Isomorph theory prediction for the dielectric loss variation along an isochrone

This paper derives a prediction for the variation of the amplitude of the dielectric loss from isomorph theory, and presents an experimental test of the prediction performed by measuring the dielectric relaxation behavior of the van der Waals liquid 5-phenyl-4-ether (5PPE). The liquid is studied at...

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Bibliographic Details
Published inJournal of non-crystalline solids Vol. 407; pp. 190 - 195
Main Authors Xiao, Wence, Tofteskov, Jon, Christensen, Troels V., Dyre, Jeppe C., Niss, Kristine
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.01.2015
Subjects
Amplitudes
Capacitance
Capacitors
Constants
Density
Dielectric loss
Dielectric loss measurement
Elevated pressure
Equivalence
Isomorph theory
Liquids
Supercooled liquid
Dielectric loss measurement
Supercooled liquid
Elevated pressure
Isomorph theory
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Summary:This paper derives a prediction for the variation of the amplitude of the dielectric loss from isomorph theory, and presents an experimental test of the prediction performed by measuring the dielectric relaxation behavior of the van der Waals liquid 5-phenyl-4-ether (5PPE). The liquid is studied at isochronal states in the temperature range 266–333K and pressure range 0.1−300MPa, for relaxation times around 10−3s and 10−4s. From the isomorph statement that there is structural and dynamic invariance of isomorph states in reduced units for Roskilde simple liquids we derive four equivalent isomorph-invariant terms, one of which is used in analyzing our data. It is the frequency-dependent term χe(f)ργ−1, with electric susceptibility χe, density ρ, and density-scaling factor γ. Due to the unique design of our experimental setup, we obtain dielectric loss data where the amplitude is reproducible ±0.1%. We moreover find that the empty capacitance of the capacitor cell is stable within ±0.3% in our measuring range and can be assumed to be constant. Using this we predict for two isomorph states there is C2″(f)=C1″(f)(ρ1/ρ2)γ−1 to scale the imaginary capacitance, where C1 is the capacitance measurement at ambient pressure and C2 is the predicted capacitance at elevated pressure. We visually compare the predicted and measured plots and there is a good match between the two plots among the 42 pairs of isochronal states from the measurement. •Isomorph prediction for dielectric loss scaling•The density dependence of the dielectric loss strength at isochronal states•Experimental support of isomorph theory
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ISSN:0022-3093
1873-4812
DOI:10.1016/j.jnoncrysol.2014.08.041