Robin nullity and asymptotic geometry of the critical hyperbolic catenoid

Abstract

For each parameter a>1, the critical hyperbolic catenoid a is a rotationally symmetric, free boundary minimal annulus in a geodesic ball B3(r(a))⊂H3. The Morse index of a is at least 4 by Medvedev [7], who conjectures equality. In this paper we identify a new geometric and spectral phenomenon for the family \a\a>1, which we call "parameter-criticality", and study its consequences for the Robin spectrum. Specifically, we prove two main results: (I) Parameter-criticality (Theorem 1.5). The boundary radius r(a) is non-monotone on (1,∞): it satisfies r'(1+)<0 and r(a)=32 a+d∞+o(1) as a∞ with d∞=[(1/4)/(3/4)]-12(2π) (Theorem 1.4). Hence there exists a parameter-critical value a∈(1,∞) with r'(a)=0. (II) Robin nullity jump (Theorem 1.6). At every such a, the Robin nullity of a satisfies nul(L_a)≥ 3, with an additional kernel element in mode k=0 generated by the parametric variation field ja=∂aa,L|a=a, which we show is non-vanishing at the catenoid neck via the closed-form ja(0)=1/(2a2-1). The argument requires the limit r0:=a 1+r(a) characterized as the unique positive solution of the transcendental equation (r0)\,(2r0/3)=3/2 (Theorem 1.3), giving a clean parametrization of the degeneration a1. The Robin nullity of a in mode |k|=1 is shown to equal 2 (Proposition 1.1); this extends to the hyperbolic setting the mode-by-mode Fourier decomposition technique of Devyver [2] for the Euclidean critical catenoid, and is used in the proof of (II) to identify the extra kernel as a mode-k=0 phenomenon.