Generic update

Author: dgerosa

_citations.md

@@ -1,30 +1,30 @@
 ## Citation Summary
 
-- **Total ADS citations**: 9677
+- **Total ADS citations**: 9698
 - **Total INSPIRE citations**: 10561
-- **Total MAX citations**: 10639
+- **Total MAX citations**: 10644
 - **h-index**: 47
 
 ## Paper list sorted by citation count
 
 | # | Author | Year | Title | ADS | INSPIRE | MAX |
 |---|--------|------|-------|-----|---------|-----|
-| **1** | Berti | 2015 | Testing general relativity with present and future astrophysical observations | 1413 | 1585 | 1585 |
-| **2** | Barack | 2019 | Black holes, gravitational waves and fundamental physics: a roadmap | 837 | 927 | 927 |
-| **3** | Amaro-Seoane | 2022 | Astrophysics with the Laser Interferometer Space Antenna | 734 | 686 | 734 |
+| **1** | Berti | 2015 | Testing general relativity with present and future astrophysical observations | 1414 | 1585 | 1585 |
+| **2** | Barack | 2019 | Black holes, gravitational waves and fundamental physics: a roadmap | 838 | 927 | 927 |
+| **3** | Amaro-Seoane | 2022 | Astrophysics with the Laser Interferometer Space Antenna | 736 | 686 | 736 |
 | **4** | Belczynski | 2020 | Evolutionary roads leading to low effective spins, high black hole masses, and O1/O2 rates for LIGO/Virgo binary black holes | 455 | 471 | 471 |
-| **5** | Varma | 2019 | Surrogate models for precessing binary black hole simulations with unequal masses | 426 | 445 | 445 |
-| **6** | Barausse | 2020 | Prospects for fundamental physics with LISA | 390 | 439 | 439 |
-| **7** | Gerosa | 2017 | Are merging black holes born from stellar collapse or previous mergers? | 330 | 355 | 355 |
-| **8** | Arun | 2022 | New horizons for fundamental physics with LISA | 300 | 354 | 354 |
-| **9** | Gerosa | 2021 | Hierarchical mergers of stellar-mass black holes and their gravitational-wave signatures | 262 | 279 | 279 |
+| **5** | Varma | 2019 | Surrogate models for precessing binary black hole simulations with unequal masses | 429 | 445 | 445 |
+| **6** | Barausse | 2020 | Prospects for fundamental physics with LISA | 389 | 439 | 439 |
+| **7** | Gerosa | 2017 | Are merging black holes born from stellar collapse or previous mergers? | 331 | 355 | 355 |
+| **8** | Arun | 2022 | New horizons for fundamental physics with LISA | 301 | 354 | 354 |
+| **9** | Gerosa | 2021 | Hierarchical mergers of stellar-mass black holes and their gravitational-wave signatures | 263 | 279 | 279 |
 | **10** | Gerosa | 2018 | Spin orientations of merging black holes formed from the evolution of stellar binaries | 214 | 235 | 235 |
-| **11** | Afshordi | 2025 | Waveform modelling for the Laser Interferometer Space Antenna | 143 | 174 | 174 |
-| **12** | Gerosa | 2015 | Multi-timescale analysis of phase transitions in precessing black-hole binaries | 138 | 162 | 162 |
+| **11** | Afshordi | 2025 | Waveform modelling for the Laser Interferometer Space Antenna | 144 | 174 | 174 |
+| **12** | Gerosa | 2015 | Multi-timescale analysis of phase transitions in precessing black-hole binaries | 139 | 162 | 162 |
 | **13** | Varma | 2019 | High-accuracy mass, spin, and recoil predictions of generic black-hole merger remnants | 142 | 159 | 159 |
 | **14** | Gerosa | 2013 | Resonant-plane locking and spin alignment in stellar-mass black-hole binaries: a diagnostic of compact-binary formation | 143 | 158 | 158 |
 | **15** | Islam | 2021 | Eccentric binary black hole surrogate models for the gravitational waveform and remnant properties: comparable mass, nonspinning case | 127 | 138 | 138 |
-| **16** | Vitale | 2020 | Inferring the properties of a population of compact binaries in presence of selection effects | 128 | 137 | 137 |
+| **16** | Vitale | 2020 | Inferring the properties of a population of compact binaries in presence of selection effects | 129 | 137 | 137 |
 | **17** | Kesden | 2015 | Effective potentials and morphological transitions for binary black-hole spin precession | 115 | 137 | 137 |
 | **18** | Ng | 2018 | Gravitational-wave astrophysics with effective-spin measurements: asymmetries and selection biases | 115 | 126 | 126 |
 | **19** | Baibhav | 2019 | Gravitational-wave detection rates for compact binaries formed in isolation: LIGO/Virgo O3 and beyond | 108 | 125 | 125 |
@@ -38,27 +38,27 @@
 | **27** | Taylor | 2018 | Mining gravitational-wave catalogs to understand binary stellar evolution: a new hierarchical bayesian framework | 92 | 96 | 96 |
 | **28** | Baibhav | 2020 | The mass gap, the spin gap, and the origin of merging binary black holes | 79 | 91 | 91 |
 | **29** | O'Shaughnessy | 2017 | Inferences about supernova physics from gravitational-wave measurements: GW151226 spin misalignment as an indicator of strong black-hole natal kicks | 79 | 87 | 87 |
-| **30** | Gerosa | 2021 | A generalized precession parameter $$\chi_\mathrm{p}$$ to interpret gravitational-wave data | 66 | 79 | 79 |
+| **30** | Gerosa | 2021 | A generalized precession parameter $$\chi_\mathrm{p}$$ to interpret gravitational-wave data | 67 | 79 | 79 |
 | **31** | Bouffanais | 2019 | Constraining the fraction of binary black holes formed in isolation and young star clusters with gravitational-wave data | 76 | 78 | 78 |
 | **32** | Korol | 2020 | Populations of double white dwarfs in Milky Way satellites and their detectability with LISA | 76 | 76 | 76 |
 | **33** | Horbatsch | 2015 | Tensor-multi-scalar theories: relativistic stars and 3+1 decomposition | 70 | 74 | 74 |
 | **34** | Klein | 2022 | The last three years: multiband gravitational-wave observations of stellar-mass binary black holes | 61 | 68 | 68 |
 | **35** | Gerosa | 2016 | Black-hole kicks as new gravitational-wave observables | 61 | 66 | 66 |
 | **36** | Buscicchio | 2021 | Bayesian parameter estimation of stellar-mass black-hole binaries with LISA | 55 | 64 | 64 |
-| **37** | Gupta | 2020 | Black holes in the low mass gap: Implications for gravitational wave observations | 58 | 64 | 64 |
+| **37** | Gupta | 2020 | Black holes in the low mass gap: Implications for gravitational wave observations | 59 | 64 | 64 |
 | **38** | Gerosa | 2018 | Black-hole kicks from numerical-relativity surrogate models | 56 | 62 | 62 |
 | **39** | Gerosa | 2015 | Precessional instability in binary black holes with aligned spins | 56 | 61 | 61 |
 | **40** | Gerosa | 2020 | Astrophysical implications of GW190412 as a remnant of a previous black-hole merger | 53 | 60 | 60 |
 | **41** | Gerosa | 2016 | Numerical simulations of stellar collapse in scalar-tensor theories of gravity | 52 | 60 | 60 |
 | **42** | Gerosa | 2014 | Distinguishing black-hole spin-orbit resonances by their gravitational-wave signatures | 47 | 57 | 57 |
 | **43** | Mould | 2022 | Deep learning and Bayesian inference of gravitational-wave populations: hierarchical black-hole mergers | 52 | 56 | 56 |
-| **44** | Gerosa | 2015 | Spin alignment and differential accretion in merging black hole binaries | 54 | 49 | 54 |
+| **44** | Gerosa | 2015 | Spin alignment and differential accretion in merging black hole binaries | 55 | 49 | 55 |
 | **45** | Mould | 2022 | Which black hole formed first? Mass-ratio reversal in massive binary stars from gravitational-wave data | 46 | 53 | 53 |
 | **46** | Roebber | 2020 | Milky Way satellites shining bright in gravitational waves | 44 | 50 | 50 |
 | **47** | Sperhake | 2017 | Long-lived inverse chirp signals from core collapse in massive scalar-tensor gravity | 43 | 50 | 50 |
 | **48** | Gerosa | 2015 | Missing black holes in brightest cluster galaxies as evidence for the occurrence of superkicks in nature | 41 | 47 | 47 |
 | **49** | Moore | 2021 | Testing general relativity with gravitational-wave catalogs: the insidious nature of waveform systematics | 41 | 46 | 46 |
-| **50** | Gangardt | 2024 | pAGN: the one-stop solution for AGN disc modeling | 42 | 44 | 44 |
+| **50** | Gangardt | 2024 | pAGN: the one-stop solution for AGN disc modeling | 43 | 44 | 44 |
 | **51** | Tso | 2019 | Optimizing LIGO with LISA forewarnings to improve black-hole spectroscopy | 37 | 43 | 43 |
 | **52** | Trifiro' | 2016 | Distinguishing black-hole spin-orbit resonances by their gravitational wave signatures. II: Full parameter estimation | 34 | 42 | 42 |
 | **53** | Gerosa | 2020 | Gravitational-wave selection effects using neural-network classifiers | 37 | 41 | 41 |
@@ -97,15 +97,15 @@
 | **86** | Gerosa | 2020 | The Bardeen-Petterson effect in accreting supermassive black-hole binaries: a systematic approach | 17 | 16 | 17 |
 | **87** | Gerosa | 2017 | filltex: Automatic queries to ADS and INSPIRE databases to fill LaTex bibliography | 13 | 16 | 16 |
 | **88** | Mould | 2023 | One to many: comparing single gravitational-wave events to astrophysical populations | 14 | 15 | 15 |
-| **89** | Gerosa | 2024 | Quick recipes for gravitational-wave selection effects | 12 | 14 | 14 |
+| **89** | Gerosa | 2024 | Quick recipes for gravitational-wave selection effects | 13 | 14 | 14 |
 | **90** | Tenorio | 2025 | Scalable data-analysis framework for long-duration gravitational waves from compact binaries using short Fourier transforms | 10 | 12 | 12 |
 | **91** | Pacilio | 2024 | Catalog variance of testing general relativity with gravitational-wave data | 9 | 12 | 12 |
 | **92** | Steinle | 2023 | The Bardeen-Petterson effect, disk breaking, and the spin orientations of supermassive black-hole binaries | 10 | 12 | 12 |
 | **93** | Reali | 2020 | Mapping the asymptotic inspiral of precessing binary black holes to their merger remnants | 10 | 12 | 12 |
 | **94** | Gangardt | 2022 | Constraining black-hole binary spin precession and nutation with sequential prior conditioning | 10 | 11 | 11 |
 | **95** | Pedrotti | 2025 | Cosmology with the angular cross-correlation of gravitational-wave and galaxy catalogs: forecasts for next-generation interferometers and the Euclid survey | 10 | 10 | 10 |
 | **96** | Santoliquido | 2024 | Classifying binary black holes from Population III stars with the Einstein Telescope: a machine-learning approach | 10 | 8 | 10 |
-| **97** | Mould | 2024 | Calibrating signal-to-noise ratio detection thresholds using gravitational-wave catalogs | 8 | 10 | 10 |
+| **97** | Mould | 2024 | Calibrating signal-to-noise ratio detection thresholds using gravitational-wave catalogs | 9 | 10 | 10 |
 | **98** | De Renzis | 2022 | Characterization of merging black holes with two precessing spins | 7 | 10 | 10 |
 | **99** | Cole | 2025 | Sequential simulation-based inference for extreme mass ratio inspirals | 9 | 9 | 9 |
 | **100** | Fumagalli | 2025 | Non-adiabatic dynamics of eccentric black-hole binaries in post-Newtonian theory | 9 | 9 | 9 |
@@ -115,16 +115,16 @@
 | **104** | Stegmann | 2025 | Distinguishing the origin of eccentric black-hole mergers with gravitational-wave spin measurements | 7 | 6 | 7 |
 | **105** | Gerosa | 2025 | Which is which? Identification of the two compact objects in gravitational-wave binaries | 6 | 7 | 7 |
 | **106** | De Renzis | 2025 | Forecasting the population properties of merging black holes | 4 | 7 | 7 |
-| **107** | Kritos | 2024 | Minimum gas mass accreted by spinning intermediate-mass black holes in stellar clusters | 5 | 7 | 7 |
+| **107** | Kritos | 2024 | Minimum gas mass accreted by spinning intermediate-mass black holes in stellar clusters | 6 | 7 | 7 |
 | **108** | Steinle | 2024 | Probing AGN jet precession with LISA | 6 | 4 | 6 |
 | **109** | Gerosa | 2022 | The irreducible mass and the horizon area of LIGO's black holes | 6 | 5 | 6 |
 | **110** | Dabrowny | 2021 | Modeling the outcome of supernova explosions in binary population synthesis using the stellar compactness | 5 | 6 | 6 |
 | **111** | Varma | 2019 | The binary black hole explorer: on-the-fly visualizations of precessing binary black holes | 4 | 6 | 6 |
 | **112** | Toubiana | 2025 | Comparing astrophysical models to gravitational-wave data in the observable space | 5 | 4 | 5 |
-| **113** | Gerosa | 2018 | Surprises from the spins: astrophysics and relativity with detections of spinning black-hole mergers | 4 | 5 | 5 |
-| **114** | Chiaberge | 2025 | A recoiling supermassive black hole in a powerful quasar | 4 | 4 | 4 |
-| **115** | Giarda | 2025 | Accelerated inference of binary black-hole populations from the stochastic gravitational-wave background | 2 | 4 | 4 |
-| **116** | Boschini | 2024 | Astrophysical and relativistic modeling of the recoiling black-hole candidate in quasar 3C 186 | 4 | 4 | 4 |
+| **113** | Chiaberge | 2025 | A recoiling supermassive black hole in a powerful quasar | 5 | 4 | 5 |
+| **114** | Boschini | 2024 | Astrophysical and relativistic modeling of the recoiling black-hole candidate in quasar 3C 186 | 5 | 4 | 5 |
+| **115** | Gerosa | 2018 | Surprises from the spins: astrophysics and relativity with detections of spinning black-hole mergers | 4 | 5 | 5 |
+| **116** | Giarda | 2025 | Accelerated inference of binary black-hole populations from the stochastic gravitational-wave background | 2 | 4 | 4 |
 | **117** | Speri | 2025 | Ab uno disce omnes: Single-harmonic search for extreme mass-ratio inspirals | 2 | 2 | 2 |
 | **118** | Tenorio | 2025 | Where did heavy binaries go? Gravitational-wave populations using Delaunay triangulation with optimized complexity | 2 | 1 | 2 |
 | **119** | Gerosa | 2023 | QLUSTER: quick clusters of merging binary black holes | 2 | 0 | 2 |
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-*Last updated: 2026-01-30 01:01:13 UTC*
+*Last updated: 2026-01-31 01:01:16 UTC*

_group.md

@@ -259,4 +259,4 @@ Here are the amazing students who are currently completing research projects wit
 
 
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-*Last updated: 2026-01-30 01:01:13 UTC*
+*Last updated: 2026-01-31 01:01:16 UTC*

_publications.md

@@ -690,4 +690,4 @@ E. Berti, et al. (53 authors incl. **D. Gerosa**).\
 
 
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-*Last updated: 2026-01-30 01:01:13 UTC*
+*Last updated: 2026-01-31 01:01:16 UTC*

_talks.md

@@ -549,4 +549,4 @@ Liceo Candia and Liceo Frassati, Seregno, Italy, Jan 2018.
 
 
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-*Last updated: 2026-01-30 01:01:13 UTC*
+*Last updated: 2026-01-31 01:01:16 UTC*