An Integrated Approach to Thermoelectrics: Combining Phonon Dynamics, Nanoengineering, Novel Materials Development, Module Fabrication, and Metrology

This review discusses the longstanding efforts to develop advanced thermoelectrics through a multidisciplinary approach by combining condensed matter physics, nanotechnology, solid‐state chemistry, electrical engineering, mechanical engineering, and metrology. The phonon dynamics of skutterudites, c...

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Bibliographic Details
Published in:Advanced energy materials 2019-06, Vol.9 (23), p.n/a
Main Authors: Ohta, Michihiro, Jood, Priyanka, Murata, Masayuki, Lee, Chul‐Ho, Yamamoto, Atsushi, Obara, Haruhiko
Format: Article
Language:English
Subjects:
Arsenides
bulk nanostructuring
Clathrates
Condensed matter physics
Electrical engineering
Electrical resistivity
Electromagnetism
Energy conversion efficiency
Energy harvesting
Energy recovery
Figure of merit
Hall effect
Inelastic scattering
Intermetallic compounds
Mechanical engineering
Metrology
modularization
Modules
Nanotechnology
nanowires
Neutron scattering
Neutrons
Organic chemistry
Phonons
rattling
Seebeck effect
Temperature gradients
Thermal conductivity
Thermoelectric materials
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Summary:This review discusses the longstanding efforts to develop advanced thermoelectrics through a multidisciplinary approach by combining condensed matter physics, nanotechnology, solid‐state chemistry, electrical engineering, mechanical engineering, and metrology. The phonon dynamics of skutterudites, clathrates, tetrahedrites, and layered LaOBiSSe are investigated through inelastic neutron scattering, allowing insights into their low lattice thermal conductivity due to rattling in a cage as well as under planar coordination. The electrical resistivity, Seebeck coefficient, and Hall coefficient of Bi‐nanowires are successfully measured with a home‐made system, demonstrating a size effect in thermoelectric and galvanomagnetic phenomena. For PbTe‐based bulk thermoelectrics, an exceptionally high figure of merit ZT (≈1.8 at 800 K) is achieved through nanostructuring. Moreover, correspondingly high conversion efficiency (≈11% for a temperature difference of 590 K) is demonstrated in nanostructured PbTe‐based modules. Sulfides (tetrahedrite, colusite, and CdI2‐type layered systems) and arsenides (LnFeAsO and BaZn2As2) are developed as environmentally friendly and emerging thermoelectric materials, respectively. The output power and efficiency of modules with novel materials, including nanostructured PbTe, Zn4Sb3, and clathrates, are measured with the highly accurate self‐made system. Future opportunities and challenges for the widespread use of thermoelectric waste heat recovery and energy harvesting are also discussed. The longstanding efforts to gain insights into thermoelectrics to develop highly efficient and environmentally friendly thermoelectric materials and modules and to improve the accuracy of evaluation methods are reviewed. Advanced thermoelectrics are developed for waste heat recovery through a multidisciplinary approach by combining condensed matter physics, nanotechnology, solid‐state chemistry, electrical engineering, mechanical engineering, and metrology.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.201801304