. Landulfo, George E. A. Matsas, Daniel A. T. Vanzella, Phys.Rev. D97 (2018) 105022, arXiv:1803.06400.
[Cozzella:2018qew]
[6-5]: Neutrino oscillations in accelerated states, Dharam Vir Ahluwalia, Lance Labun, Giorgio Torrieri, Eur.Phys.J. A52 (2016) 189, arXiv:1508.03091.
[Ahluwalia:2015kxa]
[6-6]: Unruh effect for neutrinos interacting with accelerated matter, Maxim Dvornikov, JHEP 08 (2015) 151, arXiv:1507.01174.
[Dvornikov:2015eqa]

7 - Theory - Accelerated States - Talks

[7-1]: The Unruh effect and oscillating neutrinos, Dharam Vir Ahluwalia, Lance Labun, Giorgio Torrieri, J. Phys. Conf. Ser. 706 (2016) 042006, arXiv:1505.04082.
[Ahluwalia:2015wha]

8 - Phenomenology

[8-1]: Neutrinos as possible probes for quantum gravity, Marco Danilo Claudio Torri, Lino Miramonti, arXiv:2404.04076, 2024.
[Torri:2024jwc]
[8-2]: Gravitational scattering of spinning neutrinos by a rotating black hole with a slim magnetized accretion disk, Maxim Dvornikov, Class.Quant.Grav. 40 (2023) 015002, arXiv:2206.00042.
[Dvornikov:2022qge]
[8-3]: Flavor ratios of astrophysical neutrinos interacting with stochastic gravitational waves having arbitrary spectrum, Maxim Dvornikov, JCAP 2012 (2020) 022, arXiv:2009.02195.
[Dvornikov:2020dst]
[8-4]: Signature of neutrino mass hierarchy in gravitational lensing, Himanshu Swami, Kinjalk Lochan, Ketan M. Patel, Phys.Rev. D102 (2020) 024043, arXiv:2002.00977.
[Swami:2020qdi]
[8-5]: Distinguishing Dirac and Majorana neutrinos by their gravi-majoron decays, Lena Funcke, Georg Raffelt, Edoardo Vitagliano, Phys.Rev. D101 (2020) 015025, arXiv:1905.01264.
[Funcke:2019grs]
[8-6]: Limits on the Neutrino Velocity, Lorentz Invariance, and the Equivalence Principle with TeV neutrinos from Gamma-Ray Bursts, Jun-Jie Wei, Xue-Feng Wu, He Gao, Peter Meszaros, JCAP 1608 (2016) 031, arXiv:1603.07568.
[Wei:2016ygk]
[8-7]: Gravitational lensing of transient neutrino sources by black holes, Ernesto F. Eiroa, Gustavo E. Romero, Phys. Lett. B663 (2008) 377-381, arXiv:0802.4251.
[Eiroa:2008ks]
[8-8]: Gravitational Lensing Characteristics of the Transparent Sun, Bijunath Patla, Robert J. Nemiroff, Astrophys.J. 685 (2008) 1297, arXiv:0711.4811.
[Patla:2007ju]
[8-9]: Gravitational Lensing of Supernova Neutrinos, Olga Mena, Irina Mocioiu, Chris Quigg, Astropart. Phys. 28 (2007) 348-356, arXiv:astro-ph/0610918.
[Mena:2006ym]

9 - Phenomenology - Models

[9-1]: CPT and lepton number violation in neutrino sector: Modified mass matrix of neutrino coupled to gravity, Monika Sinha, Banibrata Mukhopadhyay, Phys. Rev. D77 (2008) 025003, arXiv:0704.2593.
[Sinha:2007uh]

10 - Phenomenology - Models - Talks

[10-1]: Phenomenology of Quantum Gravity and its Possible Role in Neutrino Anomalies, Mario A. Acero, Yuri Bonder, Springer Proc.Phys. 157 (2014) 461-468, arXiv:1210.3004. Relativity and Gravitation: 100 Years after Einstein in Prague (June 2012, Prague).
[Acero:2012mm]

11 - Violations of the Equivalence Principle

[11-1]: Sensitivity of KM3NeT to Violation of Equivalence Principle, Marco Chianese, Damiano F. G. Fiorillo, Gianpiero Mangano, Gennaro Miele, Stefano Morisi, Ofelia Pisanti, Symmetry 13 (2021) 1353, arXiv:2107.13013.
[Chianese:2021vkf]
[11-2]: Violation of Equivalence Principle in Neutrino Sector: Probing the Extended Parameter Space, Arman Esmaili, JCAP 2107 (2021) 018, arXiv:2105.08744.
[Esmaili:2021omm]
[11-3]: IceCube constraints on Violation of Equivalence Principle, Damiano F. G. Fiorillo, Gianpiero Mangano, Stefano Morisi, Ofelia Pisanti, JCAP 2104 (2021) 079, arXiv:2012.07867.
[Fiorillo:2020gsb]
[11-4]: Effects of the Violation of the Equivalence Principle at DUNE, F. N. Diaz, J. Hoefken, A. M. Gago, Phys.Rev. D102 (2020) 055020, arXiv:2003.13712.
[Diaz:2020aax]
[11-5]: New Limits for the Violation of the Equivalence Principle in the Solar-Reactor Neutrino Sector, G. do A. Valdiviesso, M. M. Guzzo, P. C. de Holanda, Phys.Lett. B701 (2011) 240-247, arXiv:0811.2128.
[Valdiviesso:2008vyk]
[11-6]: Mapping Lorentz invariance violations into equivalence principle violations, A. Halprin, H. B. Kim, Phys. Lett. B469 (1999) 78-80, arXiv:hep-ph/9905301.
[Halprin:1999be]
[11-7]: Closing the neutrinoless double beta decay window into violations of the equivalence principle and/or Lorentz invariance, A. Halprin, R. R. Volkas, Phys. Lett. B459 (1999) 183-185, arXiv:hep-ph/9904298.
[Halprin:1999cg]
[11-8]: A Possible Violation of the Equivalence Principle by Neutrinos, A. Halprin, C. N. Leung, J. Pantaleone, Phys. Rev. D53 (1996) 5365-5376, arXiv:hep-ph/9512220.
[Halprin:1995vg]
[11-9]: Neutrino mixing due to a violation of the equivalence principle, J. Pantaleone, A. Halprin, C. N. Leung, Phys. Rev. D47 (1993) 4199-4202, arXiv:hep-ph/9211214.
[Pantaleone:1992ha]
[11-10]: Can the sun shed light on neutrino gravitational interactions?, A. Halprin, C. N. Leung, Phys. Rev. Lett. 67 (1991) 1833-1835.
[Halprin:1991gs]
[11-11]: Experimental Constraints on a Minimal and Nonminimal Violation of the Equivalence Principle in the Oscillations of Massive Neutrinos, M. Gasperini, Phys. Rev. D 39 (1989) 3606-3611.
[Gasperini:1989rt]
[11-12]: Testing the Principle of Equivalence with Neutrino Oscillations, M. Gasperini, Phys. Rev. D 38 (1988) 2635-2637.
[Gasperini:1988zf]

12 - Violations of the Equivalence Principle - Talks

[12-1]: IceCube constraints on Violation of Equivalence Principle, Damiano F. G. Fiorillo, arXiv:2107.13018, 2021. 37th International Cosmic Ray Conference (ICRC 2021).
[2107.13018]
[12-2]: Solar neutrino oscillations and neutrino-gravity couplings, A. Halprin, C. N. Leung, Nucl. Phys. Proc. Suppl. 28A (1992) 139-141.
[Halprin:1992in]

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