On the Density of Complex Eigenvalues of Wigner Reaction Matrix in a Disordered or Chaotic System with Absorption

Y. V. Fyodorov

doi:10.12693/APhysPolA.144.447

On the Density of Complex Eigenvalues of Wigner Reaction Matrix in a Disordered or Chaotic System with Absorption

Y. V. Fyodorov^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

In an absorptive system, the Wigner reaction K-matrix (directly related to the impedance matrix in acoustic or electromagnetic wave scattering) is non-selfadjoint, hence its eigenvalues are complex. The most interesting regime arises when the absorption, taken into account as an imaginary part of the spectral parameter, is of the order of the mean level spacing. I will show how to derive the mean density of the complex K-matrix eigenvalues for the M-channel reflection problem in disordered or chaotic systems with broken time-reversal invariance. The computations have been done in the framework of the nonlinear σ-model approach, assuming fixed M and the dimension of the underlying Hamiltonian matrix N → ∞. Some explicit formulas are provided for zero-dimensional quantum chaotic system as well as for a semi-infinite quasi-1D system with fully operative Anderson localization.

Original language	English
Pages (from-to)	447-455
Number of pages	9
Journal	Acta Physica Polonica A
Volume	144
Issue number	6
DOIs	https://doi.org/10.12693/APhysPolA.144.447
Publication status	Published - Dec 2023

Keywords

non-Hermitian matrices
quantum chaotic scattering
random matrix theory

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10.12693/APhysPolA.144.447

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abstract = "In an absorptive system, the Wigner reaction K-matrix (directly related to the impedance matrix in acoustic or electromagnetic wave scattering) is non-selfadjoint, hence its eigenvalues are complex. The most interesting regime arises when the absorption, taken into account as an imaginary part of the spectral parameter, is of the order of the mean level spacing. I will show how to derive the mean density of the complex K-matrix eigenvalues for the M-channel reflection problem in disordered or chaotic systems with broken time-reversal invariance. The computations have been done in the framework of the nonlinear σ-model approach, assuming fixed M and the dimension of the underlying Hamiltonian matrix N → ∞. Some explicit formulas are provided for zero-dimensional quantum chaotic system as well as for a semi-infinite quasi-1D system with fully operative Anderson localization.",

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T1 - On the Density of Complex Eigenvalues of Wigner Reaction Matrix in a Disordered or Chaotic System with Absorption

AU - Fyodorov, Y. V.

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N2 - In an absorptive system, the Wigner reaction K-matrix (directly related to the impedance matrix in acoustic or electromagnetic wave scattering) is non-selfadjoint, hence its eigenvalues are complex. The most interesting regime arises when the absorption, taken into account as an imaginary part of the spectral parameter, is of the order of the mean level spacing. I will show how to derive the mean density of the complex K-matrix eigenvalues for the M-channel reflection problem in disordered or chaotic systems with broken time-reversal invariance. The computations have been done in the framework of the nonlinear σ-model approach, assuming fixed M and the dimension of the underlying Hamiltonian matrix N → ∞. Some explicit formulas are provided for zero-dimensional quantum chaotic system as well as for a semi-infinite quasi-1D system with fully operative Anderson localization.

AB - In an absorptive system, the Wigner reaction K-matrix (directly related to the impedance matrix in acoustic or electromagnetic wave scattering) is non-selfadjoint, hence its eigenvalues are complex. The most interesting regime arises when the absorption, taken into account as an imaginary part of the spectral parameter, is of the order of the mean level spacing. I will show how to derive the mean density of the complex K-matrix eigenvalues for the M-channel reflection problem in disordered or chaotic systems with broken time-reversal invariance. The computations have been done in the framework of the nonlinear σ-model approach, assuming fixed M and the dimension of the underlying Hamiltonian matrix N → ∞. Some explicit formulas are provided for zero-dimensional quantum chaotic system as well as for a semi-infinite quasi-1D system with fully operative Anderson localization.

KW - non-Hermitian matrices

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KW - random matrix theory

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On the Density of Complex Eigenvalues of Wigner Reaction Matrix in a Disordered or Chaotic System with Absorption

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