An Analytic Threshold for LESA-Driven Negative ELN Flux Directions in Core-Collapse Supernovae: Derivation and Population Census

Abstract

In core-collapse supernovae (CCSNe), deleptonization normally favors e over e emission. However, lepton-number emission self-sustained asymmetry (LESA) can make the energy-integrated emitted lepton-number flux negative along some directions. We derive a simple diagnostic for this transition and test it in 33 independent 3D CCSN simulations: 25 Princeton/Fornax models (8.1--100\,M) and 8 Garching models, including non-, slow-, and fast-rotating 15\,M cases. Of 23 non-black-hole-forming Princeton models, 22 cross the threshold, with median onset tc=225\,ms, IQR 162--264\,ms, and cross-model scatter CV=18.6\%. Full-sky flux-sign searches show that the threshold identifies the anti-LESA-pole transition, distinguishing the global LESA-driven crossing from early localized turbulent crossings. The fast-rotating Garching 15\,M model, where rapid rotation suppresses the LESA dipole, is correctly classified as a non-crosser without using any rotation parameter. Both black-hole-forming Princeton models cross near 250\,ms post-bounce and remain above threshold for 1807 and 2463\,ms before collapse. Thus, in the next nearby CCSN, the emitted e energy flux may exceed the e flux along some lines of sight. Such directions may also correlate with sustained fast flavor instability, although testing this requires local phase-space distributions or dedicated linear stability analysis. The relevant quantity here is the energy-integrated emitted flux field, i.e. a luminosity difference per steradian, not a neutrino number flux.