Thermoelectric power factor enhancement of calcium-intercalated layered silicene by introducing metastable phase

Tsukasa Terada; Takafumi Ishibe; Toranosuke Katayama; Kazunori Sato; Tien Quang Nguyen; Hideyuki Nakano; Yoshiaki Nakamura

doi:10.35848/1882-0786/ac2a57

Thermoelectric power factor enhancement of calcium-intercalated layered silicene by introducing metastable phase

Tsukasa Terada, Takafumi Ishibe, Toranosuke Katayama, Kazunori Sato, Tien Quang Nguyen, Hideyuki Nakano, Yoshiaki Nakamura

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

It has been theoretically predicted that the thermoelectric properties of silicene can be enhanced by deforming its atomic structure. In CaSi2, calcium-intercalated layered silicene, the silicene structure of the metastable 3R phase is a deformed silicene structure of the stable 6R phase. In this paper, our first-principle calculation reveals that the Seebeck coefficient is enhanced by transformation from stable 6R- to metastable 3R-CaSi2. We experimentally enhance the Seebeck coefficient by endotaxially introducing metastable 3R-CaSi2 into single-crystalline 6R-CaSi2, leading to a high thermoelectric power factor. This study demonstrates that introducing the metastable phase can become an effective way to enhance the thermoelectric power factor.

Original language	English
Article number	115505
Journal	Applied Physics Express
Volume	14
Issue number	11
DOIs	https://doi.org/10.35848/1882-0786/ac2a57
Publication status	Published - 2021 Nov
Externally published	Yes

ASJC Scopus subject areas

Engineering(all)
Physics and Astronomy(all)

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title = "Thermoelectric power factor enhancement of calcium-intercalated layered silicene by introducing metastable phase",

abstract = "It has been theoretically predicted that the thermoelectric properties of silicene can be enhanced by deforming its atomic structure. In CaSi2, calcium-intercalated layered silicene, the silicene structure of the metastable 3R phase is a deformed silicene structure of the stable 6R phase. In this paper, our first-principle calculation reveals that the Seebeck coefficient is enhanced by transformation from stable 6R- to metastable 3R-CaSi2. We experimentally enhance the Seebeck coefficient by endotaxially introducing metastable 3R-CaSi2 into single-crystalline 6R-CaSi2, leading to a high thermoelectric power factor. This study demonstrates that introducing the metastable phase can become an effective way to enhance the thermoelectric power factor. ",

author = "Tsukasa Terada and Takafumi Ishibe and Toranosuke Katayama and Kazunori Sato and {Quang Nguyen}, Tien and Hideyuki Nakano and Yoshiaki Nakamura",

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T1 - Thermoelectric power factor enhancement of calcium-intercalated layered silicene by introducing metastable phase

AU - Terada, Tsukasa

AU - Ishibe, Takafumi

AU - Katayama, Toranosuke

AU - Sato, Kazunori

AU - Quang Nguyen, Tien

AU - Nakano, Hideyuki

AU - Nakamura, Yoshiaki

PY - 2021/11

Y1 - 2021/11

N2 - It has been theoretically predicted that the thermoelectric properties of silicene can be enhanced by deforming its atomic structure. In CaSi2, calcium-intercalated layered silicene, the silicene structure of the metastable 3R phase is a deformed silicene structure of the stable 6R phase. In this paper, our first-principle calculation reveals that the Seebeck coefficient is enhanced by transformation from stable 6R- to metastable 3R-CaSi2. We experimentally enhance the Seebeck coefficient by endotaxially introducing metastable 3R-CaSi2 into single-crystalline 6R-CaSi2, leading to a high thermoelectric power factor. This study demonstrates that introducing the metastable phase can become an effective way to enhance the thermoelectric power factor.

AB - It has been theoretically predicted that the thermoelectric properties of silicene can be enhanced by deforming its atomic structure. In CaSi2, calcium-intercalated layered silicene, the silicene structure of the metastable 3R phase is a deformed silicene structure of the stable 6R phase. In this paper, our first-principle calculation reveals that the Seebeck coefficient is enhanced by transformation from stable 6R- to metastable 3R-CaSi2. We experimentally enhance the Seebeck coefficient by endotaxially introducing metastable 3R-CaSi2 into single-crystalline 6R-CaSi2, leading to a high thermoelectric power factor. This study demonstrates that introducing the metastable phase can become an effective way to enhance the thermoelectric power factor.

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Thermoelectric power factor enhancement of calcium-intercalated layered silicene by introducing metastable phase

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