Prospective Photovoltaic-Thermoelectric Hybrid System

“…The detection sensitivity of the thermal sensor can be assessed by the speed and magnitude of voltage generation from a minimal temperature change . Thus, TE material with a large Seebeck coefficient is preferred for thermal sensing that requires high sensitivity and accurate temperature-sensing ability. , Recent decades have witnessed great efforts in developing novel TE materials including organic and inorganic materials to realize highly sensitive thermal sensing. − The organic TE materials exhibit unique flexibility and ease of processing. This low Seebeck coefficient limits its potential application in high-performance thermal sensors. − Due to the relatively high carrier concentration, inorganic crystalline TE materials usually show a low Seebeck coefficient and high electrical conductivity, which is not suitable for thermal sensing. − In contrast, inorganic amorphous TE materials possess low thermal conductivity and high Seebeck coefficient in spite of a low ZT, which are promising candidates for thermal sensors with high sensitivity and temperature resolution. , The recently reported semiconducting chalcogenide glasses of Cu–As–Se–Te, As–Se–Sb–Cu, and Ge–Se–Sb–Ag systems present a high Seebeck coefficient of above 1000 μV/K, − while the low anticrystallization ability of these materials leads to uncontrolled crystallization during fiber drawing, which results in the decrease of the Seebeck coefficient .…”

High Seebeck Coefficient Inorganic Ge₁₅Ga₁₀Te₇₅ Core/Polymer Cladding Fibers for Respiration and Body Temperature Monitoring

“…The detection sensitivity of the thermal sensor can be assessed by the speed and magnitude of voltage generation from a minimal temperature change . Thus, TE material with a large Seebeck coefficient is preferred for thermal sensing that requires high sensitivity and accurate temperature-sensing ability. , Recent decades have witnessed great efforts in developing novel TE materials including organic and inorganic materials to realize highly sensitive thermal sensing. − The organic TE materials exhibit unique flexibility and ease of processing. This low Seebeck coefficient limits its potential application in high-performance thermal sensors. − Due to the relatively high carrier concentration, inorganic crystalline TE materials usually show a low Seebeck coefficient and high electrical conductivity, which is not suitable for thermal sensing. − In contrast, inorganic amorphous TE materials possess low thermal conductivity and high Seebeck coefficient in spite of a low ZT, which are promising candidates for thermal sensors with high sensitivity and temperature resolution. , The recently reported semiconducting chalcogenide glasses of Cu–As–Se–Te, As–Se–Sb–Cu, and Ge–Se–Sb–Ag systems present a high Seebeck coefficient of above 1000 μV/K, − while the low anticrystallization ability of these materials leads to uncontrolled crystallization during fiber drawing, which results in the decrease of the Seebeck coefficient .…”

High Seebeck Coefficient Inorganic Ge₁₅Ga₁₀Te₇₅ Core/Polymer Cladding Fibers for Respiration and Body Temperature Monitoring

“…Advanced energy conversion technologies like solar cells, thermoelectricity, fuel cells, and supercapacitors are important guarantees for continuous economic growth and people's life quality improvement 1–15 . Among them, rechargeable zinc‐air battery (ZAB) has been attracting more and more attention for its high energy density, low cost, and environmental friendliness 16,17 .…”

Electrospun 3D structured double perovskite oxide PrBa_0.8Ca_0.2Co₂O_5+δ bifunctional electrocatalyst for zinc‐air battery

“…With utility of recent generation and ecological knowledge, the neighborhood assets may beefed on without a great deal damage to environment. [5][6][7] The renewable assets encompass wind power, sunpower, biomass power, biogas etc. Power technology zone may be very vital in Indian financial system and it's far growing rapidly.…”

Photovoltaic Integrated Solar Induction Heater using Voltage Source Inverter