Thermoelectric Energy Conversion: Theories and Mechanisms, Materials, Devices, and Applications

Thermoelectric Energy Conversion: Theories and Mechanisms, Materials, Devices, and Applications

by Ryoji Funahashi (Editor)


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Thermoelectric Energy Conversion: Theories and Mechanisms, Materials, Devices, and Applications provides readers with foundational knowledge on key aspects of thermoelectric conversion and reviews future prospects. Sections cover the basic theories and mechanisms of thermoelectric physics, the chemical and physical aspects of classical to brand-new materials, measurement techniques of thermoelectric conversion properties from the materials to modules and current research, including the physics, crystallography and chemistry aspects of processing to produce thermoelectric devices. Finally, the book discusses thermoelectric conversion applications, including cooling, generation, energy harvesting, space, sensor and other emerging areas of applications.

  • Reviews key applications of thermoelectric energy conversion, including cooling, power generation, energy harvesting, and applications for space and sensing
  • Discusses a wide range of materials, including skutterudites, heusler materials, chalcogenides, oxides, low dimensional materials, and organic materials
  • Provides the fundamentals of thermoelectric energy conversion, including the physics, phonon conduction, electronic correlation, magneto-seebeck theories, topological insulators and thermionics

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Product Details

ISBN-13: 9780128185353
Publisher: Elsevier Science
Publication date: 02/05/2021
Series: Woodhead Publishing Series in Electronic and Optical Materials Series
Pages: 730
Product dimensions: 6.00(w) x 9.00(h) x 1.46(d)

About the Author

Dr. Funahashi earned his MS in Chemistry (1992) from the Graduate School of Science, Nagoya University and a PhD in Applied Physics (1998) from Nagoya University. Before his work at AIST, he was a Research Scientist of Osaka National Research Institute. He has been a lecturer at Nagoya University, Osaka Electro-communication University, Akita Prefectural University and Osaka University.
He has studied thermoelectric materials from 1998, primarily focusing on oxide materials. He developed not only materials but also modules and power generation units. He is the founder of a start-up of thermoelectric technology in 2010.
He is a contributor to the thermoelectric academic community as a board member of both International Thermoelectric Society and Thermoelectric Society of Japan since 2004. He has a diverse array of experience in a wide range of fields including science, technology and application.

Table of Contents

Section A: Theory and mechanism

1.1 Thermoelectric properties beyond the standard Boltzmann model in oxides: A focus on the ruthenates

Florent Pawula, Ramzy Daou, Sylvie He'bert, and Antoine Maignan

1.2 Electron correlation

Ichiro Terasaki

1.3 Thermal transport by phonons in thermoelectrics

Yuxuan Liao, Harsh Chandra, and Junichiro Shiomi

Section B: Materials

2.1 Bismuth telluride

Yu Pan and Jing-Feng Li

2.2 Thermoelectric properties of skutterudites

Ctirad Uher

2.3 Recent developments in half-Heusler thermoelectric materials

Jan-Willem G. Bos

2.4 Pseudogap engineering of Fe2VAl-based thermoelectric Heusler compounds

Yoichi Nishino

2.5 Zintl phases for thermoelectric applications

Susan M. Kauzlarich, Kasey P. Devlin, and Christopher J. Perez

2.6 High-performance sulfide thermoelectric materials

Anthony V. Powell

2.7 Synthetic minerals tetrahedrites and colusites for thermoelectric power generation

Koichiro Suekuni, Michihiro Ohta, Toshiro Takabatake, and Emmanuel Guilmeau

2.8 High-performance thermoelectrics based on metal selenides

Tanmoy Ghosh, Moinak Dutta, and Kanishka Biswas

2.9 Materials development and module fabrication in highly efficient lead tellurides

Michihiro Ohta, Priyanka Jood, Raju Chetty, and Mercouri G. Kanatzidis

2.10 Oxide thermoelectric materials: Compositional, structural, microstructural, and processing challenges to realize their potential

Slavko Bernik

2.11 Oxide thermoelectric materials

Dursun Ekren, Feridoon Azough, and Robert Freer

2.12 Thermoelectric materials-based on organic semiconductors

Qingshuo Wei, Masakazu Mukaida, Kazuhiro Kirihara, and Takao Ishida

2.13 Organic thermoelectric materials and devices

Hong Wang and Choongho Yu

2.14 Thermoelectric materials and devices based on carbon nanotubes

Yoshiyuki Nonoguchi

2.15 Higher manganese silicides

Yuzuru Miyazaki

2.16 Silicide materials: Thermoelectric, mechanical properties, and durability for Mg-Si and Mn-Si

Tsutomu Iida, Ryo Inoue, Daishi Shiojiri, Naomi Hirayama, Noriaki Hamada, and Yasuo Kogo

2.17 Highly efficient Mg2Si-based thermoelectric materials: A review on the micro- and nanostructure properties and the role of alloying

Georgios S. Polymeris, Euripides Hatzikraniotis, and Theodora Kyratsi

Section C: Devices and modules

3.1 Segmented modules

Shengqiang Bai, Qihao Zhang, and Lidong Chen

3.2 Power generation performance of Heusler Fe2VAl modules

Masashi Mikami

3.3 Microthermoelectric devices using Si nanowires

Takanobu Watanabe

3.4 Measurement techniques of thermoelectric devices and modules

Hsin Wang and Shengqiang Bai

3.5 Evaluation method and measurement example of thermoelectric devices and modules

Satoaki Ikeuchi

Section D: Applications

4.1 Thermoelectric air cooling

Kashif Irshad

4.2 Air-cooled thermoelectric generator

Ryoji Funahashi, Tomoyuki Urata, Yoko Matsumura, Hiroyo Murakami, and Hitomi Ikenishi

4.3 Prospects of TEG application from the thermoelectric cooling market

Hirokuni Hachiuma

4.4 Thermoelectric applications in passenger vehicles

Doug Crane

4.5 Thermoelectric generators for full-sized trucks and sports utility vehicles

James R Salvador

4.6 Thermoelectric generation using solar energy

Sajjad Mahmoudinezhad and Alireza Rezaniakolaei

4.7 Development and demonstration of outdoor-applicable thermoelectric generators for IoT applications

Kanae Nakagawa and Takashi Suzuki

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