SN 2023gpw: Exploring the diversity and power sources of hydrogen-rich superluminous supernovae

Kangas, T; Charalampopoulos, P; Nagao, T; Yan, L; Stritzinger, M; Schulze, S; Das, K; Elias-Rosa, N; Fremling, C; Perley, D; Sollerman, J; Müller-Bravo, TE; Galbany, L; Groom, SL; Gutiérrez, CP; Kasliwal, M; Kotak, R; Laher, R; Lundqvist, P; Mattila, S; Smith, R

SN 2023gpw: Exploring the diversity and power sources of hydrogen-rich superluminous supernovae

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Kangas, T, Charalampopoulos, P, Nagao, T, Yan, L, Stritzinger, M, Schulze, S, Das, K, Elias-Rosa, N, Fremling, C, Perley, D ORCID: 0000-0001-8472-1996, Sollerman, J, Müller-Bravo, TE, Galbany, L, Groom, SL, Gutiérrez, CP, Kasliwal, M, Kotak, R, Laher, R, Lundqvist, P, Mattila, S et al (2025) SN 2023gpw: Exploring the diversity and power sources of hydrogen-rich superluminous supernovae. Astronomy & Astrophysics. ISSN 0004-6361

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Publisher URL: https://doi.org/10.1051/0004-6361/202555588

Abstract

We present our observations and analysis of SN 2023gpw, a hydrogen-rich superluminous supernova (SLSN II) with broad emission lines in its post-peak spectra. Unlike previously observed SLSNe II, its light curve suggests an abrupt drop during a solar conjunction between ∼80 and ∼180 d after the light curve peak, which is possibly analogous to a normal hydrogen-rich supernova (SN). Spectra taken at and before the peak show hydrogen and helium ``flash" emission lines attributed to early interaction with a dense confined circumstellar medium (CSM). A well-observed ultraviolet excess appears as these lines disappear, also as a result of CSM interaction. The blackbody photosphere expands roughly at the same velocity throughout the observations, indicating little or no bulk deceleration. This velocity is much higher than what is seen in spectral lines, suggesting asymmetry in the ejecta. The high total radiated energy (≳9 erg) and aforementioned lack of bulk deceleration in SN 2023gpw are difficult to reconcile with a neutrino-driven SN simply combined with efficient conversion from kinetic energy to emission through interaction. This suggests an additional energy source, such as a central engine. While magnetar-powered models qualitatively similar to SN 2023gpw exist, more modeling work is required to determine if they can reproduce the observed properties in combination with early interaction. The required energy might alternatively be provided by accretion onto a black hole created in the collapse of a massive progenitor star.

Item Type:	Article
Uncontrolled Keywords:	5101 Astronomical Sciences; 51 Physical Sciences; 7 Affordable and Clean Energy; 0201 Astronomical and Space Sciences; Astronomy & Astrophysics; 5101 Astronomical sciences; 5107 Particle and high energy physics; 5109 Space sciences
Subjects:	Q Science > QB Astronomy Q Science > QC Physics
Divisions:	Astrophysics Research Institute
Publisher:	EDP Sciences
Date of acceptance:	14 September 2025
Date of first compliant Open Access:	6 November 2025
Date Deposited:	06 Nov 2025 15:03
Last Modified:	06 Nov 2025 16:15
DOI or ID number:	10.1051/0004-6361/202555588
URI:	https://researchonline.ljmu.ac.uk/id/eprint/27509

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