Cage decay, near constant loss, and crossover to cooperative ion motion in ionic conductors: insight from experimental data

Experimental frequency-dependent conductivity relaxation spectra of a number of molten, glassy, and crystalline ionic conductors that show both the presence of the near constant loss (NCL) and the cooperative ion hopping contribution are analyzed. On decreasing frequency, the NCL appears first but t...

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Bibliographic Details
Authors: Ngai, K. L., León Yebra, Carlos
Format: article
Publication Date:2002
Country:España
Institution:Universidad Complutense de Madrid (UCM)
Repository:Docta Complutense
Language:English
OAI Identifier:oai:docta.ucm.es:20.500.14352/59621
Online Access:https://hdl.handle.net/20.500.14352/59621
Access Level:Open access
Keyword:537
Glass transformation temperature
Complete conductivity spectra
Yttria-stabilized zirconia
Iodide-silver selenate
AC-conductivity
Neutron-scattering
Light-scattering
Sctructural relaxation
Electrical relaxation
Chalcogenide glasses.
Electricidad
Electrónica (Física)
2202.03 Electricidad
Description
Summary:Experimental frequency-dependent conductivity relaxation spectra of a number of molten, glassy, and crystalline ionic conductors that show both the presence of the near constant loss (NCL) and the cooperative ion hopping contribution are analyzed. On decreasing frequency, the NCL appears first but terminates at some frequency v_(x1). At still a lower frequency v_(x2) the cooperative ion hopping dispersion takes over. The independent ion hopping frequency v_(0) of the coupling model is calculated from the parameters characterizing the cooperative ion hopping dispersion. It is found for all ionic conductors that v_(x1)>>v_(0), and v_(0) always fall inside the frequency region v_(x1) > v > v_(x2). The empirical results leads to a qualitative theory for the origin of the NCL, which gives physical meanings of the two crossover frequencies v_(x1) and v_(x2), as well as explaining the role of the independent hopping frequency v_(0), in determining them. The weak temperature dependence of the NCL has been recaptured by the qualitative theory. An improved understanding is gained of the evolution of the ion dynamics from early times when the cages decay very slowly with time, giving rise to the near constant loss, to long times when ions move cooperatively, leading finally to dc conductivity.