What question did this study set out to answer?

The study aims to reassess the metallicity of LFBOT host galaxies and propose a compact object + Wolf-Rayet star merger progenitor model.

June 8, 2026Open Access

Paper CLXII: One-Octonion Luminous Fast Blue Optical Transients as Merging Dual Hyperbolic Infundibula: The Compact Object + Wolf-Rayet Binary as a G₂

Key Points

The study aims to reassess the metallicity of LFBOT host galaxies and propose a compact object + Wolf-Rayet star merger progenitor model.
Uniform analysis of luminous fast blue optical transients (LFBOT) and their host galaxy properties.
Utilization of the One-Octonion Brane-Bulk Framework to reassess metallicity and progenitor models.
Analysis of oxygen abundance and enrichment mechanisms in LFBOT environments.
Host galaxies exhibit solar metallicity with median oxygen abundance of 8.71, indicating mislabeling as 'metal-poor'.
Anomalously low O/Fe ratio predicted in LFBOT ejecta due to isobaric Co→Ni channel enrichment.
Predictions of optical-to-X-ray luminosity ratio of 8/6 based on permutohedron face geometry.

Abstract

Nugent et al. (2026, arXiv: 2603. 23597) present the largest uniform analysis of Luminous Fast Blue Optical Transient (LFBOT) host galaxies to date, concluding that hosts are "metal-poor" and proposing a compact object + Wolf-Rayet (WR) star merger progenitor. We argue, using the One-Octonion Brane-Bulk Framework, that (1) the host metallicity is not sub-solar but rather solar: the median Nugent et al. oxygen abundance 12+log (O/H) = 8. 71 is 0. 02 dex above the solar value of 8. 69, and the apparent 'metal-poor' label arises from comparison to SN Ibc/II occurring in metal-enriched inner spirals; (2) the standard O/H metallicity proxy underestimates total metallicity because the isobaric Co→Ni channel (Paper CLIX, Jagadeesan 2026) enriches LFBOT environments in Fe-group elements by 10–20% beyond model predictions, producing a low O/Fe ratio at solar total metallicity; and (3) the compact object + WR star binary is precisely the dual hyperbolic infundibula system established in Paper CXLVIII (Cygnus X-1), scaled to LFBOT parameters. Both bodies have κ=−1 zones (rₐ0 ≈ 8, 000–33, 000 AU) vastly exceeding the binary orbital separation (≤0. 1 AU), so the entire system is embedded in the dual κ=−1 regime throughout its lifetime. The LFBOT event itself is the coalescence of two overlapping G₂ permutohedra, with the H sector ⁺ (8 hexagonal faces) producing the fast blue optical emission and the H sector (6 square faces) producing ⁻ the X-ray/jet component. Three predictions follow: the O/Fe ratio in LFBOT ejecta is anomalously low (same isobaric channel as Paper CLIX) ; the optical-to-X-ray luminosity ratio is 8/6 (from G₂ ∼ permutohedron face geometry, qualitative) ; and LFBOTs should occur at solar total metallicity independent of gas-phase O/H. Part of the One-Octonion Brane-Bulk Framework series. Anchor DOI: 10. 5281/zenodo. 19120873. Community: one-octonion-brane-bulk. Author: Bharathi Dasan Jagadeesan, M. D. , University of Minnesota. ORCID: 0000-0002-1143-941X.

Paper CLXII: One-Octonion Luminous Fast Blue Optical Transients as Merging Dual Hyperbolic Infundibula: The Compact Object + Wolf-Rayet Binary as a G₂

Key Points

Abstract

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