Enhanced thermoelectric performance of p -type filled skutterudites via the coherency strain fields from spinodal decomposition

Filled skutterudites, possessing a high power factor and good mechanical properties, have attracted intensive attention for the intermediate-temperature power generation.

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Фазовые равновесия в системе Sm2Te3–GeTe

Kondensirovannye sredy i mezhfaznye granitsy = Condensed Matter and Interphases ◽

10.17308/kcmf.2019.21/770 ◽

2019 ◽

Vol 21 (2) ◽

pp. 328-333

Author(s):

Ziyafat Mukhtarova

Keyword(s):

Spinodal Decomposition ◽

Thermoelectric Properties ◽

Electronic Materials ◽

Decomposition Reaction ◽

Simultaneous Optimization ◽

Thermoelectric Performance ◽

Advanced Materials ◽

Energy Materials ◽

Thermo Electric ◽

P Type

Методами физико-химического анализа – дифференциально-термическим, высокотемпературным дифференциально-термическим, рентгенофазовым, микроструктурным, а также измерением микротвердости изучена система Sm2Te3–GeTe, которая является квазибинарным сечением тройной системы Ge–Sm–Te. При соотношении исходных теллуридов 1:1 (50 мол. %) и температуре 1100 К по перитектической реакции ж+Sm2Te3→ GeSm2Te4 образуется тройное соединение GeSm2Te4. Образцы системы, богатые GeTe, представляют собой компактные слитки блестяще-серого цвета, а сплавы, бо-гатые Sm2Te3 – спек черного цвета. Ликвидус системы Sm2Te3–GeTe состоит из трех ветвей: Sm2Te3, GeSm2Te4 и a-твердых растворов на основе GeTe. Рентгенофазовый анализ закристаллизованных образцов показал, что набор рентгеновских отражений соответствует фазам Sm2Te3, GeSm2Te4 и a-твердых растворов на основе GeTe. Установлено образование инконгруэнтно плавящегося соединения состава GeSm2Te4, которое может использоваться как термоэлектрический материал. 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