Non-negative Wigner-like distributions and Renyi-Wigner entropies of arbitrary non-Gaussian quantum states: The thermal state of the one-dimensional box problem

Abstract

In this work, we consider the phase-space picture of quantum mechanics. We then introduce non-negative Wigner-like (operational) distributions Wrho;alpha(x,p) corresponding to the density operator rho and being proportional to Wrho(alpha/2)(x,p)2, where Wrho(x,p) denotes the usual Wigner function. In doing so, we utilize the formal symmetry between the purity measure Tr(rho2) and its Wigner representation (2 pi hbar) ∫ dx dp Wrho(x,p)2 and then consider, as a generalization, such symmetry between the fractional moment Tr(rhoalpha) and its Wigner representation (2 pi hbar) ∫ dx dp Wrhoalpha/2(x,p)2. Next, we create a framework that enables explicit evaluation of the Renyi-Wigner entropies for the classical-like distributions Wrho;alpha(x,p). Consequently, a better understanding of some non-Gaussian features of a given state rho will be given, by comparison with the Gaussian state rhoG defined in terms of its Wigner function WrhoG(x,p) and essentially determined by its purity measure T(rhoG)2 alone. To illustrate the validity of our framework, we evaluate the distributions Wbeta;alpha(x,p) corresponding to the (non-Gaussian) thermal state rhoβ of a single particle confined by a one-dimensional infinite potential well with either the Dirichlet or Neumann boundary condition and then analyze the resulting Renyi entropies. Our phase-space approach will also contribute to a deeper understanding of non-Gaussian states and their properties either in the semiclassical limit (hbar 0) or in the high-temperature limit (beta 0), as well as enabling us to systematically discuss the quantal-classical Second Law of Thermodynamics on the single footing.