A convexity-type invariant for the critical coagulation--fragmentation Hamilton--Jacobi equation

Abstract

We study the critical coagulation--fragmentation equation with multiplicative coagulation kernel a(s, s)=s s and constant fragmentation kernel b(s, s)=1. Under the Bernstein transform, mass-conserving solutions correspond to solutions of a singular Hamilton--Jacobi equation studied by Tran and Van (Comm. Pure Appl. Math. 75 (2022), no. 6, 1292--1331). Through this correspondence they proved that mass-conserving solutions are unique on the full critical range 0<m1, but could establish their existence only for 0<m<12. We identify a one-sided, convexity-type invariant that holds for Bernstein-transform data and is propagated by their viscous scheme as a genuine maximum-principle bound. We call it the half-slope invariant. It sharpens the curvature barrier and thereby extends mass-conserving existence to the entire critical range 0<m1. Hence m=1 is the critical mass, confirming the threshold predicted by Vigil and Ziff (J. Colloid Interface Sci. 133 (1989), no. 1, 257--264). The same invariant appears in the radial partial-mass formulation of the two-dimensional Keller--Segel equation, whose critical mass is 8π.

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