What is the nature of GW230529? An exploration of the gravitational lensing hypothesis

Justin Janquart; David Keitel; Rico K. L. Lo; Juno C. L. Chan; Jose María Ezquiaga; Otto A. Hannuksela; Alvin K. Y. Li; Anupreeta More; Hemantakumar Phurailatpam; Neha Singh; Laura E. Uronen; Mick Wright; Naresh Adhikari; Sylvia Biscoveanu; Tomasz Bulik; Amanda M. Farah; Anna Heffernan; Prathamesh Joshi; Vincent Juste; Atul Kedia; Shania A. Nichols; Geraint Pratten; C. Rawcliffe; Soumen Roy; Elise M. Sänger; Hui Tong; M. Trevor; Luka Vujeva; Michael Zevin

doi:10.1093/mnras/staf049

What is the nature of GW230529? An exploration of the gravitational lensing hypothesis

Justin Janquart^*, David Keitel^*, Rico K. L. Lo^*, Juno C. L. Chan, Jose María Ezquiaga, Otto A. Hannuksela, Alvin K. Y. Li, Anupreeta More, Hemantakumar Phurailatpam, Neha Singh, Laura E. Uronen, Mick Wright, Naresh Adhikari, Sylvia Biscoveanu, Tomasz Bulik, Amanda M. Farah, Anna Heffernan, Prathamesh Joshi, Vincent Juste, Atul KediaShania A. Nichols, Geraint Pratten, C. Rawcliffe, Soumen Roy, Elise M. Sänger, Hui Tong, M. Trevor, Luka Vujeva, Michael Zevin

^*Corresponding author for this work

Institute of Cosmology & Gravitation

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

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Abstract

On the 29th of May 2023, the LIGO-Virgo-KAGRA Collaboration observed a compact binary coalescence event consistent with a neutron star-black hole merger, though the heavier object of mass 2.5-4.5 M_⊙ would fall into the purported lower mass gap. An alternative explanation for apparent observations of events in this mass range has been suggested as strongly gravitationally lensed binary neutron stars. In this scenario, magnification would lead to the source appearing closer and heavier than it really is. Here, we investigate the chances and possible consequences for the GW230529 event to be gravitationally lensed. We find this would require high magnifications and we obtain low rates for observing such an event, with a relative fraction of lensed versus unlensed observed events of 2×10⁻³ at most. When comparing the lensed and unlensed hypotheses accounting for the latest rates and population model, we find a 1/58 chance of lensing, disfavoring this option. Moreover, when the magnification is assumed to be strong enough to bring the mass of the heavier binary component below the standard limits on neutron star masses, we find high probability for the lighter object to have a sub-solar mass, making the binary even more exotic than a mass-gap neutron star-black hole system. Even when the secondary is not sub-solar, its tidal deformability would likely be measurable, which is not the case for GW230529. Finally, we do not find evidence for extra lensing signatures such as the arrival of additional lensed images, type-II image dephasing, or microlensing. Therefore, we conclude it is unlikely for GW230529 to be a strongly gravitationally lensed binary neutron star signal.

Original language	English
Pages (from-to)	1001-1014
Number of pages	14
Journal	Monthly Notices of the Royal Astronomical Society
Volume	537
Issue number	2
Early online date	11 Jan 2025
DOIs	https://doi.org/10.1093/mnras/staf049
Publication status	Published - 1 Feb 2025

Keywords

gravitational lensing: micro
gravitational lensing: strong
gravitational waves
UKRI
STFC
ST/W507477/1

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Janquart, J., Keitel, D., Lo, R. K. L., Chan, J. C. L., Ezquiaga, J. M., Hannuksela, O. A., Li, A. K. Y., More, A., Phurailatpam, H., Singh, N., Uronen, L. E., Wright, M., Adhikari, N., Biscoveanu, S., Bulik, T., Farah, A. M., Heffernan, A., Joshi, P., Juste, V., ... Zevin, M. (2025). What is the nature of GW230529? An exploration of the gravitational lensing hypothesis. Monthly Notices of the Royal Astronomical Society, 537(2), 1001-1014. https://doi.org/10.1093/mnras/staf049

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title = "What is the nature of GW230529? An exploration of the gravitational lensing hypothesis",

abstract = "On the 29th of May 2023, the LIGO-Virgo-KAGRA Collaboration observed a compact binary coalescence event consistent with a neutron star-black hole merger, though the heavier object of mass 2.5-4.5 M⊙ would fall into the purported lower mass gap. An alternative explanation for apparent observations of events in this mass range has been suggested as strongly gravitationally lensed binary neutron stars. In this scenario, magnification would lead to the source appearing closer and heavier than it really is. Here, we investigate the chances and possible consequences for the GW230529 event to be gravitationally lensed. We find this would require high magnifications and we obtain low rates for observing such an event, with a relative fraction of lensed versus unlensed observed events of 2×10−3 at most. When comparing the lensed and unlensed hypotheses accounting for the latest rates and population model, we find a 1/58 chance of lensing, disfavoring this option. Moreover, when the magnification is assumed to be strong enough to bring the mass of the heavier binary component below the standard limits on neutron star masses, we find high probability for the lighter object to have a sub-solar mass, making the binary even more exotic than a mass-gap neutron star-black hole system. Even when the secondary is not sub-solar, its tidal deformability would likely be measurable, which is not the case for GW230529. Finally, we do not find evidence for extra lensing signatures such as the arrival of additional lensed images, type-II image dephasing, or microlensing. Therefore, we conclude it is unlikely for GW230529 to be a strongly gravitationally lensed binary neutron star signal.",

keywords = "gravitational lensing: micro, gravitational lensing: strong, gravitational waves, UKRI, STFC, ST/W507477/1",

author = "Justin Janquart and David Keitel and Lo, {Rico K. L.} and Chan, {Juno C. L.} and Ezquiaga, {Jose Mar{\'i}a} and Hannuksela, {Otto A.} and Li, {Alvin K. Y.} and Anupreeta More and Hemantakumar Phurailatpam and Neha Singh and Uronen, {Laura E.} and Mick Wright and Naresh Adhikari and Sylvia Biscoveanu and Tomasz Bulik and Farah, {Amanda M.} and Anna Heffernan and Prathamesh Joshi and Vincent Juste and Atul Kedia and Nichols, {Shania A.} and Geraint Pratten and C. Rawcliffe and Soumen Roy and S{\"a}nger, {Elise M.} and Hui Tong and M. Trevor and Luka Vujeva and Michael Zevin",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). ",

year = "2025",

month = feb,

day = "1",

doi = "10.1093/mnras/staf049",

language = "English",

volume = "537",

pages = "1001--1014",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

publisher = "Oxford University Press",

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Janquart, J, Keitel, D, Lo, RKL, Chan, JCL, Ezquiaga, JM, Hannuksela, OA, Li, AKY, More, A, Phurailatpam, H, Singh, N, Uronen, LE, Wright, M, Adhikari, N, Biscoveanu, S, Bulik, T, Farah, AM, Heffernan, A, Joshi, P, Juste, V, Kedia, A, Nichols, SA, Pratten, G, Rawcliffe, C, Roy, S, Sänger, EM, Tong, H, Trevor, M, Vujeva, L & Zevin, M 2025, 'What is the nature of GW230529? An exploration of the gravitational lensing hypothesis', Monthly Notices of the Royal Astronomical Society, vol. 537, no. 2, pp. 1001-1014. https://doi.org/10.1093/mnras/staf049

TY - JOUR

T1 - What is the nature of GW230529? An exploration of the gravitational lensing hypothesis

AU - Janquart, Justin

AU - Keitel, David

AU - Lo, Rico K. L.

AU - Chan, Juno C. L.

AU - Ezquiaga, Jose María

AU - Hannuksela, Otto A.

AU - Li, Alvin K. Y.

AU - More, Anupreeta

AU - Phurailatpam, Hemantakumar

AU - Singh, Neha

AU - Uronen, Laura E.

AU - Wright, Mick

AU - Adhikari, Naresh

AU - Biscoveanu, Sylvia

AU - Bulik, Tomasz

AU - Farah, Amanda M.

AU - Heffernan, Anna

AU - Joshi, Prathamesh

AU - Juste, Vincent

AU - Kedia, Atul

AU - Nichols, Shania A.

AU - Pratten, Geraint

AU - Rawcliffe, C.

AU - Roy, Soumen

AU - Sänger, Elise M.

AU - Tong, Hui

AU - Trevor, M.

AU - Vujeva, Luka

AU - Zevin, Michael

PY - 2025/2/1

Y1 - 2025/2/1

N2 - On the 29th of May 2023, the LIGO-Virgo-KAGRA Collaboration observed a compact binary coalescence event consistent with a neutron star-black hole merger, though the heavier object of mass 2.5-4.5 M⊙ would fall into the purported lower mass gap. An alternative explanation for apparent observations of events in this mass range has been suggested as strongly gravitationally lensed binary neutron stars. In this scenario, magnification would lead to the source appearing closer and heavier than it really is. Here, we investigate the chances and possible consequences for the GW230529 event to be gravitationally lensed. We find this would require high magnifications and we obtain low rates for observing such an event, with a relative fraction of lensed versus unlensed observed events of 2×10−3 at most. When comparing the lensed and unlensed hypotheses accounting for the latest rates and population model, we find a 1/58 chance of lensing, disfavoring this option. Moreover, when the magnification is assumed to be strong enough to bring the mass of the heavier binary component below the standard limits on neutron star masses, we find high probability for the lighter object to have a sub-solar mass, making the binary even more exotic than a mass-gap neutron star-black hole system. Even when the secondary is not sub-solar, its tidal deformability would likely be measurable, which is not the case for GW230529. Finally, we do not find evidence for extra lensing signatures such as the arrival of additional lensed images, type-II image dephasing, or microlensing. Therefore, we conclude it is unlikely for GW230529 to be a strongly gravitationally lensed binary neutron star signal.

AB - On the 29th of May 2023, the LIGO-Virgo-KAGRA Collaboration observed a compact binary coalescence event consistent with a neutron star-black hole merger, though the heavier object of mass 2.5-4.5 M⊙ would fall into the purported lower mass gap. An alternative explanation for apparent observations of events in this mass range has been suggested as strongly gravitationally lensed binary neutron stars. In this scenario, magnification would lead to the source appearing closer and heavier than it really is. Here, we investigate the chances and possible consequences for the GW230529 event to be gravitationally lensed. We find this would require high magnifications and we obtain low rates for observing such an event, with a relative fraction of lensed versus unlensed observed events of 2×10−3 at most. When comparing the lensed and unlensed hypotheses accounting for the latest rates and population model, we find a 1/58 chance of lensing, disfavoring this option. Moreover, when the magnification is assumed to be strong enough to bring the mass of the heavier binary component below the standard limits on neutron star masses, we find high probability for the lighter object to have a sub-solar mass, making the binary even more exotic than a mass-gap neutron star-black hole system. Even when the secondary is not sub-solar, its tidal deformability would likely be measurable, which is not the case for GW230529. Finally, we do not find evidence for extra lensing signatures such as the arrival of additional lensed images, type-II image dephasing, or microlensing. Therefore, we conclude it is unlikely for GW230529 to be a strongly gravitationally lensed binary neutron star signal.

KW - gravitational lensing: micro

KW - gravitational lensing: strong

KW - gravitational waves

KW - UKRI

KW - STFC

KW - ST/W507477/1

UR - http://www.scopus.com/inward/record.url?scp=85216920482&partnerID=8YFLogxK

U2 - 10.1093/mnras/staf049

DO - 10.1093/mnras/staf049

M3 - Article

AN - SCOPUS:85216920482

SN - 0035-8711

VL - 537

SP - 1001

EP - 1014

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 2

ER -

What is the nature of GW230529? An exploration of the gravitational lensing hypothesis

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Keywords

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