G. Jeffrey Snyder
Affiliations: | 1997-2014 | Jet Propulsion Laboratory | California Institute of Technology, Pasadena, CA |
| 2015- | Materials Science and Engineering | Northwestern University, Evanston, IL |
Area:
thermoelectric materialsWebsite:
http://www.mccormick.northwestern.edu/research-faculty/directory/profiles/snyder-gerald.htmlGoogle:
"G. Snyder"Bio:
http://thermoelectrics.matsci.northwestern.edu/
http://www.mccormick.northwestern.edu/docs/public_cv/Snyder-Gerald%20Jeffrey-CV.pdf
a href=http://thermoelectrics.caltech.edu/jsnyder/ target=_blank>http://thermoelectrics.caltech.edu/jsnyder/
Snyder, G. Jeffrey, Magnetism and electron transport in magnetoresistive lanthanum calcium manganite, Thesis (Ph. D.)--Stanford University, 1997.
Mean distance: 9.51 | S | N | B | C | P |
Parents
Sign in to add mentor| Theodore H. Geballe | grad student | 1997 | Stanford | |
| (Magnetism and Electron Transport in Magnetoresistive Lanthanum Calcium Manganite) | ||||
Children
Sign in to add trainee| Gregory Pomrehn | grad student | 2013 | Caltech |
| Alexandra Zevalkink | grad student | 2008-2014 | Caltech, Northwestern |
| Stephen Dongmin Kang | grad student | 2013-2018 | Caltech (Physics Tree) |
| Richard G. Blair | post-doc | 2005-2006 | Jet Propulsion Laboratory |
| Eric S. Toberer | post-doc | 2006-2011 | Caltech |
| Jun Peng | post-doc | 2020 | Northwestern (E-Tree) |
| Kent Griffith | post-doc | 2019-2022 | Northwestern |
| Wolfgang Zeier | research scientist | 2010-2013 | Caltech |
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Publications
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| Toriyama MY, Snyder GJ. (2024) Are topological insulators promising thermoelectrics? Materials Horizons |
| Hauble AK, Toriyama MY, Bartling S, et al. (2023) Experiment and Theory in Concert To Unravel the Remarkable Electronic Properties of Na-Doped EuZnSnAs: A Layered Zintl Phase. Chemistry of Materials : a Publication of the American Chemical Society. 35: 7719-7729 |
| Toriyama MY, Carranco AN, Snyder GJ, et al. (2023) Material descriptors for thermoelectric performance of narrow-gap semiconductors and semimetals. Materials Horizons |
| Isotta E, Jiang S, Moller G, et al. (2023) Microscale Imaging of Thermal Conductivity Suppression at Grain Boundaries. Advanced Materials (Deerfield Beach, Fla.). e2302777 |
| Liu Y, Xie H, Li Z, et al. (2023) Unraveling the Role of Entropy in Thermoelectrics: Entropy-Stabilized Quintuple Rock Salt PbGeSnCdTe. Journal of the American Chemical Society |
| Toriyama MY, Cheikh D, Bux SK, et al. (2022) YTe: A New n-Type Thermoelectric Material. Acs Applied Materials & Interfaces. 14: 43517-43526 |
| Jang H, Toriyama MY, Abbey S, et al. (2022) Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p-Type Dopability in AgBiSe2-SnSe Thermoelectrics. Advanced Materials (Deerfield Beach, Fla.). e2204132 |
| Xie H, Liu Y, Zhang Y, et al. (2022) High Thermoelectric Performance in Chalcopyrite CuAgGaTe-ZnTe: Nontrivial Band Structure and Dynamic Doping Effect. Journal of the American Chemical Society |
| Jang H, Park JH, Lee HS, et al. (2021) Regulating Te Vacancies through Dopant Balancing via Excess Ag Enables Rebounding Power Factor and High Thermoelectric Performance in p-Type PbTe. Advanced Science (Weinheim, Baden-Wurttemberg, Germany). e2100895 |
| Hu L, Fang YW, Qin F, et al. (2021) High thermoelectric performance enabled by convergence of nested conduction bands in PbBiSe with low thermal conductivity. Nature Communications. 12: 4793 |