Publications: Research Papers

Some of my papers are signed in alphabetical order, while some others are signed following the astro-ph community convention.

  1. M. George, M.-R. Wu, I. Tamborra, R. Ardevol-Pulpillo, H.-T. Janka, Fast neutrino flavor conversion, ejecta properties, and nucleosynthesis in the newly-formed hypermassive remnants of neutron-star mergers, arXiv: 2009.04046.
  2. I. Padilla-Gay, S. Shalgar, I. Tamborra, Multi-Dimensional Solution of Fast Neutrino Conversions in Binary Neutron Star Merger Remnants, arXiv: 2009.01843.
  3. M. Bustamante, I. Tamborra, Using High-Energy Neutrinos as Cosmic Magnetometers, arXiv: 2009.01306.
  4. S. Shalgar, I. Tamborra, Dispelling a myth on dense neutrino media: fast pairwise conversions depend on energy, arXiv: 2007.07926.
  5. A.M. Suliga, I. Tamborra, M.-R. Wu, Lifting the core-collapse supernova bounds on keV-mass sterile neutrinos, JCAP 08 (2020) 018 [arXiv: 2004.11389].
  6. L. Pattavina, N. Ferreiro Iachellini, I. Tamborra, Neutrino observatory based on archeological lead, Phys. Rev. D 102 (2020) no.6, 063001 [arXiv: 2004.06936].
  7. M. Bustamante, C.A. Rosenstroem, S. Shalgar, I. Tamborra, Bounds on secret neutrino interactions from high-energy astrophysical neutrinos, Phys. Rev. D 101 (2020) no.12, 123024 [arXiv: 2001.04994].
  8. S. Shalgar, I. Tamborra, M. Bustamante, Core-collapse supernovae stymie secret neutrino interactions, arXiv: 1912.09115.
  9. S. Shalgar, I. Padilla-Gay, I. Tamborra, Neutrino propagation hinders fast pairwise flavor conversions, JCAP 06 (2020) 048 [arXiv: 1911.09110].
  10. L. Walk, I. Tamborra, H.-T. Janka, A. Summa, Neutrino emission characteristics of black hole formation in three-dimensional simulations of stellar collapse, Phys. Rev. D 101 (2020) no.12, 123013 [arXiv: 1910.12971].
  11. A. M. Suliga, I. Tamborra, M.-R. Wu, Tau lepton asymmetry by sterile neutrino emission — Moving beyond one-zone supernova models, JCAP 12 (2019) 019 [arXiv: 1908.11382].
  12. J. R. Westernacher-Schneider, E. O’Connor, E. O’Sullivan, I. Tamborra, M.-R. Wu, S. M. Couch, F. Malmenbeck, Multimessenger Asteroseismology of Core-Collapse Supernovae, Phys. Rev. D 100 (2019) 12 [arXiv: 1907.01138].
  13. S. Shalgar and I. Tamborra, On the Occurrence of Crossings Between the Angular Distributions of Electron Neutrinos and Antineutrinos in the Supernova Core, Astrophys. J. 883 (2019) 80 [arXiv: 1904.07236].
  14. L. Walk, I. Tamborra, H.-T. Janka, A. Summa, D. Kresse, Effects of the standing accretion-shock instability and the lepton-emission self-sustained asymmetry in the neutrino emission of rotating supernovae, Phys. Rev. D 100 (2019) 063018 [arXiv: 1901.06235].
  15. K. Moller, P. B. Denton, I. Tamborra, Cosmogenic Neutrinos Through the GRAND Lens Unveil the Nature of Cosmic Accelerators, JCAP 05 (2019) 047 [arXiv: 1809.04866].
  16. L. Walk, I. Tamborra, H.-T. Janka, A. Summa, Identifying rotation in SASI-dominated core-collapse supernovae with a neutrino gyroscope, Phys. Rev. D 98 (2018) no.12, 123001 [arXiv: 1807.02366].
  17. P. B. Denton and I. Tamborra, Invisible Neutrino Decay Resolves IceCube’s Track and Cascade Tension, Phys. Rev. Lett. 121 (2018) 121802 [arXiv:1805.05950].
  18. K. Moller, A. M. Suliga, I. Tamborra and P. B. Denton, Measuring the supernova unknowns at the next-generation neutrino telescopes through the diffuse neutrino background, JCAP 05 (2018) 066 [arXiv:1804.03157].
  19. P. B. Denton and I. Tamborra, The Bright and Choked Gamma-Ray Burst Contribution to the IceCube and ANTARES Low-Energy Excess, JCAP 04 (2018) 058   [arXiv:1802.10098].
  20. M. R. Wu, I. Tamborra, O. Just and H.-T. Janka, Imprints of neutrino-pair flavor conversions on nucleosynthesis in ejecta from neutron-star merger remnants, Phys. Rev. D 96 (2017) 123015 [arXiv:1711.00477].
  21. P. B. Denton and I. Tamborra, Exploring the Properties of Choked Gamma-Ray Bursts with IceCube’s High Energy Neutrinos, Astrophys. J. 855 (2018) 37 [arXiv:1711.00470].
  22. I. Tamborra, L. Huedepohl, G. Raffelt and H.-T. Janka, Flavor-dependent neutrino angular distribution in core-collapse supernovae, Astrophys. J.  839 (2017) 132 [arXiv:1702.00060].
  23. M. R. Wu and I. Tamborra, Fast neutrino conversions: Ubiquitous in compact binary merger remnants, Phys. Rev. D 95 (2017) 103007 [arXiv:1701.06580].
  24. P. Mertsch, M. Rameez and I. Tamborra, Detection prospects for high energy neutrino sources from the anisotropic matter distribution in the local universe, JCAP 03 (2017) 011 [arXiv:1612.07311].
  25. I. Izaguirre, G. Raffelt and I. Tamborra, Fast Pairwise Conversion of Supernova Neutrinos: Dispersion-Relation Approach, Phys. Rev. Lett. 118 (2017) 2, 021101 [arXiv:1610.01612].
  26. M. R. Feyereisen, I. Tamborra and S. Ando, One-point fluctuation analysis of the high-energy neutrino sky, JCAP 03 (2017) 057 [arXiv:1610.01607].
  27. R. F. Lang, C. McCabe, S. Reichard, M. Selvi and I. Tamborra, Supernova neutrino physics with xenon dark matter detectors: A timely perspective, Phys. Rev. D 94 (2016) 10, 103009 [arXiv:1606.09243].
  28. I. Tamborra and S. Ando, Inspecting the supernova-gamma-ray-burst connection with high-energy neutrinos, Phys. Rev. D 93 (2016) 5, 053010 [arXiv: 1512.01559].
  29. S. Ando, I. Tamborra and F. Zandanel, Tomographic Constraints on High-Energy Neutrinos of Hadronuclear Origin, Phys. Rev. Lett. 115 (2015) 22, 221101 [arXiv: 1509.02444].
  30.  I. Tamborra and S. Ando, Diffuse emission of high-energy neutrinos from gamma-ray burst fireballs, JCAP 1509 (2015) 09, 036 [arXiv: 1504.00107]
  31.  F. Zandanel, I. Tamborra, S. Gabici and S. Ando, High-energy gamma-ray and neutrino backgrounds from clusters of galaxies and radio constraints, Astron. & Astrophys. 578 (2015)  A32 [arXiv: 1406.2596].
  32.  E. Pllumbi, I. Tamborra, S. Wanajo, H.-T. Janka and L.Huedepohl, Impact of neutrino flavor oscillations on the neutrino-driven wind nucleosynthesis of an electron-capture supernova, Astrophys. J.  808 (2015) 2,  188 [arXiv: 1406.2596].
  33.   I. Tamborra, G. G. Raffelt, F. Hanke, H.-T. Janka and B. Mueller, Neutrino emission characteristics and detection opportunities based on three-dimensional supernova simulations, Phys. Rev. D 90 (2014) 045032  [arXiv: 1406.0006].
  34.  I. Tamborra, S. Ando, K. Murase, Star-forming galaxies as the origin of diffuse high-energy backgrounds: Gamma-ray and neutrino connections, and implications for starburst history, JCAP 09 (2014)  043 [arXiv: 1404.1189].
  35.  I. Tamborra, F. Hanke, H.-T. Janka, B.  Mueller, G. G. Raffelt, and A. Marek, Self-sustained asymmetry of lepton-number emission: A new phenomenon during the supernova shock-accretion phase in three dimensions, Astrophys. J. 792 (2014) 96  [arXiv: 1402.5418].
  36.  I. Tamborra, F. Hanke, B. Mueller, H.-T. Janka and G. G. Raffelt, Neutrino signature of supernova hydrodynamical instabilities in three dimensions, Phys.  Rev. Lett. 111 (2013) 121104, [arXiv: 1307.7936].
  37.   I. Tamborra, B. Mueller, L. Huedepohl, H.-T. Janka and G. G. Raffelt, High-resolution supernova neutrino spectra represented by a simple fit, Phys. Rev. D 86 (2012) 125031 [arXiv: 1211.3920].
  38.  E. Borriello, S. Chakraborty, A. Mirizzi, P. D. Serpico and  I. Tamborra, Can one observe Earth matter effects with supernova neutrinos?, Phys. Rev. D 86 (2012) 083004, [arXiv: 1207.5049].
  39.  C. Lunardini and I. Tamborra, Diffuse supernova neutrinos: oscillation effects, stellar cooling and progenitor mass dependence, JCAP 1207 (2012) 012 [arXiv: 1205.6292].
  40.  S. Hannestad,  I. Tamborra and T. Tram, Thermalisation of light sterile neutrinos in the early universe, JCAP 1207 (2012) 025 [arXiv: 1204.5861].
  41.  S. Sarikas, I. Tamborra, G. G. Raffelt, L. Huedepohl, H.-T. Janka, Supernova neutrino halo and the suppression of self-induced flavor conversion, Phys. Rev. D 85 (2012) 113007 [arXiv: 1204.0971].
  42.   I. Tamborra, G. G. Raffelt, L. Huedepohl, H.-T. Janka, Impact of eV-mass sterile neutrinos on neutrino-driven supernova outflows, JCAP 1201 (2012) 013  [arXiv: 1110.2104].
  43.  J. Hamann, S. Hannestad, G. G. Raffelt,  I. Tamborra and Y. Y. Y. Wong, Cosmology Favoring Extra Radiation and Sub-eV Mass Sterile Neutrinos as an Option, Phys. Rev. Lett. 105 (2010) 181301 [arXiv: 1006.5276].
  44.  G. G. Raffelt and  I. Tamborra, Synchronization vs. decoherence of neutrino oscillations at intermediate densities, Phys. Rev. D 82 (2010) 125004 [arXiv: 1006.0002].
  45.  B. Dasgupta, A. Mirizzi, I. Tamborra, R. Tomas, Neutrino mass hierarchy and three-flavor spectral splits supernova neutrinos, Phys. Rev. D 81 (2010) 093008 [arXiv: 1002.2943].
  46.  B. Dasgupta, G. G. Raffelt, I. Tamborra, Triggering collective oscillations by three-flavor effects, Phys. Rev. D 81 (2010) 073004 [arXiv: 1001.5396].
  47.  G. L. Fogli, E. Lisi, A. Marrone, I. Tamborra, Supernova neutrinos and antineutrinos: spectral split  patterns in a ternary luminosity diagram, JCAP 0910 (2009) 002 [arXiv: 0907.5115].
  48.  G. L. Fogli, E. Lisi, A. Marrone,  I. Tamborra, Three-flavor evolution of supernova neutrino fluxes with dominant collective effects, JCAP 0904 (2009) 030 [arXiv: 0812.3031].
  49.   G. L. Fogli, E. Lisi, A. Marrone, A. Mirizzi, I. Tamborra, Low energy spectral features of supernova (anti)neutrinos in inverted hierarchy, Phys. Rev. D 78 (2008) 097301 [arXiv: 0808.0807].