The SXS collaboration’s third catalog of binary black hole simulations

Mark A. Scheel; Michael Boyle; Keefe Mitman; Nils Deppe; Leo C. Stein; Cristóbal Armaza; Marceline S. Bonilla; Luisa T. Buchman; Andrea Ceja; Himanshu Chaudhary; Yitian Chen; Maxence Corman; Károly Zoltán Csukás; C. Melize Ferrus; Scott E. Field; Matthew Giesler; Sarah Habib; François Hébert; Daniel A. Hemberger; Dante A.B. Iozzo; Tousif Islam; Ken Z. Jones; Aniket Khairnar; Lawrence E. Kidder; Taylor Knapp; Prayush Kumar; Guillermo Lara; Oliver Long; Geoffrey Lovelace; Sizheng Ma; Denyz Melchor; Marlo Morales; Jordan Moxon; Peter James Nee; Kyle C. Nelli; Eamonn O’Shea; Serguei Ossokine; Robert Owen; Harald P. Pfeiffer; Isabella G. Pretto; Teresita Ramirez-Aguilar; Antoni Ramos-Buades; Adhrit Ravichandran; Abhishek Ravishankar; Samuel Rodriguez; Hannes R. Rüter; Jennifer Sanchez; Md Arif Shaikh; Dongze Sun; Béla Szilágyi; Daniel Tellez; Saul A. Teukolsky; Sierra Thomas; William Throwe; Vijay Varma; Nils L. Vu; Marissa Walker; Nikolas A. Wittek; Jooheon Yoo

doi:10.1088/1361-6382/adfd34

The SXS collaboration’s third catalog of binary black hole simulations

Mark A. Scheel, Michael Boyle, Keefe Mitman, Nils Deppe, Leo C. Stein, Cristóbal Armaza, Marceline S. Bonilla, Luisa T. Buchman, Andrea Ceja, Himanshu Chaudhary, Yitian Chen, Maxence Corman, Károly Zoltán Csukás, C. Melize Ferrus, Scott E. Field, Matthew Giesler, Sarah Habib, François Hébert, Daniel A. Hemberger, Dante A.B. IozzoTousif Islam, Ken Z. Jones, Aniket Khairnar, Lawrence E. Kidder, Taylor Knapp, Prayush Kumar, Guillermo Lara, Oliver Long, Geoffrey Lovelace, Sizheng Ma, Denyz Melchor, Marlo Morales, Jordan Moxon, Peter James Nee, Kyle C. Nelli, Eamonn O’Shea, Serguei Ossokine, Robert Owen, Harald P. Pfeiffer, Isabella G. Pretto, Teresita Ramirez-Aguilar, Antoni Ramos-Buades, Adhrit Ravichandran, Abhishek Ravishankar, Samuel Rodriguez, Hannes R. Rüter, Jennifer Sanchez, Md Arif Shaikh, Dongze Sun, Béla Szilágyi, Daniel Tellez, Saul A. Teukolsky, Sierra Thomas, William Throwe, Vijay Varma, Nils L. Vu, Marissa Walker, Nikolas A. Wittek, Jooheon Yoo

Research output: Contribution to journal › Article › peer-review

Abstract

We present a major update to the Simulating eXtreme Spacetimes (SXSs) Collaboration’s catalog of binary black hole (BBH) simulations. Using highly efficient spectral methods implemented in the Spectral Einstein Code (SpEC), we have nearly doubled the total number of binary configurations from 2018 to 3756. The catalog now more densely covers the parameter space with precessing simulations up to mass ratio q = 8 and dimensionless spins up to | χ → | ⩽ 0.8 with near-zero eccentricity. The catalog also includes some simulations at higher mass ratios with moderate spin and more than 250 eccentric simulations. We have also deprecated and rerun some simulations from our previous catalog (e.g. simulations run with a much older version of SpEC or that had anomalously high errors in the waveform). The median waveform difference (which is similar to the mismatch) between resolutions over the simulations in the catalog is 4 × 10 − 4 . The simulations have a median of 22 orbits, while the longest simulation has 148 orbits. We have corrected each waveform in the catalog to be in the binary’s center-of-mass frame and exhibit gravitational-wave memory. We estimate the total CPU cost of all simulations in the catalog to be 480 000 000 core-hours. We find that using spectral methods for BBH simulations is over 1000 times more efficient than previously published finite-difference simulations. The full catalog is publicly available through the sxs Python package and at https://data.black-holes.org .

Original language	English
Article number	195017
Journal	Classical and Quantum Gravity
Volume	42
Issue number	19
DOIs	https://doi.org/10.1088/1361-6382/adfd34
State	Published - Oct 3 2025
Externally published	Yes

Keywords

binaries
black hole
general relativity
gravitational waves
numerical relativity

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10.1088/1361-6382/adfd34

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Scheel, M. A., Boyle, M., Mitman, K., Deppe, N., Stein, L. C., Armaza, C., Bonilla, M. S., Buchman, L. T., Ceja, A., Chaudhary, H., Chen, Y., Corman, M., Zoltán Csukás, K., Melize Ferrus, C., Field, S. E., Giesler, M., Habib, S., Hébert, F., Hemberger, D. A., ... Yoo, J. (2025). The SXS collaboration’s third catalog of binary black hole simulations. Classical and Quantum Gravity, 42(19), Article 195017. https://doi.org/10.1088/1361-6382/adfd34

@article{758da1c12aee438c98f73724aceb5586,

title = "The SXS collaboration{\textquoteright}s third catalog of binary black hole simulations",

abstract = "We present a major update to the Simulating eXtreme Spacetimes (SXSs) Collaboration{\textquoteright}s catalog of binary black hole (BBH) simulations. Using highly efficient spectral methods implemented in the Spectral Einstein Code (SpEC), we have nearly doubled the total number of binary configurations from 2018 to 3756. The catalog now more densely covers the parameter space with precessing simulations up to mass ratio q = 8 and dimensionless spins up to | χ → | ⩽ 0.8 with near-zero eccentricity. The catalog also includes some simulations at higher mass ratios with moderate spin and more than 250 eccentric simulations. We have also deprecated and rerun some simulations from our previous catalog (e.g. simulations run with a much older version of SpEC or that had anomalously high errors in the waveform). The median waveform difference (which is similar to the mismatch) between resolutions over the simulations in the catalog is 4 × 10 − 4 . The simulations have a median of 22 orbits, while the longest simulation has 148 orbits. We have corrected each waveform in the catalog to be in the binary{\textquoteright}s center-of-mass frame and exhibit gravitational-wave memory. We estimate the total CPU cost of all simulations in the catalog to be 480 000 000 core-hours. We find that using spectral methods for BBH simulations is over 1000 times more efficient than previously published finite-difference simulations. The full catalog is publicly available through the sxs Python package and at https://data.black-holes.org .",

keywords = "binaries, black hole, general relativity, gravitational waves, numerical relativity",

author = "Scheel, \{Mark A.\} and Michael Boyle and Keefe Mitman and Nils Deppe and Stein, \{Leo C.\} and Crist{\'o}bal Armaza and Bonilla, \{Marceline S.\} and Buchman, \{Luisa T.\} and Andrea Ceja and Himanshu Chaudhary and Yitian Chen and Maxence Corman and \{Zolt{\'a}n Csuk{\'a}s\}, K{\'a}roly and \{Melize Ferrus\}, C. and Field, \{Scott E.\} and Matthew Giesler and Sarah Habib and Fran{\c c}ois H{\'e}bert and Hemberger, \{Daniel A.\} and Iozzo, \{Dante A.B.\} and Tousif Islam and Jones, \{Ken Z.\} and Aniket Khairnar and Kidder, \{Lawrence E.\} and Taylor Knapp and Prayush Kumar and Guillermo Lara and Oliver Long and Geoffrey Lovelace and Sizheng Ma and Denyz Melchor and Marlo Morales and Jordan Moxon and \{James Nee\}, Peter and Nelli, \{Kyle C.\} and Eamonn O{\textquoteright}Shea and Serguei Ossokine and Robert Owen and Pfeiffer, \{Harald P.\} and Pretto, \{Isabella G.\} and Teresita Ramirez-Aguilar and Antoni Ramos-Buades and Adhrit Ravichandran and Abhishek Ravishankar and Samuel Rodriguez and R{\"u}ter, \{Hannes R.\} and Jennifer Sanchez and \{Arif Shaikh\}, Md and Dongze Sun and B{\'e}la Szil{\'a}gyi and Daniel Tellez and Teukolsky, \{Saul A.\} and Sierra Thomas and William Throwe and Vijay Varma and Vu, \{Nils L.\} and Marissa Walker and Wittek, \{Nikolas A.\} and Jooheon Yoo",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Published by IOP Publishing Ltd.",

year = "2025",

month = oct,

day = "3",

doi = "10.1088/1361-6382/adfd34",

language = "English",

volume = "42",

journal = "Classical and Quantum Gravity",

issn = "0264-9381",

publisher = "IOP Publishing Ltd.",

number = "19",

}

Scheel, MA, Boyle, M, Mitman, K, Deppe, N, Stein, LC, Armaza, C, Bonilla, MS, Buchman, LT, Ceja, A, Chaudhary, H, Chen, Y, Corman, M, Zoltán Csukás, K, Melize Ferrus, C, Field, SE, Giesler, M, Habib, S, Hébert, F, Hemberger, DA, Iozzo, DAB, Islam, T, Jones, KZ, Khairnar, A, Kidder, LE, Knapp, T, Kumar, P, Lara, G, Long, O, Lovelace, G, Ma, S, Melchor, D, Morales, M, Moxon, J, James Nee, P, Nelli, KC, O’Shea, E, Ossokine, S, Owen, R, Pfeiffer, HP, Pretto, IG, Ramirez-Aguilar, T, Ramos-Buades, A, Ravichandran, A, Ravishankar, A, Rodriguez, S, Rüter, HR, Sanchez, J, Arif Shaikh, M, Sun, D, Szilágyi, B, Tellez, D, Teukolsky, SA, Thomas, S, Throwe, W, Varma, V, Vu, NL, Walker, M, Wittek, NA & Yoo, J 2025, 'The SXS collaboration’s third catalog of binary black hole simulations', Classical and Quantum Gravity, vol. 42, no. 19, 195017. https://doi.org/10.1088/1361-6382/adfd34

TY - JOUR

T1 - The SXS collaboration’s third catalog of binary black hole simulations

AU - Scheel, Mark A.

AU - Boyle, Michael

AU - Mitman, Keefe

AU - Deppe, Nils

AU - Stein, Leo C.

AU - Armaza, Cristóbal

AU - Bonilla, Marceline S.

AU - Buchman, Luisa T.

AU - Ceja, Andrea

AU - Chaudhary, Himanshu

AU - Chen, Yitian

AU - Corman, Maxence

AU - Zoltán Csukás, Károly

AU - Melize Ferrus, C.

AU - Field, Scott E.

AU - Giesler, Matthew

AU - Habib, Sarah

AU - Hébert, François

AU - Hemberger, Daniel A.

AU - Iozzo, Dante A.B.

AU - Islam, Tousif

AU - Jones, Ken Z.

AU - Khairnar, Aniket

AU - Kidder, Lawrence E.

AU - Knapp, Taylor

AU - Kumar, Prayush

AU - Lara, Guillermo

AU - Long, Oliver

AU - Lovelace, Geoffrey

AU - Ma, Sizheng

AU - Melchor, Denyz

AU - Morales, Marlo

AU - Moxon, Jordan

AU - James Nee, Peter

AU - Nelli, Kyle C.

AU - O’Shea, Eamonn

AU - Ossokine, Serguei

AU - Owen, Robert

AU - Pfeiffer, Harald P.

AU - Pretto, Isabella G.

AU - Ramirez-Aguilar, Teresita

AU - Ramos-Buades, Antoni

AU - Ravichandran, Adhrit

AU - Ravishankar, Abhishek

AU - Rodriguez, Samuel

AU - Rüter, Hannes R.

AU - Sanchez, Jennifer

AU - Arif Shaikh, Md

AU - Sun, Dongze

AU - Szilágyi, Béla

AU - Tellez, Daniel

AU - Teukolsky, Saul A.

AU - Thomas, Sierra

AU - Throwe, William

AU - Varma, Vijay

AU - Vu, Nils L.

AU - Walker, Marissa

AU - Wittek, Nikolas A.

AU - Yoo, Jooheon

PY - 2025/10/3

Y1 - 2025/10/3

N2 - We present a major update to the Simulating eXtreme Spacetimes (SXSs) Collaboration’s catalog of binary black hole (BBH) simulations. Using highly efficient spectral methods implemented in the Spectral Einstein Code (SpEC), we have nearly doubled the total number of binary configurations from 2018 to 3756. The catalog now more densely covers the parameter space with precessing simulations up to mass ratio q = 8 and dimensionless spins up to | χ → | ⩽ 0.8 with near-zero eccentricity. The catalog also includes some simulations at higher mass ratios with moderate spin and more than 250 eccentric simulations. We have also deprecated and rerun some simulations from our previous catalog (e.g. simulations run with a much older version of SpEC or that had anomalously high errors in the waveform). The median waveform difference (which is similar to the mismatch) between resolutions over the simulations in the catalog is 4 × 10 − 4 . The simulations have a median of 22 orbits, while the longest simulation has 148 orbits. We have corrected each waveform in the catalog to be in the binary’s center-of-mass frame and exhibit gravitational-wave memory. We estimate the total CPU cost of all simulations in the catalog to be 480 000 000 core-hours. We find that using spectral methods for BBH simulations is over 1000 times more efficient than previously published finite-difference simulations. The full catalog is publicly available through the sxs Python package and at https://data.black-holes.org .

AB - We present a major update to the Simulating eXtreme Spacetimes (SXSs) Collaboration’s catalog of binary black hole (BBH) simulations. Using highly efficient spectral methods implemented in the Spectral Einstein Code (SpEC), we have nearly doubled the total number of binary configurations from 2018 to 3756. The catalog now more densely covers the parameter space with precessing simulations up to mass ratio q = 8 and dimensionless spins up to | χ → | ⩽ 0.8 with near-zero eccentricity. The catalog also includes some simulations at higher mass ratios with moderate spin and more than 250 eccentric simulations. We have also deprecated and rerun some simulations from our previous catalog (e.g. simulations run with a much older version of SpEC or that had anomalously high errors in the waveform). The median waveform difference (which is similar to the mismatch) between resolutions over the simulations in the catalog is 4 × 10 − 4 . The simulations have a median of 22 orbits, while the longest simulation has 148 orbits. We have corrected each waveform in the catalog to be in the binary’s center-of-mass frame and exhibit gravitational-wave memory. We estimate the total CPU cost of all simulations in the catalog to be 480 000 000 core-hours. We find that using spectral methods for BBH simulations is over 1000 times more efficient than previously published finite-difference simulations. The full catalog is publicly available through the sxs Python package and at https://data.black-holes.org .

KW - binaries

KW - black hole

KW - general relativity

KW - gravitational waves

KW - numerical relativity

UR - https://www.scopus.com/pages/publications/105017990168

U2 - 10.1088/1361-6382/adfd34

DO - 10.1088/1361-6382/adfd34

M3 - Article

AN - SCOPUS:105017990168

SN - 0264-9381

VL - 42

JO - Classical and Quantum Gravity

JF - Classical and Quantum Gravity

IS - 19

M1 - 195017

ER -

The SXS collaboration’s third catalog of binary black hole simulations

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Keywords

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