How silver influences the structure and physical properties of chalcogenide glass (GeS2)50(Sb2S3)50

Fraenkl, Max; Frumarová, Božena; Podzemná, Veronika; Šlang, Stanislav; Beneš, Ludvı́k; Vlček, M.; Wágner, T.

doi:10.1016/j.jnoncrysol.2018.07.046

Cited by 14 publications

(15 citation statements)

References 33 publications

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“…Thus, the 4-coordinated Ge unit connects through a Se atom to a 3-coordinated Sb unit and, therefore, the first neighbour distance of Ge-Sb is less realistic. In the literature, there are studies [29,[31][32][33], which support this suggestion. Considering the values of the weighting factors in Table 1, one can see that Ge-Sb bond's weighting factors ( ND,Ge-Sb =6.24% and XRD,Ge-Sb =8.49%) are lower than those for Ge-Se ( ND,Ge-Se =21.43% and XRD,Ge-Se =13.56%) and Sb-Se ( ND,Sb-Se =24.30% and XRD,Sb-Se =36.16%), which bonds have well known first neighbour distances.…”

Section: Reverse Monte Carlomentioning

confidence: 77%

Investigation of the Atomic Structure of Ge-Sb-Se Chalcogenide Glasses

Fábián

Dulgheru

Antonova

et al. 2018

Advances in Condensed Matter Physics

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at. %) have been synthesized. Neutron and X-ray diffraction techniques were used to study the atomic glassy structure, and Reverse Monte Carlo (RMC) simulations were applied to model the 3-dimensional atomic configurations and thorough mapping of the atomic parameters, such as first and second neighbour distances, coordination numbers, and bond-angle distributions. The results are explained with formation of GeSe 4 and SbSe 3 structural units, which correlate with the Ge/Sb ratio. For all the studied compositions, the Ge-Se, Sb-Se, Ge-Ge, and Se-Se bonds are significant. RMC simulations reveal the presence of Ge-Sb and Sb-Sb bonds, being dependent on Ge/Sb ratio. All atomic compositions satisfy formal valence requirements, i.e., Ge is fourfold coordinated, Sb is threefold coordinated, and Se is twofold coordinated. By increasing the Sb content, both the Se-Ge-Se bonds angle of 107±3 ∘ and Se-Sb-Se bonds angle of 118±3 ∘ decrease, respectively, indicating distortion of the structural units. Far infrared Fourier Transform spectroscopic measurements conducted in the range of 50-450 cm -1 at oblique (75 ∘ ) incidence radiation have revealed clear dependences of the IR band's shift and intensity on the glassy composition, showing features around x=27 at.% supporting the topological phase transition to a stable rigid network consisting mainly of SbSe 3 pyramidal and GeSe 4 tetrahedral clusters. These results are in agreement with the Reverse Monte Carlo models, which define the Ge and Sb environment.

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Section: Reverse Monte Carlomentioning

confidence: 77%

Investigation of the Atomic Structure of Ge-Sb-Se Chalcogenide Glasses

Fábián

Dulgheru

Antonova

et al. 2018

Advances in Condensed Matter Physics

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“…The as‐prepared powder sample after the deliquescence process for different times was subjected to Raman scattering measurement for a better understanding of the influence of humidity on the network. The Raman peaks were decomposed in a series of sub‐bands for further accurate analysis by Gaussian fitting method 24,25 . Figure 9A‐C indicate that, after three days of exposure, the entire Raman peak presented a declining trend in intensity.…”

Section: Resultsmentioning

confidence: 99%

Structure promoted electrochemical behavior and chemical stability of AgI‐doped solid electrolyte in sulfide glass system

Jiao

Zhang

et al. 2020

J Am Ceram Soc

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Ion‐conducting chalcogenide glass is a promising solid electrolyte with excellent conductivity and energy density for all‐solid‐state batteries. A suitable ionic channel for carriers in the amorphous network is urgently needed. In this work, the structural evolution of co‐doped metal cations (Ge and Ga) in the glass matrix and its influence on electrochemical behavior were studied using a series of GexGa16‐xSb64S128‐40AgI glass samples. The macroscopic properties of samples were examined by X‐ray diffraction (XRD), differential scanning calorimetry (DSC), and Raman tests. The electrochemical behavior of samples was investigated by AC impendence spectroscopy and cyclic voltammetry (CV) measurement. Furthermore, a deliquescence experiment was applied for the chemical stability test of glass samples. The ionic conductivity of samples was developed by adding Ga components. Notably, the electrochemical window of electrolytes was remarkably wide at approximately 5 V. The resistance of samples to humidity was characterized by the decreased Raman peaks. Analysis results show that the Ga‐related bonding structure evidently increased the chemical stability compared with the non‐Ga sample. This work provides an insight into the effective and stable ions transport, especially in the Ge(Ga)SbS glass system. These results promote the further investigation of sulfide solid electrolytes and practical application of all‐solid‐state batteries.

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“…The decreased band near 360 cm -1 can be credited to the symmetric stretching mode of edge-shared (ES) [GeS 4/2 ] tetrahedra. The increasing broad bands at 170 and 212 cm -1 were attributed to [S 2 Sb-SbS 2 ] and [Ag-S] units, respectively [13,15]. The most intense peak shifts from 308 cm -1 (x = 0.1) to 340 cm -1 at (x = 0.5) could be attributed to the influence of the added Ag 2 S on network bonding.…”

Section: Xrd Analysismentioning

confidence: 95%

“…Afterwards, the T g remained stable at approximately 190 °C rather than changing drastically with continuous addition of AgI (0.05 ≤ y ≤ 0.2). Addition of Ag + as the network modifier may be responsible for the bond breakage of [Sb-S…S-Sb] and [Ge-S…S-Ge] chains [13]. Severe reductions in T g are frequently accompanied by reductions in the interconnections of units, which means the interconnected S bonds are largely destroyed by Ag + at high concentrations of Ag + .…”

Section: Xrd Analysismentioning

confidence: 99%

Physical and electrochemical behaviors of AgX (X = S/I) in a GeS2–Sb2S3 chalcogenide-glass matrix

Jiao

Zhang

et al. 2020

Ceramics International

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Ion-conducting chalcogenide glasses of a AgX (X = S/I)-modified GeSbS system were triumphantly synthesized through the conventional techniques of melt quenching. The evolution of the physical and structural natures of these samples were examined through density and microhardness tests, DSC, and Raman scattering spectroscopy. The electric features of the bulk samples were studied by means of impedance spectroscopy. Room-temperature ionic conductivity dramatically increased by six orders of magnitude from 7.68 × 10-10 to 3.54 × 10-4 S/cm with increasing Ag + content. The blocking effect, a novel phenomenon caused by the presence of a small amount of I ions in the glass system, was also observed, and its corresponding mechanism was proposed. The blocking effect hindered a portion of the mobile carriers in the network. Another phenomenon, i.e., the saturation of Ag ions, resulted in a slow increase in ionic conductivity at high Ag + dopant concentrations. These results provide novel insights into structural evolution and electrochemical properties of metal-doped solid electrolytes.

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How silver influences the structure and physical properties of chalcogenide glass (GeS2)50(Sb2S3)50

Cited by 14 publications

References 33 publications

Investigation of the Atomic Structure of Ge-Sb-Se Chalcogenide Glasses

Investigation of the Atomic Structure of Ge-Sb-Se Chalcogenide Glasses

Structure promoted electrochemical behavior and chemical stability of AgI‐doped solid electrolyte in sulfide glass system

Physical and electrochemical behaviors of AgX (X = S/I) in a GeS2–Sb2S3 chalcogenide-glass matrix

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