W. John scite author profile

Correlation of a quantum many-body state makes the one-particle density matrix nonidempotent. Therefore, the Shannon entropy of the natural occupation numbers measures the correlation strength on the one-particle level. Here, it is shown how this general idea of a correlation entropy must be adapted for two-electron systems in view of conservation laws which mix Slater determinants even in the noninteracting limit. Results are presented for the correlation entropy s of H as a function of the 2 nucleus᎐nucleus separation R. In the ground state, the entropy of the spatial factor of the wave function maximizes 1.7 bohr beyond the Coulson᎐Fischer separation. The role of the correlation entropy in density functional theory is also discussed.

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Instanton approach to the conductivity of a disordered solid

Hayn

John

1991

Nuclear Physics B

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Statistical properties of resonances in quantum irregular scattering

et al. 1991

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The close relations between statistical properties of quantum dissipative systems and scattering systems is discussed. It is conjectured that for quantum chaotic scattering the distribution of the resonance poles of the S matrix is generic and follows the predictions of the Ginibre ensemble of random nonHermitian matrices. This phenomenon has been demonstrated on a simple example of a single particle scattered by eight randomly distributed point obstacles in three dimensions.PACS numbers: 05.45.+b, 03.65.Nk Irregular scattering is nowadays one of the most interesting questions in the field of quantum chaos. It has been demonstrated, for instance [1], that the existence of classical irregular scattering leads in the quantum case to an S matrix whose structure can be described by the Dyson ensemble of random matrices [2]. It is also known that the fluctuations of the quantum cross section resemble the so-called Ericson fluctuations (discovered for nuclear systems [3]). This indicates that many overlapping resonances contribute. Also, the universal fluctuations of the conductivity in mesoscopic samples has been recently interpreted in terms of chaotic scattering [4]. It is therefore natural to ask whether one can predict something about the universal features of the distribution of the corresponding resonance poles in the complex energy plane.It is intuitively clear that the resonance poles have much in common with the eigenvalues of a quantum dissipative system. From the physical point of view, the resonance can be considered as a two-step process. During the first step an unstable intermediate (virtual) state is excited which then decays (second step) and leads for an isolated resonance to a peak in the cross section. The correspondence with the theory of the dissipative systems becomes apparent as soon as one starts with the description of the virtual state.In order to describe the intermediate state in the scattering process, Livsic [5] introduced a dissipative operator (the so-called Livsic matrix [6]), the eigenvalues of which coincide with the position of the resonance poles.The resonances which can be obtained as the poles of the analytically continued Green's function are defined according to Livsic with the help of a "restricted" quantum dynamics. Let P be a projection on a finite-dimensional subspace of the state Hilbert space J4 and let H be the relevant quantum Hamiltonian on ft. The restricted Green's function is then defined as P(H-z)~]P.(1)The Livsic matrix Biz) represents the effective dissipative and energy-dependent Hamiltonian describing the quantum dynamics on the restricted state space: lB(z)-z)~]=P(H-z)-] P(the rest of the Hilbert space is understood as the "heat bath"). The resonances are then obtained by solving the effective eigenvalue equationThis approach is equivalent to the complex scaling method introduced later [7]. The Livsic method shows a close similarity with the treatment of the dissipative system [8]. It is therefore natural to conjecture that the statistical properties of the e...

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W. John

Two-site Hubbard model, the Bardeen-Cooper-Schrieffer model, and the concept of correlation entropy

Correlation entropy of the H2 molecule

Instanton approach to the conductivity of a disordered solid

Statistical properties of resonances in quantum irregular scattering

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