Nonhomogeneity of the density of states of tunneling two-level systems at low energies

A. Churkin; D. Barash; M. Schechter

doi:https://doi.org/10.1103/PhysRevB.89.104202

Nonhomogeneity of the density of states of tunneling two-level systems at low energies

A. Churkin, D. Barash, M. Schechter

Ben-Gurion University of the Negev

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

Abstract

Amorphous solids, and many disordered lattices, exhibit a remarkable qualitative and quantitative universality in their acoustic properties at temperature â‰3 K. This phenomenon is attributed to the existence of tunneling two-level systems (TTLSs), characterized by a homogeneous density of states (DOS) at energies much lower than the disorder energy (≈0.1 eV). Here we calculate numerically, from first principles, the DOS of KBr:CN glass, the archetypal disordered lattice showing universality. In contrast to the standard tunneling model, we find that the DOS diminishes abruptly at ≈3 K, and that tunneling states differ essentially by their symmetry under inversion. This structure of the TTLSs dictates the low temperature below which universality is observed, and the quantitative universality of the acoustic properties in glasses. Consequences to the properties of glasses at intermediate temperatures, as well as to the microscopic structure of amorphous solids, are discussed.

Original language	American English
Article number	104202
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	89
Issue number	10
DOIs	https://doi.org/10.1103/PhysRevB.89.104202
State	Published - 7 Mar 2014

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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https://doi.org/10.1103/PhysRevB.89.104202

Cite this

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title = "Nonhomogeneity of the density of states of tunneling two-level systems at low energies",

abstract = "Amorphous solids, and many disordered lattices, exhibit a remarkable qualitative and quantitative universality in their acoustic properties at temperature {\^a}‰3 K. This phenomenon is attributed to the existence of tunneling two-level systems (TTLSs), characterized by a homogeneous density of states (DOS) at energies much lower than the disorder energy (≈0.1 eV). Here we calculate numerically, from first principles, the DOS of KBr:CN glass, the archetypal disordered lattice showing universality. In contrast to the standard tunneling model, we find that the DOS diminishes abruptly at ≈3 K, and that tunneling states differ essentially by their symmetry under inversion. This structure of the TTLSs dictates the low temperature below which universality is observed, and the quantitative universality of the acoustic properties in glasses. Consequences to the properties of glasses at intermediate temperatures, as well as to the microscopic structure of amorphous solids, are discussed.",

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AU - Churkin, A.

AU - Barash, D.

AU - Schechter, M.

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N2 - Amorphous solids, and many disordered lattices, exhibit a remarkable qualitative and quantitative universality in their acoustic properties at temperature â‰3 K. This phenomenon is attributed to the existence of tunneling two-level systems (TTLSs), characterized by a homogeneous density of states (DOS) at energies much lower than the disorder energy (≈0.1 eV). Here we calculate numerically, from first principles, the DOS of KBr:CN glass, the archetypal disordered lattice showing universality. In contrast to the standard tunneling model, we find that the DOS diminishes abruptly at ≈3 K, and that tunneling states differ essentially by their symmetry under inversion. This structure of the TTLSs dictates the low temperature below which universality is observed, and the quantitative universality of the acoustic properties in glasses. Consequences to the properties of glasses at intermediate temperatures, as well as to the microscopic structure of amorphous solids, are discussed.

AB - Amorphous solids, and many disordered lattices, exhibit a remarkable qualitative and quantitative universality in their acoustic properties at temperature â‰3 K. This phenomenon is attributed to the existence of tunneling two-level systems (TTLSs), characterized by a homogeneous density of states (DOS) at energies much lower than the disorder energy (≈0.1 eV). Here we calculate numerically, from first principles, the DOS of KBr:CN glass, the archetypal disordered lattice showing universality. In contrast to the standard tunneling model, we find that the DOS diminishes abruptly at ≈3 K, and that tunneling states differ essentially by their symmetry under inversion. This structure of the TTLSs dictates the low temperature below which universality is observed, and the quantitative universality of the acoustic properties in glasses. Consequences to the properties of glasses at intermediate temperatures, as well as to the microscopic structure of amorphous solids, are discussed.

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Nonhomogeneity of the density of states of tunneling two-level systems at low energies

Abstract

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