Stable Semilinear Elliptic Equations: -Regularity à la Brezis and Dimensional Bounds for the Singular Set

Abstract

We develop a quantitative partial regularity theory for stable solutions of \[ -Δu=f(u), \] where f: R [0,+∞] is increasing and convex. The theory is uniform in the nonlinearity and allows for a finite or infinite blow-up level Tf∈(-∞,+∞]. Our first result is a universal -regularity criterion that answers a celebrated question of Brezis: smallness of the scale-invariant mass of the stability potential f'(u) forces Hölder regularity. Moreover, if Tf<+∞, the same smallness condition forces almost quadratic contact between the solution and the blow-up level Tf. This result is optimal and, in particular, covers the case of MEMS-type nonlinearities. Our second result identifies a critical exponent qf1, given explicitly in terms of the asymptotic behavior of f, f', and f'', such that \[ f'(u)∈ Lqloc for every q<qf . \] Combined with our -regularity theorem, this yields quantitative bounds for the singular set, in particular \[ HΣ(u) n-2qf. \] Remarkably, our exponent qf recovers the sharp thresholds for all standard model nonlinearities, including f(t)=(1+t)p, et, and (1-t)-p. Also, this result provides the first general quantitative singular-set estimates for stable semilinear equations beyond the model nonlinearities. Finally, in the two-dimensional case, we provide a complete picture by proving the universal Hessian estimate \[ \|D2u\|L∞(B1/2) C\|u\|L1(B1), \] where C depends neither on u nor on f. This C1,1 regularity is essentially optimal: one cannot expect C2,α estimates for any α>0, and in general even C2 regularity should fail.