Bottom of the Spectrum of Complete Kähler Metrics from Finite-Mass Plurisubharmonic Exhaustions

Abstract

Let Ω⊂Cn be a bounded domain, and let ρ:Ω[-1,0) be a smooth strictly plurisubharmonic exhaustion function. We consider the logarithmic potential g=-(-ρ) and the associated complete Kähler metric ω=ddcg. We prove that if ρ satisfies the finite weighted Monge--Ampère mass condition ∫Ω(-ρ)(ddcρ)n<+∞ for every >0, then the bottom of the spectrum of the Laplace--Beltrami operator of (Ω,ω) satisfies λ0(Δω,Ω)=n2. The lower bound follows from the standard estimate applied to g, together with the inequality |∂ g|ω2 1. For the reverse inequality, for each α>n/2, we set f=(-ρ)α and prove that f∈ W1,2(Ω,ω) if and only if ∫Ω(-ρ)2α-n(ddcρ)n<+∞. Under the finite weighted Monge--Ampère mass condition, this allows us to let α n/2 in the Rayleigh quotient and obtain the upper bound λ0(Δω,Ω) n2. As an application, Cegrell's theorem gives a smooth strictly plurisubharmonic exhaustion with finite Monge--Ampère mass on every bounded hyperconvex domain; the associated complete Kähler metric constructed from this exhaustion therefore satisfies λ0(Δω,Ω)=n2.

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