On the Ground State Energies of Discrete and Semiclassical Schr\"odinger Operators
Abstract
We study the infimum of the spectrum, or ground state energy (g.s.e.), of a discrete Schr\"odinger operator on θZd parameterized by a potential V:Rd→R 0 and a frequency parameter θ∈ (0,1). We relate this g.s.e. to that of a corresponding continuous semiclassical Schr\"odinger operator on Rd with parameter θ, arising from the same choice of potential. We show that: the discrete g.s.e. is at most the continuous one for continuous periodic V and irrational θ; the opposite inequality holds up to a factor of 1-o(1) as θ→ 0 for sufficiently regular smooth periodic V; and the opposite inequality holds up to a constant factor for every bounded V and θ with the property that discrete and continuous averages of V on fundamental domains of θ Zd are comparable. Our proofs are elementary and rely on sampling and interpolation to map low-energy functions for the discrete operator on θ Zd to low-energy functions for the continuous operator on Rd, and vice versa.
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