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Impedance response and I–V characteristics of Bi6(As2S3)94 and Bi7(As2S3)93 at elevated temperature

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We report on the dynamics of the softening process of Bi6(As2S3)94 through studying the AC impedance response in the frequency interval of 1 Hz to 10 MHz at operating temperatures… Click to show full abstract

We report on the dynamics of the softening process of Bi6(As2S3)94 through studying the AC impedance response in the frequency interval of 1 Hz to 10 MHz at operating temperatures of 323–373 K. The increase of glass fictive temperature with heating rate, observed in DSC curves, is explained using the Lasocka equation. The analysis of impedance spectra indicated single-phase glass behavior for Bi6(As2S3)94, whereas the appearance of internal interfaces was confirmed for Bi7(As2S3)93 at all temperatures. While this was previously assigned to the boundary surface of the matrix–interface region and the crystalline centers themselves, the extension of the observed range now revealed that at low temperatures, amorphous phase separation without crystal precipitation comes into play. By analyzing the impedance data, we determined refined DC resistance and relaxation time values, and also confirmed the decrease of resistance with temperature for both compositions. Similar activation barriers for α relaxation and charge carrier mobility indicate that both processes are strongly coupled. The I–V characteristics of the Bi7(As2S3)93 sample recorded up to T = 373 K show bipolar resistive switching behavior controlled by voltage. At higher temperatures, there is switching with conducting filament due to the contribution of crystalline centers.

Keywords: temperature; bi6 as2s3; impedance response; impedance; bi7 as2s3

Journal Title: Journal of Materials Science: Materials in Electronics
Year Published: 2020

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