| Thermoelectric materials and applications for energy harvesting power generation I Petsagkourakis, K Tybrandt, X Crispin, I Ohkubo, N Satoh, T Mori Science and technology of advanced materials 19 (1), 836-862, 2018 | 492 | 2018 |
| Novel principles and nanostructuring methods for enhanced thermoelectrics T Mori Small 13 (45), 1702013, 2017 | 318 | 2017 |
| Thermoelectric performance of a metastable thin-film Heusler alloy B Hinterleitner, I Knapp, M Poneder, Y Shi, H Müller, G Eguchi, ... Nature 576 (7785), 85-90, 2019 | 306 | 2019 |
| Nano-micro-porous skutterudites with 100% enhancement in ZT for high performance thermoelectricity AU Khan, K Kobayashi, DM Tang, Y Yamauchi, K Hasegawa, M Mitome, ... Nano Energy 31, 152-159, 2017 | 244 | 2017 |
| Demonstration of ultrahigh thermoelectric efficiency of∼ 7.3% in Mg3Sb2/MgAgSb module for low-temperature energy harvesting Z Liu, N Sato, W Gao, K Yubuta, N Kawamoto, M Mitome, K Kurashima, ... Joule 5 (5), 1196-1208, 2021 | 237 | 2021 |
| Thermoelectric nanomaterials K Koumoto, T Mori Materials Design and Applications, Springer Series in Materials Science 182 …, 2013 | 219 | 2013 |
| Polymer based thermoelectric nanocomposite materials and devices: Fabrication and characteristics N Nandihalli, CJ Liu, T Mori Nano Energy 78, 105186, 2020 | 212 | 2020 |
| Thermoelectricity generation and electron–magnon scattering in a natural chalcopyrite mineral from a deep‐sea hydrothermal vent R Ang, AU Khan, N Tsujii, K Takai, R Nakamura, T Mori Angewandte Chemie 127 (44), 13101-13105, 2015 | 210 | 2015 |
| High thermoelectric power factor in a carrier-doped magnetic semiconductor CuFeS2 N Tsujii, T Mori Applied Physics Express 6 (4), 043001, 2013 | 207 | 2013 |
| Materials for energy harvesting: At the forefront of a new wave T Mori, S Priya MRS Bulletin 43 (3), 176-180, 2018 | 179 | 2018 |
| Observation of enhanced thermopower due to spin fluctuation in weak itinerant ferromagnet N Tsujii, A Nishide, J Hayakawa, T Mori Science advances 5 (2), eaat5935, 2019 | 163 | 2019 |
| Thermoelectric properties of CuGa 1− x Mn x Te 2: power factor enhancement by incorporation of magnetic ions F Ahmed, N Tsujii, T Mori Journal of Materials Chemistry A 5 (16), 7545-7554, 2017 | 151 | 2017 |
| Manipulating the Ge vacancies and Ge precipitates through Cr doping for realizing the high‐performance GeTe thermoelectric material J Shuai, Y Sun, X Tan, T Mori Small 16 (13), 1906921, 2020 | 143 | 2020 |
| Measurements of branching fractions and direct asymmetries for , and decays YT Duh, TY Wu, P Chang, GB Mohanty, Y Unno, I Adachi, H Aihara, ... Physical Review D 87 (3), 031103, 2013 | 138 | 2013 |
| Magnetism-mediated thermoelectric performance of the Cr-doped bismuth telluride tetradymite JB Vaney, SA Yamini, H Takaki, K Kobayashi, N Kobayashi, T Mori Materials today physics 9, 100090, 2019 | 134 | 2019 |
| Maximizing the performance of n-type Mg3Bi2 based materials for room-temperature power generation and thermoelectric cooling Z Liu, W Gao, H Oshima, K Nagase, CH Lee, T Mori Nature communications 13 (1), 1120, 2022 | 132 | 2022 |
| Enhanced thermoelectric performance of Bi–Sb–Te/Sb 2 O 3 nanocomposites by energy filtering effect A Pakdel, Q Guo, V Nicolosi, T Mori Journal of materials chemistry A 6 (43), 21341-21349, 2018 | 127 | 2018 |
| Thermoelectric properties of homologous p-and n-type boron-rich borides T Mori, T Nishimura Journal of Solid State Chemistry 179 (9), 2908-2915, 2006 | 121 | 2006 |
| Handbook on the physics and chemistry of rare earths T Mori, KA Gschneidner, JC Bunzli, V Pecharsky by KA Gschneidner, Jr., J.-CG Bünzli and VK Pecharsky, Elsevier, Amsterdam, 105, 2008 | 119 | 2008 |
| Higher borides T Mori Handbook on the physics and chemistry of rare earths 38, 105-173, 2008 | 117 | 2008 |
