Photoconductivity and laser operated piezoelectricity the Ag-Ga-Ge-(S,Se) crystals and solid solutions

El‐Naggar, A. M.; Albassam, A.A.; Myronchuk, G.L.; Zamuruyeva, O.V.; Kityk, I.V.; Rakus, P.; Parasyuk, O. V.; Jedryka, J.; Pavlyuk, Volodymyr; Piasecki, M.

doi:10.1016/j.mssp.2018.06.019

Cited by 6 publications

(5 citation statements)

References 34 publications

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“…For decades, chalcogenide glass has received considerable interest owing to its excellent infrared transmittance, low phonon energy, high nonlinear refractive index, and good glass‐forming ability . For all solid‐state battery application, electrolyte materials mainly forms two kinds of conduction mechanism including ions conduction and photoelectric conduction . As fast ion‐conducting materials, chalcogenide glasses have large anion ions and low electronegativity and are thus superior to oxide glasses.…”

Section: Introductionmentioning

confidence: 99%

“…7 For all solid-state battery application, electrolyte materials mainly forms two kinds of conduction mechanism including ions conduction and photoelectric conduction. 8,9 As fast ion-conducting materials, chalcogenide glasses have large anion ions and low electronegativity and are thus superior to oxide glasses. These features contribute to border ionic transport channel and exert minimal limited force on the conductive ions, thereby increasing ionic electrical conductivity.…”

Section: Introductionmentioning

confidence: 99%

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Effective ionic transport in AgI‐based Ge(Ga)–Sb–S chalcogenide glasses

Zhang

Jiao

et al. 2019

J Am Ceram Soc

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AgI‐based Ge–Sb–S, Ga–Sb–S, and Ge–Ga–Sb–S chalcogenide glasses were designed and prepared by melt‐quenching, thereafter their thermal properties and conductive performance were comparatively investigated on the basis of their composition‐induced network structures. Glass transition in each sample was examined by DSC measurements. Results showed that the samples containing Ge had a higher thermal stability than the Ga–Sb–S–AgI sample, and the Ge–Sb–S–AgI sample obtained had the highest conductivity ion. Raman spectrum analysis was performed, and the results indicated that the [GeS4‐xIx] structural units and [SbS3−xIx] pyramids in the matrix produced effective ion transport channel for dissolved conductive Ag+ ions. In the matrix containing Ga, the [Ga(Ge)S4‐xIx] structure was consumed by part of [S3Ga–GaS3] ethane‐like units, which had no contribution to the ion transition framework. The study provided the directions for composition and structure configuration control in effective conductive chalcogenide glasses.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effective ionic transport in AgI‐based Ge(Ga)–Sb–S chalcogenide glasses

Zhang

Jiao

et al. 2019

J Am Ceram Soc

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“…4b have been fitted well using Eqs. (6) and 7in two frequency domains respectively. This fitting provides the values of "s" and "r", which are presented in Table 1.…”

Section: Resultsmentioning

confidence: 99%

“…Chalcogenide glassy system is particularly important because of its considerable applications in the field of infrared spectroscopy, lower phonon energy, high value of non-linear refractive indices and excellent glass-forming ability [1][2][3][4]. Chalcogenide glassy system exhibits higher electrical conductivity than their oxide counterparts as the high polarizability of sulfur or selenium plays vital role in the conduction process [5][6][7]. Recent works [7] exhibit that higher electrical conductivity of silver doped glassy systems should be favourable to enhance lifetime of battery material.…”

Section: Introductionmentioning

confidence: 99%

Electrical transport of chalcogenide glassy system: interpretation by Hunt’s model and microstructure

Ojha

Roy

Chamuah³

et al. 2020

SN Appl. Sci.

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Ag 2 S doped Sulphur-Tellurium chalcogenide glassy system has been developed and their dielectric properties and electrical conductivity have been studied. Electrical conductivity via hopping of polarons in the present system is found to decrease due to large number of defects. TEM micrographs reveal the formation of Ag 2 S, Ag 2 Te and AgTe 3 nanophases, whose sizes are found to decrease with compositions. Almond-West formalism has been used to analyze the thermally activated nature of conductivity spectra. Hunt's model is used to reveal dielectric relaxation process with composition, which is justified by microstructure, revealed from TEM micrographs. Peak frequency (ω m) corresponding to imaginary modulus spectra shows Arrhenius relation. The results may reveal the opening for the development, significance and investigation of electrical and dielectric properties of chalcogenide glassy system.

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“…It is worth mentioning that the crystal structure of AgGaGeS 4 –AgGaGe 3 Se 8 possesses the particular optoelectronic characteristics, showing great promise for optoelectronic applications. For instance, Naggar et al [ 155 ] designed a novel and different laser-powered optoelectronic device based on a chalcogenide semiconductor. The optoelectronic features of the high-temperature piezoelectric materials originated from their intrinsic defects and the electron-phonon anharmonicities within their crystal lattice.…”

Section: Applications Of Piezoelectric Nanomaterials At High Temperaturementioning

confidence: 99%

Piezoelectric Materials: Properties, Advancements, and Design Strategies for High-Temperature Applications

2022

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Piezoelectronics, as an efficient approach for energy conversion and sensing, have a far-reaching influence on energy harvesting, precise instruments, sensing, health monitoring and so on. A majority of the previous works on piezoelectronics concentrated on the materials that are applied at close to room temperatures. However, there is inadequate research on the materials for high-temperature piezoelectric applications, yet they also have important applications in the critical equipment of aeroengines and nuclear reactors in harsh and high-temperature conditions. In this review, we briefly introduce fundamental knowledge about the piezoelectric effect, and emphatically elucidate high-temperature piezoelectrics, involving: the typical piezoelectric materials operated in high temperatures, and the applications, limiting factors, prospects and challenges of piezoelectricity at high temperatures.

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Photoconductivity and laser operated piezoelectricity the Ag-Ga-Ge-(S,Se) crystals and solid solutions

Cited by 6 publications

References 34 publications

Effective ionic transport in AgI‐based Ge(Ga)–Sb–S chalcogenide glasses

Effective ionic transport in AgI‐based Ge(Ga)–Sb–S chalcogenide glasses

Electrical transport of chalcogenide glassy system: interpretation by Hunt’s model and microstructure

Piezoelectric Materials: Properties, Advancements, and Design Strategies for High-Temperature Applications

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