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熱電変換の部屋 | |
| THE ROOM OF THERMOELECTRICS |
 2025 English |
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North East Materials Database The comprehensive database of 7,123 thermoelectric compounds contains key information such as chemical composition, structural detail, Seebeck coefficient, electrical and thermal conductivity, power factor, and figure of merit (ZT). This data was extracted and curated automatically by researchers at the University of New Hampshire using the GPTArticleExtractor workflow, which is powered by large language models (LLM), from scientific literature published in Elsevier journals. |
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North East Materials Database, Computational Materials Science (DOI: 10.1016/j.commatsci.2025.113855) |
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| 2025 English |
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2025 Roadmap Toward Sustainable Thermoelectrics The roadmap covers everything from raw material supply and life cycle assessment to key materials. |
| SOURCE: Nanomaterials (DOI: 10.1088/2515-7655/ae2d98) | ||
| 2025 Japanese |
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Thermoelectric beginners' seminar movie A beginners' seminar held by the Thermoelectric Society of Japan has been uploaded to YouTube. |
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Thermoelectric property measurement technology Thermoelectric module evaluation technology |
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| 2025 English |
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SpringerMaterials This is Springer's paid materials database. This collection contains five important properties of these materials: thermal conductivity, ZT (figure of merit), power factor, conductivity, Seebeck Coefficient. |
| SOURCE: Springer | ||
| 2025 English |
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teMatDb:teMatDb: A High-Quality Thermoelectric Material Database with Self-Consistent ZT Filtering A thermoelectric material database created by researchers at the Korea Electrotechnology Research Institute. The teMatDb272 dataset, containing 272 high-quality TEP curve sets curated using the selfconsistent ZT filtering protocol. The full parent database, teMatDb v1.1.6, includes all 355 digitized TEP samples with both pre- and post-processing scripts used in the construction of teMatDb272. |
| SOURCE: arXiv:2505.19150, teMatDb272, teMatDb v1.1.6 | ||
| 2024 English |
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ThermoParser: Streamlined Analysis of Thermoelectric Properties ThermoParser is a Python package for analysing and plotting thermoelectric properties. The main dependencies are matplotlib (Hunter, 2007) for plotting, pymatgen (Ong et al., 2013) for symmetry analysis, numpy for calculations and click for the CLI. The package interfaces with Phonopy, Phono3py, AMSET and BoltzTraP. |
| SOURCE: The Journal of Open Source Softwear (DOI: 10.21105/joss.06340) | ||
| 2023 Japanese |
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Thermoelectric Society of Japan seminar "Basics of thermoelectric research" This video is a simplified version of the seminar for beginners held in May 2023. |
| SOURCE: YouTube | ||
| 2023 English |
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HORATES's Thermoelectric Materials Library HORATES bilding a free-acces library of thermoelectric materials, based on existing literature as well as their own research. This library organizes organic and hybrid thermoelectric materials preparation methods, power factors, etc. by polymer name. |
| SOURCE: HORATES | ||
| 2022 English |
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A thermoelectric materials database auto-generated from the scientific literature using ChemDataExtractor The database was auto-generated using the automatic sentence-parsing capabilities, natural language processing toolkit, ChemDataExtractor 2.0, adapted for application in the thermoelectric-materials domain. Data were mined from the text of 60,843 scientific papers that were sourced from three scientific publishers: Elsevier, the Royal Society of Chemistry, and Springer. |
| SOURCE: Scientific Data (DOI:10.1038/s41597-022-01752-1) | ||
| 2022 English |
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Digitized Contents Transmission Service for Individuals of the National Diet Library in Japan Approximately 1.53 million items stored by the National Diet Library can be viewed online. (Only for residents in Japan) |
| SOURCE: National Diet Library | ||
| 2022 English |
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Key properties of inorganic thermoelectric materials – tables (version 1) This paper presents tables of key thermoelectric properties, which define thermoelectric conversion efficiency, for a wide range of inorganic materials. The 12 families of materials included in these tables are primarily selected on the basis of well established. |
| SOURCE:
J. Phys. Energy (DOI:10.1088/2515-7655/ac49dc), An excel spreadsheet from the NIST Materials Data Facility |
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| 2022 Japanese |
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PropertiesDB Web, Heat-related materials database display software This database developed by NEDO, ThermoMAT and AIST. Two-dimensional correlation is displayed by collecting thermodynamic information mainly from Landolt-Börnstein, The NBS table of chemical thermodynamics and Research Report No. 196 of the Electrotechnical Laboratory. It is also linked to the PubChem. |
| SOURCE: PropertiesDB Web (in Japanese),AIST (in Japanese) | ||
| 2021 English |
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Materials informatics platform with three dimensional structures, workflow and thermoelectric applications The Materials Informatics Platform with Three-Dimensional Structures (MIP-3d) has more than 80,000 structural entries, mainly from the inorganic crystal structural database, are included in MIP-3d. Density functional theory calculations are carried out for over 30,000 entries in the database, which contain the relaxed crystal structures, density of states, and band structures. The calculation of the equations of state and sound velocities is performed for over 12,000 entries. Notably, for entries with band gap values larger than 0.3 eV, the band degeneracies for the valence band maxima and the conduction band minima are analysed. The electrical transport properties for approximately 4,400 entries are also calculated and presented in MIP-3d under the constant electron-phonon coupling approximation. The calculations of the band degeneracies and electrical transport properties make MIP-3d a database specifically designed for thermoelectric applications. |
| SOURCE: MIP-3d,Scientific Data(DOI:10.1038/s41597-021-01022-6) | ||
| 2021 English |
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UCSB Energy Materials Datamining Because not only physical properties such as Seebeck coefficient and electrical resistivity, but also Herfindahl–Hirschman index (HHI) can be plotted to rapidly sorting of thermoelectric compositions with respect to important issues of elemental scarcity and supply risk. |
| SOURCE: University of California, Santa Barbara | ||
| 2021 Japanese |
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TSJ Thermoelectric Application Roadmap (2021 version) This is SDGs compliant and provides efficiency and power generation cost goals. |
| SOURCE: Thermoelectrics Society of Japan | ||
| 2020 English |
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Advanced Thermoelectric Design: From Materials and Structures to Devices The ZT for the past 10 years is sorted by material type and year, and strategies of performance improvement is also summarized. Article Views is over 2000 in a week. I recommend that new researchers read this paper. |
| SOURCE: Chem. Rev.(DOI:10.1021/acs.chemrev.0c00026) | ||
| 2020 English |
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JARVIS:Joint Automated Repository for Various Integrated Simulations JARVIS is a repository designed to automate materials discovery using classical force-field, density functional theory, machine learning calculations and experiments. JARVIS-DFT has thermoelectric properties calculated with BoltzTrap code. |
| SOURCE: National Institute of Standards and Technology | ||
| 2020 English |
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Simulator for Phonon Transport in Arbitrary Nano-Structure(P-TRANS) This Free software is developed by Shiomi's Lab at The University of Tokyo and is sponsored by TherMAT project of NEDO. With this software, it is possible to estimate the effect of reducing the thermal conductivity when nanostructured, and also to understand the influence of the grain boundaries on the thermal conductivity of the polycrystalline structure generated during the production of highly thermally conductive materials. |
| SOURCE:
P-TRANS(Shiomi Lab @ UTokyo),
NEDO (in Japanese) REFERENCE:ACS Appl. Energy Mater.(DOI:10.1021/acsaem.9b00893) |
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| 2019 English |
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Thermoelectrics: From history, a window to the future This review begins with an historical excursus on the major steps in the history of thermoelectrics, from the very early discovery to present technology. Then, the most promising thermoelectric material classes are discussed one by one in dedicated sections and subsections, carefully highlighting the technological solutions on materials growth that have represented a turning point in the research on thermoelectrics. Finally, perspectives and the future of the technology are discussed in the framework of sustainability and environmental compatibility. An appendix on the theory of thermoelectric transport in the solid state reviews the transport theory in complex crystal structures and nanostructured materials. |
| SOURCE: Materials Science and Engineering: R: Reports (DOI:10.1016/j.mser.2018.09.001) | ||
| 2019 English |
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Material database led by Duke University Inorganic cristal structure database, band structuers, and thermal properties are recorded. |
| SOURCE: Automatic - FLOW for Materials Discovery | ||
| 2019 English |
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The Materials Project of Lawrence Berkeley National Laboratory At this website, you can use supercomputers to calculate properties of known materials and predict properties of unknown materials. |
| SOURCE: Lawrence Berkeley National Laboratory | ||
| 2018 English |
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A Review on Low-Grade Thermal Energy Harvesting:Materials, Methods and Devices The review provides a detailed analysis of advantages and disadvantages of each energy harvesting (Thermoelectric,Thermomagnetic,Thermoelastic,Pyroelectric) mechanism. |
| SOURCE: materials(DOI:10.3390/ma11081433) | ||
| 2018 English |
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Review of Development Status of Bi2Te3-Based Semiconductor Thermoelectric Power Generation The research status and progress of Bi2Te3-based semiconductor materials and thermoelectric generators in recent years are also introduced, respectively. |
| SOURCE: Hindawi | ||
| 2018 English |
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EPSRC Thermoelectric Network UK-ROADMAP The Thermoelectric Roadmap has been prepared by members of the EPSRC Thermoelectric Network such as the UK in 2018. |
| SOURCE: EPSRC Thermoelectric Network | ||
| 2018 English |
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Starrydata2 A wonderful web system of thermoelectric materials by Assistant Professor Yukari Katsura, University of Tokyo, and Dr. Masaya Kumagai,RIKEN AIP. You can obtain graph values of various papers. After logging in please click on "ThermoelectricMaterials". |
| SOURCE:
Starrydata2, REFERENCE:Lecture on Starrydata(YouTube, in Japanese), LLM-assisted data curation tools |
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| 2017 English |
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New trends, strategies and opportunities in thermoelectric materials: A perspective A paper on the Material Today Physics by Associate Professor Liu, Southern Science and Technology University in China, are getable. (DOI: 10.1016 / j.mtphys.2017.06.001) They predict the future from the trend of materials developed since around 1960. |
| SOURCE: ScienceDirect | ||
| 2015 Japanese |
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Patent search of thermoelectric conversion technology You can get to a report which the Japan Patent Office investigated on thermoelectric conversion technology in 2014. |
| SOURCE: Japan Patent Office | ||
| 2017 Japanese |
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Structural analysis software There are structural analysis related software collections on website of Institute for Solid State Physics at the University of Tokyo. |
| SOURCE: X-ray Laboratory, The Institute for Solid State Physics (ISSP) of the University of Tokyo | ||
2014 English |
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New ideas for advancing thermoelectric performance This is a video of a lecture given by the late MIT Research Professor Emeritus Mildred Dresselhaus at 2014 MRS Fall Meeting. |
| SOURCE: YouTube | ||
| 2014 English |
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Material and manufacturing cost considerations for thermoelectrics In this paper, system cost, operating cost versus the material performance of thermoelectric materials are estimated. |
| SOURCE: Renewable and Sustainable Energy Reviews 32 (2014) 313?327 | ||
| 2011 Japanese |
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TSJ Academic Roadmap This Thermoelectric Academic Roadmap was prepared by the Thermoelectrics Society of Japan in 2011. |
| SOURCE: Thermoelectrics Society of Japan | ||
| 2010 English |
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NIMS Materials Database From January 17, 2023, user registration has been changed to email address domain (〇.co.jp, etc.) registration.Use "Material database led by Duke University" or "The Materials Project of Lawrence Berkeley National Laboratory". There is no English user registration page yet. |
| SOURCE: National Institute for Materials Science(NIMS) | ||
| 2009 English |
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AIST Network Database System for Thermophysical Property Data Network Database System for Thermophysical Property Data is developed and run by AIST, and is available for free. Thermophysical properties data (ex. Thermal conductivity, thermal diffusivity, heat capacity, density, surface tension and vapor pressure) for liquid, solid and melts are stored in this database. |
| SOURCE: National Institute of Advanced Industrial Science and Technology (AIST) | ||
| 2008 English |
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Free band calculation software MINDLab Please download "MINDLab Software" from the link below and use it. I operation verification on only Windows XP. |
| SOURCE: University of California, Davis |