Davide Gerosa

Davide Gerosa

University professor - research in gravitational waves and black holes.

Publications

Here is my publication list; click here for a pdf version. You can also find my papers on ADS, INSPIRE, and the arXiv.

My citation count is available on this page, and see here for a bibtex file with these entries. I also write my thoughts about my papers in the news.

Summary

8 Submitted papers
97 Papers published in major peer-reviewed journals
12 Other publications (white papers, proceedings, etc.)

Submitted papers

8. Bayesian luminosity function estimation in multidepth datasets with selection effects: a case study for \(3<z<5\) Ly\(\alpha\) emitters.
D. Tornotti, M. Fossati, M. Fumagalli, D. Gerosa, L. Pizzuti, F. Arrigoni Battaia.
arXiv:2506.10083 [astro-ph.GA].

7. Sequential simulation-based inference for extreme mass ratio inspirals.
P. S. Cole, J. Alvey, L. Speri, C. Weniger, U. Bhardwaj, D. Gerosa, G. Bertone.
arXiv:2505.16795 [gr-qc].

6. Distinguishing the origin of eccentric black-hole mergers with gravitational-wave spin measurements.
J. Stegmann, D. Gerosa, I. Romero-Shaw, G. Fumagalli, H. Tagawa, L. Zwick.
arXiv:2505.13589 [astro-ph.HE].

5. Ringdown mode amplitudes of precessing binary black holes.
F. Nobili, S. Bhagwat, C. Pacilio, D. Gerosa.
arXiv:2504.17021 [gr-qc].

4. Cosmology with the angular cross-correlation of gravitational-wave and galaxy catalogs: forecasts for next-generation interferometers and the Euclid survey.
A. Pedrotti, M. Mancarella, J. Bel, D. Gerosa.
arXiv:2504.10482 [astro-ph.CO].

3. A confirmed recoiling supermassive black hole in a powerful quasar.
M. Chiaberge, T. Morishita, M. Boschini, S. Bianchi, A. Capetti, G. Castignani, D. Gerosa, M. Konishi, S. Koyama, K. Kushibiki, E. Lambrides, E. T. Meyer, K. Motohara, M. Stiavelli, H. Takahashi, G. R. Tremblay, C. Norman.
arXiv:2501.18730 [astro-ph.GA].

2. A test for LISA foreground Gaussianity and stationarity. I. Galactic white-dwarf binaries.
R. Buscicchio, A. Klein, V. Korol, F. Di Renzo, C. J. Moore, D. Gerosa, A. Carzaniga.
arXiv:2410.08263 [astro-ph.HE].

1. The last three years: multiband gravitational-wave observations of stellar-mass binary black holes.
A. Klein, G. Pratten, R. Buscicchio, P. Schmidt, C. J. Moore, E. Finch, A. Bonino, L. M. Thomas, N. Williams, D. Gerosa, S. McGee, M. Nicholl, A. Vecchio.
arXiv:2204.03423 [gr-qc].

Papers published in major peer-reviewed journals

97. Non-adiabatic dynamics of eccentric black-hole binaries in post-Newtonian theory.
G. Fumagalli, N. Loutrel, D. Gerosa, M. Boschini.
Physical Review D in press. arXiv:2502.06952 [gr-qc].

96. Reconstructing parametric gravitational-wave population fits from non-parametric results without refitting the data.
C. M. Fabbri, D. Gerosa, A. Santini, M. Mould, A. Toubiana, J. Gair.
Physical Review D 111 (2025) 104053. arXiv:2501.17233 [astro-ph.HE].

95. Scalable data-analysis framework for long-duration gravitational waves from compact binaries using short Fourier transforms.
R. Tenorio, D. Gerosa.
Physical Review D 111 (2025) 104044. arXiv:2502.11823 [gr-qc].

94. Sampling the full hierarchical population posterior distribution in gravitational-wave astronomy.
M. Mancarella, D. Gerosa.
Physical Review D 111 (2025) 103012. arXiv:2502.12156 [gr-qc].

93. Which is which? Identification of the two compact objects in gravitational-wave binaries.
D. Gerosa, V. De Renzis, F. Tettoni, M. Mould, A. Vecchio, C. Pacilio.
Physical Review Letters 134 (2025) 121402. arXiv:2409.07519 [astro-ph.HE].
PRL Editors’ Suggestion. Covered by press release.

92. Forecasting the population properties of merging black holes.
V. De Renzis, F. Iacovelli, D. Gerosa, M. Mancarella, C. Pacilio.
Physical Review D 111 (2025) 044048. arXiv:2410.17325 [astro-ph.HE].

91. Orbital eccentricity in general relativity from catastrophe theory.
M. Boschini, N. Loutrel, D. Gerosa, G. Fumagalli.
Physical Review D 111 (2025) 024008. arXiv:2411.00098 [gr-qc].

90. Stars or gas? Constraining the hardening processes of massive black-hole binaries with LISA.
A. Spadaro, R. Buscicchio, D. Izquierdo-Villalba, D. Gerosa, A. Klein, G. Pratten.
Physical Review D 111 (2025) 023004 . arXiv:2409.13011 [astro-ph.HE].

89. Probing AGN jet precession with LISA.
N. Steinle, D. Gerosa, M. G. H. Krause.
Physical Review D 110 (2024) 123034. arXiv:2403.00066 [astro-ph.HE].

88. Minimum gas mass accreted by spinning intermediate-mass black holes in stellar clusters.
K. Kritos, L. Reali, D. Gerosa, E. Berti.
Physical Review D 110 (2024) 123017. arXiv:2409.15439 [astro-ph.HE].

87. Flexible mapping of ringdown amplitudes for nonprecessing binary black holes.
C. Pacilio, S. Bhagwat, F. Nobili, D. Gerosa.
Physical Review D 110 (2024) 103037. arXiv:2408.05276 [gr-qc].

86. Classifying binary black holes from Population III stars with the Einstein Telescope: a machine-learning approach.
F. Santoliquido, U. Dupletsa, J. Tissino, M. Branchesi, F. Iacovelli, G. Iorio, M. Mapelli, D. Gerosa, J. Harms, M. Pasquato.
Astronomy & Astrophysics 690 (2024) A362. arXiv:2404.10048 [astro-ph.HE].

85. Residual eccentricity as a systematic uncertainty on the formation channels of binary black holes.
G. Fumagalli, I. Romero-Shaw, D. Gerosa, V. De Renzis, K. Kritos, A. Olejak.
Physical Review D 110 (2024) 063012. arXiv:2405.14945 [astro-ph.HE].

84. Astrophysical and relativistic modeling of the recoiling black-hole candidate in quasar 3C 186.
M. Boschini, D. Gerosa, O. S. Salafia, M. Dotti.
Astronomy & Astrophysics 686 (2024) A245. arXiv:2402.08740 [astro-ph.GA].

83. Quick recipes for gravitational-wave selection effects.
D. Gerosa, M. Bellotti.
Classical and Quantum Gravity 41 (2024) 125002. arXiv:2404.16930 [astro-ph.HE].

82. pAGN: the one-stop solution for AGN disc modeling.
D. Gangardt, A. A. Trani, C. Bonnerot, D. Gerosa.
Monthly Notices of the Royal Astronomical Society 530 (2024) 3986–3997. arXiv:2403.00060 [astro-ph.HE].
Open source code.

81. Catalog variance of testing general relativity with gravitational-wave data.
C. Pacilio, D. Gerosa, S. Bhagwat.
Physical Review D 109 (2024) L081302. arXiv:2310.03811 [gr-qc].

80. Calibrating signal-to-noise ratio detection thresholds using gravitational-wave catalogs.
M. Mould, C. J. Moore, D. Gerosa.
Physical Review D 109 (2024) 063013. arXiv:2311.12117 [gr-qc].

79. Spin-eccentricity interplay in merging binary black holes.
G. Fumagalli, D. Gerosa.
Physical Review D 108 (2023) 124055. arXiv:2310.16893 [gr-qc].

78. Glitch systematics on the observation of massive black-hole binaries with LISA.
A. Spadaro, R. Buscicchio, D. Vetrugno, A. Klein, D. Gerosa, S. Vitale, R. Dolesi, W. J. Weber, M. Colpi.
Physical Review D 108 (2023) 123029. arXiv:2306.03923 [gr-qc].

77. Black-hole mergers in disk-like environments could explain the observed \(q-\chi_\mathrm{eff}\) correlation.
A. Santini, D. Gerosa, R. Cotesta, E. Berti.
Physical Review D 108 (2023) 083033. arXiv:2308.12998 [astro-ph.HE].

76. Extending black-hole remnant surrogate models to extreme mass ratios.
M. Boschini, D. Gerosa, V. Varma, C. Armaza, M. Boyle, M. S. Bonilla, A. Ceja, Y. Chen, N. Deppe, M. Giesler, L. E. Kidder, G. Lara, O. Long, S. Ma, K. Mitman, P. J. Nee, H. P. Pfeiffer, A. Ramos-Buades, M. A. Scheel, N. L. Vu, J. Yoo.
Physical Review D 108 (2023) 084015. arXiv:2307.03435 [gr-qc].

75. One to many: comparing single gravitational-wave events to astrophysical populations.
M. Mould, D. Gerosa, M. Dall’Amico, M. Mapelli.
Monthly Notices of the Royal Astronomical Society 525 (2023) 3986–3997. arXiv:2305.18539 [astro-ph.HE].

74. Efficient multi-timescale dynamics of precessing black-hole binaries.
D. Gerosa, G. Fumagalli, M. Mould, G. Cavallotto, D. Padilla Monroy, D. Gangardt, V. De Renzis.
Physical Review D 108 (2023) 024042. arXiv:2304.04801 [gr-qc].
Open source code.

73. Parameter estimation of binary black holes in the endpoint of the up-down instability.
V. De Renzis, D. Gerosa, M. Mould, R. Buscicchio, L. Zanga.
Physical Review D 108 (2023) 024024. arXiv:2304.13063 [gr-qc].

72. Inferring, not just detecting: metrics for high-redshift sources observed with third-generation gravitational-wave detectors.
M. Mancarella, F. Iacovelli, D. Gerosa.
Physical Review D 107 (2023) L101302. arXiv:2303.16323 [gr-qc].

71. Eccentricity or spin precession? Distinguishing subdominant effects in gravitational-wave data.
I. Romero-Shaw, D. Gerosa, N. Loutrel.
Monthly Notices of the Royal Astronomical Society 519 (2023) 5352–5357. arXiv:2211.07528 [astro-ph.HE].

70. The Bardeen-Petterson effect, disk breaking, and the spin orientations of supermassive black-hole binaries.
N. Steinle, D. Gerosa.
Monthly Notices of the Royal Astronomical Society 519 (2023) 5031–5042. arXiv:2211.00044 [astro-ph.HE].

69. Deep learning and Bayesian inference of gravitational-wave populations: hierarchical black-hole mergers.
M. Mould, D. Gerosa, S. R. Taylor.
Physical Review D 106 (2022) 103013. arXiv:2203.03651 [astro-ph.HE].

68. Characterization of merging black holes with two precessing spins.
V. De Renzis, D. Gerosa, G. Pratten, P. Schmidt, M. Mould.
Physical Review D 106 (2022) 084040. arXiv:2207.00030 [gr-qc].

67. Which black hole formed first? Mass-ratio reversal in massive binary stars from gravitational-wave data.
M. Mould, D. Gerosa, F. S. Broekgaarden, N. Steinle.
Monthly Notices of the Royal Astronomical Society 517 (2022) 2738–2745. arXiv:2205.12329 [astro-ph.HE].

66. The irreducible mass and the horizon area of LIGO’s black holes.
D. Gerosa, C. M. Fabbri, U. Sperhake.
Classical and Quantum Gravity 39 (2022) 175008. arXiv:2202.08848 [gr-qc].

65. Constraining black-hole binary spin precession and nutation with sequential prior conditioning.
D. Gangardt, D. Gerosa, M. Kesden, V. De Renzis, N. Steinle.
Physical Review D 106 (2022) 024019. Erratum: 107 (2023) 109901. arXiv:2204.00026 [gr-qc].

64. Inferring the properties of a population of compact binaries in presence of selection effects.
S. Vitale, D. Gerosa, W. M. Farr, S. R. Taylor.
Chapter in: Handbook of Gravitational Wave Astronomy, Springer, Singapore. arXiv:2007.05579 [astro-ph.IM].

63. Gravitational-wave population inference at past time infinity.
M. Mould, D. Gerosa.
Physical Review D 105 (2022) 024076. arXiv:2110.05507 [astro-ph.HE].

62. The Bardeen-Petterson effect in accreting supermassive black-hole binaries: disc breaking and critical obliquity.
R. Nealon, E. Ragusa, D. Gerosa, G. Rosotti, R. Barbieri.
Monthly Notices of the Royal Astronomical Society 509 (2022) 5608–5621. arXiv:2111.08065 [astro-ph.HE].

61. Population-informed priors in gravitational-wave astronomy.
C. J. Moore, D. Gerosa.
Physical Review D 104 (2021) 083008. arXiv:2108.02462 [gr-qc].

60. Looking for the parents of LIGO’s black holes.
V. Baibhav, E. Berti, D. Gerosa, M. Mould, K. W. K. Wong.
Physical Review D 104 (2021) 084002. arXiv:2105.12140 [gr-qc].

59. Modeling the outcome of supernova explosions in binary population synthesis using the stellar compactness.
M. Dabrowny, N. Giacobbo, D. Gerosa.
Rendiconti Lincei 32 (2021) 665–673. arXiv:2106.12541 [astro-ph.HE].

58. Bayesian parameter estimation of stellar-mass black-hole binaries with LISA.
R. Buscicchio, A. Klein, E. Roebber, C. J. Moore, D. Gerosa, E. Finch, A. Vecchio.
Physical Review D 104 (2021) 044065. arXiv:2106.05259 [astro-ph.HE].

57. Hierarchical mergers of stellar-mass black holes and their gravitational-wave signatures.
D. Gerosa, M. Fishbach.
Nature Astronomy 5 (2021) 749-760. arXiv:2105.03439 [gr-qc].
Review article. Covered by press release.

56. High mass but low spin: an exclusion region to rule out hierarchical black-hole mergers as a mechanism to populate the pair-instability mass gap.
D. Gerosa, N. Giacobbo, A. Vecchio.
Astrophysical Journal 915 (2021) 56. arXiv:2104.11247 [astro-ph.HE].

55. Testing general relativity with gravitational-wave catalogs: the insidious nature of waveform systematics.
C. J. Moore, E. Finch, R. Buscicchio, D. Gerosa.
iScience 24 (2021) 102577. arXiv:2103.16486 [gr-qc].

54. A taxonomy of black-hole binary spin precession and nutation.
D. Gangardt, N. Steinle, M. Kesden, D. Gerosa, E. Stoikos.
Physical Review D 103 (2021) 124026. arXiv:2103.03894 [gr-qc].

53. A generalized precession parameter \(\chi_\mathrm{p}\) to interpret gravitational-wave data.
D. Gerosa, M. Mould, D. Gangardt, P. Schmidt, G. Pratten, L. M. Thomas.
Physical Review D 103 (2021) 064067. arXiv:2011.11948 [gr-qc].

52. Eccentric binary black hole surrogate models for the gravitational waveform and remnant properties: comparable mass, nonspinning case.
T. Islam, V. Varma, J. Lodman, S. E. Field, G. Khanna, M. A. Scheel, H. P. Pfeiffer, D. Gerosa, L. E. Kidder.
Physical Review D 103 (2021) 064022. arXiv:2101.11798 [gr-qc].

51. Up-down instability of binary black holes in numerical relativity.
V. Varma, M. Mould, D. Gerosa, M. A. Scheel, L. E. Kidder, H. P. Pfeiffer.
Physical Review D 103 (2021) 064003. arXiv:2012.07147 [gr-qc].

50. Massive black hole binary inspiral and spin evolution in a cosmological framework.
M. Sayeb, L. Blecha, L. Z. Kelley, D. Gerosa, M. Kesden, J. Thomas.
Monthly Notices of the Royal Astronomical Society 501 (2021) 2531-2546. arXiv:2006.06647 [astro-ph.GA].

49. Gravitational-wave selection effects using neural-network classifiers.
D. Gerosa, G. Pratten, A. Vecchio.
Physical Review D 102 (2020) 103020. arXiv:2007.06585 [astro-ph.HE].

48. Mapping the asymptotic inspiral of precessing binary black holes to their merger remnants.
L. Reali, M. Mould, D. Gerosa, V. Varma.
Classical and Quantum Gravity 37 (2020) 225005. arXiv:2005.01747 [gr-qc].

47. Astrophysical implications of GW190412 as a remnant of a previous black-hole merger.
D. Gerosa, S. Vitale, E. Berti.
Physical Review Letters 125 (2020) 101103. arXiv:2005.04243 [astro-ph.HE].
Covered by press release.

46. Structure of neutron stars in massive scalar-tensor gravity.
R. Rosca-Mead, C. J. Moore, U. Sperhake, M. Agathos, D. Gerosa.
Symmetry 12 (2020) 1384. arXiv:2007.14429 [gr-qc].

45. Core collapse in massive scalar-tensor gravity.
R. Rosca-Mead, U. Sperhake, C. J. Moore, M. Agathos, D. Gerosa, C. D. Ott.
Physical Review D 102 (2020) 044010. arXiv:2005.09728 [gr-qc].

44. The mass gap, the spin gap, and the origin of merging binary black holes.
V. Baibhav, D. Gerosa, E. Berti, K. W. K. Wong, T. Helfer, M. Mould.
Physical Review D 102 (2020) 043002. arXiv:2004.00650 [gr-qc].

43. The Bardeen-Petterson effect in accreting supermassive black-hole binaries: a systematic approach.
D. Gerosa, G. Rosotti, R. Barbieri.
Monthly Notices of the Royal Astronomical Society 496 (2020) 3060-3075. arXiv:2004.02894 [astro-ph.GA].

42. Populations of double white dwarfs in Milky Way satellites and their detectability with LISA.
V. Korol, S. Toonen, A. Klein, V. Belokurov, F. Vincenzo, R. Buscicchio, D. Gerosa, C. J. Moore, E. Roebber, E. M. Rossi, A. Vecchio.
Astronomy & Astrophysics 638 (2020) A153. arXiv:2002.10462 [astro-ph.GA].

41. Endpoint of the up-down instability in precessing binary black holes.
M. Mould, D. Gerosa.
Physical Review D 101 (2020) 124037. arXiv:2003.02281 [gr-qc].

40. Black holes in the low mass gap: Implications for gravitational wave observations.
A. Gupta, D. Gerosa, K. G. Arun, E. Berti, W. Farr, B. S. Sathyaprakash.
Physical Review D 101 (2020) 103036. arXiv:1909.05804 [gr-qc].

39. Milky Way satellites shining bright in gravitational waves.
E. Roebber, R. Buscicchio, A. Vecchio, C. J. Moore, A. Klein, V. Korol, S. Toonen, D. Gerosa, J. Goldstein, S. M. Gaebel, T. E. Woods.
Astrophysical Journal 894 (2020) L15. arXiv:2002.10465 [astro-ph.GA].

38. Evolutionary roads leading to low effective spins, high black hole masses, and O1/O2 rates for LIGO/Virgo binary black holes.
K. Belczynski, J. Klencki, C. E. Fields, A. Olejak, E. Berti, G. Meynet, C. L. Fryer, D. E. Holz, R. O’Shaughnessy, D. A. Brown, T. Bulik, S. C. Leung, K. Nomoto, P. Madau, R, Hirschi, E. Kaiser, S. Jones, S. Mondal, M. Chruslinska, P. Drozda, D. Gerosa, Z. Doctor, M. Giersz, S. Ekstr:om, C. Georgy, A. Askar, V. Baibhav, D. Wysocki, T. Natan, W. M. Farr, G. Wiktorowicz, M. C. Miller, B. Farr, J.-P. Lasota.
Astronomy & Astrophysics 636 (2020) A104. arXiv:1706.07053 [astro-ph.HE].

37. Amplification of superkicks in black-hole binaries through orbital eccentricity.
U. Sperhake, R. Rosca-Mead, D. Gerosa, E. Berti.
Physical Review D 101 (2020) 024044. arXiv:1910.01598 [gr-qc].

36. Constraining the fraction of binary black holes formed in isolation and young star clusters with gravitational-wave data.
Y. Bouffanais, M. Mapelli, D. Gerosa, U. N. Di Carlo, N. Giacobbo, E. Berti, V. Baibhav.
Astrophysical Journal 886 (2019) 25. arXiv:1905.11054 [astro-ph.HE].

35. Machine-learning interpolation of population-synthesis simulations to interpret gravitational-wave observations: a case study.
K. W. K. Wong, D. Gerosa.
Physical Review D 100 (2019) 083015. arXiv:1909.06373 [astro-ph.HE].

34. Surrogate models for precessing binary black hole simulations with unequal masses.
V. Varma, S. E. Field, M. A. Scheel, J. Blackman, D. Gerosa, L. C. Stein, L. E. Kidder, H. P. Pfeiffer.
Physical Review Research 1 (2019) 033015. arXiv:1905.09300 [gr-qc].

33. Gravitational-wave detection rates for compact binaries formed in isolation: LIGO/Virgo O3 and beyond.
V. Baibhav, E. Berti, D. Gerosa, M. Mapelli, N. Giacobbo, Y. Bouffanais, U. N. Di Carlo.
Physical Review D 100 (2019) 064060. arXiv:1906.04197 [gr-qc].

32. Escape speed of stellar clusters from multiple-generation black-hole mergers in the upper mass gap.
D. Gerosa, E. Berti.
Physical Review D 100 (2019) 041301R. arXiv:1906.05295 [astro-ph.HE].
Covered by press release.

31. Are stellar-mass black-hole binaries too quiet for LISA?.
C. J. Moore, D. Gerosa, A. Klein.
Monthly Notices of the Royal Astronomical Society 488 (2019) L94-L98. arXiv:1905.11998 [astro-ph.HE].

30. Optimizing LIGO with LISA forewarnings to improve black-hole spectroscopy.
R. Tso, D. Gerosa, Y. Chen.
Physical Review D 99 (2019) 124043. arXiv:1807.00075 [gr-qc].

29. Multiband gravitational-wave event rates and stellar physics.
D. Gerosa, S. Ma, K. W. K. Wong, E. Berti, R. O’Shaughnessy, Y. Chen, K. Belczynski.
Physical Review D 99 (2019) 103004. arXiv:1902.00021 [astro-ph.HE].

28. Wide nutation: binary black-hole spins repeatedly oscillating from full alignment to full anti-alignment.
D. Gerosa, A. Lima, E. Berti, U. Sperhake, M. Kesden, R. O’Shaughnessy.
Classical and Quantum Gravity 36 (2019) 105003. arXiv:1811.05979 [gr-qc].

27. The binary black hole explorer: on-the-fly visualizations of precessing binary black holes.
V. Varma, L. C. Stein, D. Gerosa.
Classical and Quantum Gravity 36 (2019) 095007. arXiv:1811.06552 [astro-ph.HE].

26. Frequency-domain waveform approximants capturing Doppler shifts.
K. Chamberlain, C. J. Moore, D. Gerosa, N. Yunes.
Physical Review D 99 (2019) 024025. arXiv:1809.04799 [gr-qc].

25. High-accuracy mass, spin, and recoil predictions of generic black-hole merger remnants.
V. Varma, D. Gerosa, L. C. Stein, F. H’ebert, H. Zhang.
Physical Review Letters 122 (2019) 011101. arXiv:1809.091259 [gr-qc].
Covered by press release.

24. Spin orientations of merging black holes formed from the evolution of stellar binaries.
D. Gerosa, E. Berti, R. O’Shaughnessy, K. Belczynski, M. Kesden, D. Wysocki, W. Gladysz.
Physical Review D 98 (2018) 084036. arXiv:1808.02491 [astro-ph.HE].

23. Mining gravitational-wave catalogs to understand binary stellar evolution: a new hierarchical bayesian framework.
S. R. Taylor, D. Gerosa.
Physical Review D 98 (2018) 083017. arXiv:1806.08365 [astro-ph.HE].

22. Gravitational-wave astrophysics with effective-spin measurements: asymmetries and selection biases.
K. K. Y. Ng, S. Vitale, A. Zimmerman, K. Chatziioannou, D. Gerosa, C.-J. Haster.
Physical Review D 98 (2018) 083007. arXiv:1805.03046 [gr-qc].

21. Black-hole kicks from numerical-relativity surrogate models.
D. Gerosa, F. H’ebert, L. C. Stein.
Physical Review D 97 (2018) 104049. arXiv:1802.04276 [gr-qc].

20. Explaining LIGO’s observations via isolated binary evolution with natal kicks.
D. Wysocki, D. Gerosa, R. O’Shaughnessy, K. Belczynski, W. Gladysz, E. Berti, M. Kesden, D. Holz.
Physical Review D 97 (2018) 043014. arXiv:1709.01943 [astro-ph.HE].

19. Impact of Bayesian priors on the characterization of binary black hole coalescences.
S. Vitale, D. Gerosa, C.-J. Haster, K. Chatziioannou, A. Zimmerman.
Physical Review Letters 119 (2017) 251103. arXiv:1707.04637 [gr-qc].

18. Long-lived inverse chirp signals from core collapse in massive scalar-tensor gravity.
U. Sperhake, C. J. Moore, R. Rosca, M. Agathos, D. Gerosa, C. D. Ott.
Physical Review Letters 119 (2017) 201103. arXiv:1708.03651 [gr-qc].

17. Nutational resonances, transitional precession, and precession-averaged evolution in binary black-hole systems.
X. Zhao, M. Kesden, D. Gerosa.
Physical Review D 96 (2017) 024007. arXiv:1705.02369 [gr-qc].

16. Inferences about supernova physics from gravitational-wave measurements: GW151226 spin misalignment as an indicator of strong black-hole natal kicks.
R. O’Shaughnessy, D. Gerosa, D. Wysocki.
Physical Review Letters 119 (2017) 011101. arXiv:1704.03879 [gr-qc].
APS Editor’s choice (physics.aps.org). Covered by press release.

15. Are merging black holes born from stellar collapse or previous mergers?.
D. Gerosa, E. Berti.
Physical Review D 95 (2017) 124046. arXiv:1703.06223 [gr-qc].
PRD Editors’ Suggestion.

14. On the equal-mass limit of precessing black-hole binaries.
D. Gerosa, U. Sperhake, J. Vo\v{s}mera.
Classical and Quantum Gravity 34 (2017) 064004. arXiv:1612.05263 [gr-qc].

13. Black-hole kicks as new gravitational-wave observables.
D. Gerosa, C. J. Moore.
Physical Review Letters 117 (2016) 011101. arXiv:1606.04226 [gr-qc].
PRL Editors’ Suggestion. Covered by press release.

12. PRECESSION: Dynamics of spinning black-hole binaries with python.
D. Gerosa, M. Kesden.
Physical Review D 93 (2016) 124066. arXiv:1605.01067 [astro-ph.HE].
Open source code.

11. Numerical simulations of stellar collapse in scalar-tensor theories of gravity.
D. Gerosa, U. Sperhake, C. D. Ott.
Classical and Quantum Gravity 33 (2016) 135002. arXiv:1602.06952 [gr-qc].

10. Distinguishing black-hole spin-orbit resonances by their gravitational wave signatures. II: Full parameter estimation.
D. Trifir`o, R. O’Shaughnessy, D. Gerosa, E. Berti, M. Kesden, T. Littenberg, U. Sperhake.
Physical Review D 93 (2016) 044071. arXiv:1507.05587 [gr-qc].

9. Precessional instability in binary black holes with aligned spins.
D. Gerosa, M. Kesden, R. O’Shaughnessy, A. Klein, E. Berti, U. Sperhake, D. Trifir`o.
Physical Review Letters 115 (2015) 141102. arXiv:1506.09116 [gr-qc].
PRL Editors’ Suggestion.

8. Tensor-multi-scalar theories: relativistic stars and 3+1 decomposition.
M. Horbatsch, H. O. Silva, D. Gerosa, P. Pani, E. Berti, L. Gualtieri, U. Sperhake.
Classical and Quantum Gravity 32 (2015) 204001. arXiv:1505.07462 [gr-qc].
IoP Editor’s choice (CQG+, IOPselect).

7. Multi-timescale analysis of phase transitions in precessing black-hole binaries.
D. Gerosa, M. Kesden, U. Sperhake, E. Berti, R. O’Shaughnessy.
Physical Review D 92 (2015) 064016. arXiv:1506.03492 [gr-qc].

6. Spin alignment and differential accretion in merging black hole binaries.
D. Gerosa, B. Veronesi, G. Lodato, G. Rosotti.
Monthly Notices of the Royal Astronomical Society 451 (2015) 3941-3954. arXiv:1503.06807 [astro-ph.GA].

5. Effective potentials and morphological transitions for binary black-hole spin precession.
M. Kesden, D. Gerosa, R. O’Shaughnessy, E. Berti, U. Sperhake.
Physical Review Letters 114 (2015) 081103. arXiv:1411.0674 [gr-qc].
Covered by press release.

4. Missing black holes in brightest cluster galaxies as evidence for the occurrence of superkicks in nature.
D. Gerosa, A. Sesana.
Monthly Notices of the Royal Astronomical Society 446 (2015) 38-55. arXiv:1405.2072 [astro-ph.GA].

3. Distinguishing black-hole spin-orbit resonances by their gravitational-wave signatures.
D. Gerosa, R. O’Shaughnessy, M. Kesden, E. Berti, U. Sperhake.
Physical Review D 89 (2014) 124025. arXiv:1403.7147 [gr-qc].

2. Resonant-plane locking and spin alignment in stellar-mass black-hole binaries: a diagnostic of compact-binary formation.
D. Gerosa, M. Kesden, E. Berti, R. O’Shaughnessy, U. Sperhake.
Physical Review D 87 (2013) 10, 104028. arXiv:1302.4442 [gr-qc].

1. Black hole mergers: do gas discs lead to spin alignment?.
G. Lodato, D. Gerosa.
Monthly Notices of the Royal Astronomical Society 429 (2013) L30-L34. arXiv:1211.0284 [astro-ph.CO].

Other publications (white papers, proceedings, etc.)

12. Waveform modelling for the Laser Interferometer Space Antenna.
N. Afshordi, et al. (105 authors incl. D. Gerosa).
arXiv:2311.01300 [gr-qc].

11. QLUSTER: quick clusters of merging binary black holes.
D. Gerosa, M. Mould.
Moriond proceedings. arXiv:2305.04987 [astro-ph.HE].
Open source code.

10. Astrophysics with the Laser Interferometer Space Antenna.
P. Amaro-Seoane, et al. (155 authors incl. D. Gerosa).
Living Reviews in Relativity 26 (2022) 2. arXiv:2203.06016 [gr-qc].

9. New horizons for fundamental physics with LISA.
K. G. Arun, et al. (141 authors incl. D. Gerosa).
Living Reviews in Relativity 25 (2022) 4. arXiv:2205.01597 [gr-qc].

8. Prospects for fundamental physics with LISA.
E. Barausse, et al. (320 authors incl. D. Gerosa).
General Relativity and Gravitation 52 (2020) 8, 81. arXiv:2001.09793 [gr-qc].

7. Black holes, gravitational waves and fundamental physics: a roadmap.
L. Barack, et al. (199 authors incl. D. Gerosa).
Classical and Quantum Gravity 36 (2019) 143001. arXiv:1806.05195 [gr-qc].

6. Reanalysis of LIGO black-hole coalescences with alternative prior assumptions.
D. Gerosa, S. Vitale, C.-J. Haster, K. Chatziioannou, A. Zimmerman.
IAU Proceedigs 338 (2018) 22-28. arXiv:1712.06635 [astro-ph.HE].

5. Surprises from the spins: astrophysics and relativity with detections of spinning black-hole mergers.
D. Gerosa.
Journal of Physics: Conference Series 957 (2018) 1, 012014. arXiv:1711.10038 [astro-ph.HE].

4. filltex: Automatic queries to ADS and INSPIRE databases to fill LaTex bibliography.
D. Gerosa, M. Vallisneri.
Journal of Open Source Software 2 (2017) 13.
Open source code.

3. Testing general relativity with present and future astrophysical observations.
E. Berti, et al. (53 authors incl. D. Gerosa).
Classical and Quantum Gravity 32 (2015) 243001. Topical Review. arXiv:1501.07274 [gr-qc].

2. Rival families: waveforms from resonant black-hole binaries as probes of their astrophysical formation history.
D. Gerosa.
Astrophysics and Space Science Proceedings 40 (2015) 137-145.

1. Spin alignment effects in black hole binaries.
D. Gerosa.
Caltech Undergraduate Research Journal (CURJ) 15:1 (2014) 17-26.