| Matminer: An open source toolkit for materials data mining L Ward, A Dunn, A Faghaninia, NER Zimmermann, S Bajaj, Q Wang, ... Computational Materials Science 152, 60-69, 2018 | 824 | 2018 |
| A practical field guide to thermoelectrics: Fundamentals, synthesis, and characterization A Zevalkink, DM Smiadak, JL Blackburn, AJ Ferguson, ML Chabinyc, ... Applied Physics Reviews 5 (2), 2018 | 331 | 2018 |
| Skutterudite with graphene-modified grain-boundary complexion enhances zT enabling high-efficiency thermoelectric device P Zong, R Hanus, M Dylla, Y Tang, J Liao, Q Zhang, GJ Snyder, L Chen Energy & Environmental Science 10 (1), 183-191, 2017 | 308 | 2017 |
| Realizing high-performance thermoelectric power generation through grain boundary engineering of skutterudite-based nanocomposites Q Zhang, Z Zhou, M Dylla, MT Agne, Y Pei, L Wang, Y Tang, J Liao, J Li, ... Nano Energy 41, 501-510, 2017 | 167 | 2017 |
| How to analyse a density of states MY Toriyama, AM Ganose, M Dylla, S Anand, J Park, MK Brod, JM Munro, ... Materials Today Electronics 1, 100002, 2022 | 88 | 2022 |
| Analytical models of phonon–point-defect scattering R Gurunathan, R Hanus, M Dylla, A Katre, GJ Snyder Physical Review Applied 13 (3), 034011, 2020 | 88 | 2020 |
| When band convergence is not beneficial for thermoelectrics J Park, M Dylla, Y Xia, M Wood, GJ Snyder, A Jain Nature communications 12 (1), 3425, 2021 | 82 | 2021 |
| Grain Boundary Engineering Nanostructured SrTiO3 for Thermoelectric Applications MT Dylla, JJ Kuo, I Witting, GJ Snyder Advanced Materials Interfaces 6 (15), 1900222, 2019 | 74 | 2019 |
| Machine learning chemical guidelines for engineering electronic structures in half-heusler thermoelectric materials MT Dylla, A Dunn, S Anand, A Jain, GJ Snyder Research, 2020 | 48 | 2020 |
| Graphene/strontium titanate: approaching single crystal–like charge transport in polycrystalline oxide perovskite nanocomposites through grain boundary engineering Y Lin, MT Dylla, JJ Kuo, JP Male, IA Kinloch, R Freer, GJ Snyder Advanced Functional Materials 30 (12), 1910079, 2020 | 47 | 2020 |
| Effect of two‐dimensional crystal orbitals on Fermi surfaces and electron transport in three‐dimensional perovskite oxides MT Dylla, SD Kang, GJ Snyder Angewandte Chemie 131 (17), 5557-5566, 2019 | 41 | 2019 |
| Thermopower-conductivity relation for distinguishing transport mechanisms: Polaron hopping in and band conduction in SD Kang, M Dylla, GJ Snyder Physical Review B 97 (23), 235201, 2018 | 38 | 2018 |
| Empirical modeling of dopability in diamond-like semiconductors SA Miller, M Dylla, S Anand, K Gordiz, GJ Snyder, ES Toberer npj Computational Materials 4 (1), 71, 2018 | 36 | 2018 |
| The Vacancy‐Induced Electronic Structure of the SrTiO3−δ Surface S Cook, MT Dylla, RA Rosenberg, ZR Mansley, GJ Snyder, LD Marks, ... Advanced Electronic Materials 5 (1), 1800460, 2019 | 21 | 2019 |
| Fracture Strength Distribution of Individual Nb3Sn Filaments MT Dylla, SE Schultz, MC Jewell IEEE Transactions on Applied Superconductivity 26 (8), 1-7, 2016 | 12 | 2016 |
| Comparison of the tetrahedron method to smearing methods for the electronic density of states MY Toriyama, AM Ganose, M Dylla, S Anand, J Park, MK Brod, J Munro, ... arXiv preprint arXiv:2103.03469, 2021 | 6 | 2021 |
| When Band Convergence is Not Beneficial for Thermoelectricity J Park, M Dylla, Y Xia, J Snyder, A Jain Bulletin of the American Physical Society 65, 2020 | | 2020 |
| Research Article Machine Learning Chemical Guidelines for Engineering Electronic Structures in Half-Heusler Thermoelectric Materials MT Dylla, A Dunn, S Anand, A Jain, GJ Snyder | | 2020 |
| Machine Learning Chemical Guidelines for Engineering Electronic Structures in Half MT Dylla, A Dunn, S Anand | | 2020 |
| Linear Decomposition of Atomic Orbitals: Mapping the Electronic Properties of Crystalline Materials MT Dylla Northwestern University, 2020 | | 2020 |
G. Jeffrey SnyderNorthwestern UniversityVerified email at northwestern.edu