Self-lensing binaries as probes of Supernova physics
Self-lensing binaries as probes of Supernova physics
Self-lensing (SL) in binary systems has the potential to provide a unique observational window into the Galactic population of compact objects. Using the startrack and COSMIC population synthesis codes, we investigate how different supernova mechanisms affect the observable population of SL systems, with particular attention to the mass gap (2–5 M⊙) in compact object distributions. We test three supernova remnant formation models with different convective growth timescales (fmix = 0.5, 1.0, and 4.0), simulating SL binary systems across the Galactic disk and bulge. We identify distinct groupings of SL sources based on lens mass and Einstein crossing time, clearly differentiating neutron star from black hole systems and close from wide orbits. Notably, the delayed fmix = 0.5 model predicts a significantly higher fraction of systems with lens masses in the mass gap region (up to about ten times more for certain surveys), suggesting that SL observations could help constrain this controversial population. Our analysis reveals a strong preference for systems with low centre-of-mass velocities (vcm ≤ 20 km/s) across all models, resulting primarily from physical processes governing compact object formation and binary survival. While many potential detections will have limited observational coverage, ZTF is predicted to yield several dozen well-covered systems that should enable detailed characterization. When applying simple detection criteria, including photometric precision and signal-to-noise requirements, predicted rates decrease by approximately two orders of magnitude but still yield up to a few tens of expected detections for LSST and ZTF in the Galactic disk population.
astro-ph.GA, astro-ph.HE
Wiktorowicz, Grzegorz
f2277210-4d99-4441-aa25-c5d324dfda2b
Middleton, Matthew
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Olejak, Aleksandra
9e754f50-0842-4e47-be6a-6ac74ce55c22
Dashwood-Brown, Cordelia
6460ccb2-d1b7-4d5b-92db-ca2270a4f377
Ward, Madeleine-Mai
1f668011-f593-4659-b2aa-f382e6fe4d5f
Ingram, Adam
277c7f8e-a271-42b9-99e7-98196d639c1a
February 2026
Wiktorowicz, Grzegorz
f2277210-4d99-4441-aa25-c5d324dfda2b
Middleton, Matthew
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Olejak, Aleksandra
9e754f50-0842-4e47-be6a-6ac74ce55c22
Dashwood-Brown, Cordelia
6460ccb2-d1b7-4d5b-92db-ca2270a4f377
Ward, Madeleine-Mai
1f668011-f593-4659-b2aa-f382e6fe4d5f
Ingram, Adam
277c7f8e-a271-42b9-99e7-98196d639c1a
Wiktorowicz, Grzegorz, Middleton, Matthew, Olejak, Aleksandra, Dashwood-Brown, Cordelia, Ward, Madeleine-Mai and Ingram, Adam
(2026)
Self-lensing binaries as probes of Supernova physics.
Astronomy & Astrophysics, 706, [A232].
(doi:10.1051/0004-6361/202557456).
Abstract
Self-lensing (SL) in binary systems has the potential to provide a unique observational window into the Galactic population of compact objects. Using the startrack and COSMIC population synthesis codes, we investigate how different supernova mechanisms affect the observable population of SL systems, with particular attention to the mass gap (2–5 M⊙) in compact object distributions. We test three supernova remnant formation models with different convective growth timescales (fmix = 0.5, 1.0, and 4.0), simulating SL binary systems across the Galactic disk and bulge. We identify distinct groupings of SL sources based on lens mass and Einstein crossing time, clearly differentiating neutron star from black hole systems and close from wide orbits. Notably, the delayed fmix = 0.5 model predicts a significantly higher fraction of systems with lens masses in the mass gap region (up to about ten times more for certain surveys), suggesting that SL observations could help constrain this controversial population. Our analysis reveals a strong preference for systems with low centre-of-mass velocities (vcm ≤ 20 km/s) across all models, resulting primarily from physical processes governing compact object formation and binary survival. While many potential detections will have limited observational coverage, ZTF is predicted to yield several dozen well-covered systems that should enable detailed characterization. When applying simple detection criteria, including photometric precision and signal-to-noise requirements, predicted rates decrease by approximately two orders of magnitude but still yield up to a few tens of expected detections for LSST and ZTF in the Galactic disk population.
Text
2509.11726v1
- Author's Original
Text
aa57456-25
- Version of Record
More information
Accepted/In Press date: 3 December 2025
e-pub ahead of print date: 12 February 2026
Published date: February 2026
Additional Information:
19 pages, 14 figures, submitted to MNRAS
Keywords:
astro-ph.GA, astro-ph.HE
Identifiers
Local EPrints ID: 511803
URI: http://eprints.soton.ac.uk/id/eprint/511803
ISSN: 0004-6361
PURE UUID: 4277a9e5-827d-4365-8c45-abc4546a6aa9
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Date deposited: 03 Jun 2026 16:35
Last modified: 04 Jun 2026 02:05
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Contributors
Author:
Grzegorz Wiktorowicz
Author:
Aleksandra Olejak
Author:
Cordelia Dashwood-Brown
Author:
Madeleine-Mai Ward
Author:
Adam Ingram
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