Impact of physicochemical properties on band gap energy and glass transition temperature of (GeS₂)₁₀(Sb₂S₃)_90−x(AgI)_x chalcohalide glasses for Near-IR applications

Abstract: The dependence of band gap energy (Eg) and glass-transition temperature (Tg) on physico-chemical properties for the (GeS2)10(Sb2S3)90−x(AgI)x (10 ≤ x ≤ 50 at%) chalcohalide glasses were theoretically investigated. Chalcohalide glasses have wide technological applications owing to the aptitude of tuning their optical band gap through composition change. Therefore, Eg of the studied chalcohalide glasses was estimated using different methods, and it was turned out that it decreased as the AgI amount increases. Th… Show more

“…The chalcogenide glasses, formed in conjunction with electropositive element, are based on sulphur (S), selenium (Se) and tellurium (Te) elements. They are the promising materials for applications in thermoelectric, near infrared (IR) and sensing devices [1][2][3][4]. The main attraction of these glasses is their transparency extending from visible to far-IR region including the atmospheric transparency bands I and II [5].…”

Topological analysis and glass kinetics of Se-Te-Ag lone pair semiconductors

“…The chalcogenide glasses, formed in conjunction with electropositive element, are based on sulphur (S), selenium (Se) and tellurium (Te) elements. They are the promising materials for applications in thermoelectric, near infrared (IR) and sensing devices [1][2][3][4]. The main attraction of these glasses is their transparency extending from visible to far-IR region including the atmospheric transparency bands I and II [5].…”

Topological analysis and glass kinetics of Se-Te-Ag lone pair semiconductors

Characterization of physicochemical properties of As2Se3–GeTe–AgI chalcohalide glasses for solar cell and IR applications: influence of adding AgI

Characterisation of physicochemical properties of ((As2Se3)0.6(AgI)0.4)100−x(GeTe)x chalcohalide glasses for infrared devices: effect of GeTe addition