Geometric structure of singular free boundary points for the logarithmic obstacle problem

Abstract

In the previous work [Interfaces Free Bound., 19, 351--369, 2017], de Queiroz and Shahgholian established the optimal C1,loc regularity of solutions for the obstacle problem with singular logarithmic forcing term - u = u\,\u>0\ in , where ⊂Rd (d≥ 2) is a smooth bounded domain. In our earlier work [arXiv:2408.08104, 2024], we proved the C1,α regularity of the free boundary ∂\u>0\ near regular points. In this paper, we investigate the more delicate structure of the singular free boundary. Since the nonlinearity - u is singular near the free boundary and destroys the scaling invariance, so that neither the classical blow-up arguments nor the standard epiperimetric inequality [Weiss, Invent.\ Math., 138, 23--50, 1999] apply directly; moreover, the Weiss type monotonicity formula requires a variable-parameter correction that introduces non-integrable remainder terms into the energy estimates. Motivated by Colombo--Spolaor--Velichkov [Geom.\ Funct.\ Anal., 28, 1029--1061, 2018], we develop a new log-epiperimetric inequality for the modified Weiss energy, also proved by the direct method. A key novelty is the introduction of an auxiliary correction term T that absorbs the non-integrable errors. As consequences, we establish a logarithmic energy decay, uniqueness of blow-ups at singular points, and a C1,-type geometric description of the singular strata. In dimension two, the logarithmic modulus improves to a H\"older modulus.