Abstract
Starting from a quantized version of the classical Hamiltonian H = x p , we add a non-local interaction which depends on two potentials. The model is solved exactly in terms of a Jost like function which is analytic in the complex upper half plane. This function vanishes, either on the real axis, corresponding to bound states, or below it, corresponding to resonances. We find potentials for which the resonances converge asymptotically toward the average position of the Riemann zeros. These potentials realize, at the quantum level, the semiclassical regularization of H = x p proposed by Berry and Keating. Furthermore, a linear superposition of them, obtained by the action of integer dilations, yields a Jost function whose real part vanishes at the Riemann zeros and whose imaginary part resembles the one of the zeta function. Our results suggest the existence of a quantum mechanical model where the Riemann zeros would make a point like spectrum embedded in the continuum. The associated spectral interpretation would resolve the emission/absorption debate between Berry–Keating and Connes. Finally, we indicate how our results can be extended to the Dirichlet L-functions constructed with real characters.
Highlights
The Riemann hypothesis is considered the most important problem in Analytic Number Theory[1,2,3,4,5]
In reference[20] we proposed a quantization of H = xp using an unexpected connection of this model to the onebody version of the so called Russian doll BCS model of superconductivity[21,22,23]
In this paper we have proposed a possible realization of the Hilbert-Polya conjecture in terms of a Hamiltonian given by a perturbation of H = xp, or rather its inverse
Summary
The Riemann hypothesis is considered the most important problem in Analytic Number Theory[1,2,3,4,5]. The step in this direction was put forward by Berry who proposed the Quantum Chaos conjecture, according to which the Riemann zeros are the spectrum of a Hamiltonian obtained by quantization of a classical chaotic Hamiltonian, whose periodic orbits are labelled by the prime numbers[12] This suggestion was based on analogies between fluctuation formulae in Number Theory and Quantum Chaos[13]. The cyclic Renormalization Group, and its realization in the field theory models of references[29,30,31], is at the origin of LeClair’s approach to the RH32 In this reference the zeta function on the critical strip is related to the quantum statistical mechanics of non-relativistic, interacting fermionic gases in 1d with a quasi-periodic twobody potential.
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