Jeffrey Greeley
Affiliations: | Chemical Engineering | Purdue University, West Lafayette, IN, United States |
Area:
First principles theories of interfacial science and catalysisWebsite:
https://engineering.purdue.edu/ChE/People/ptProfile?id=84163Google:
"Jeffrey Greeley"Mean distance: 10.09 | S | N | B | C | P |
Parents
Sign in to add mentorManos Mavrikakis | grad student | 2004 | UW Madison | |
(Studying surface reactivity of transition metals with computational surface science.) |
Children
Sign in to add traineeTej Salil Choksi | grad student | Purdue | |
Brandon Christopher Bukowski | grad student | 2014-2019 | Purdue |
Joseph Kubal | grad student | 2014-2019 | Purdue |
Yinan Xu | grad student | 2017-2022 | Purdue |
Maria Chan | post-doc | 2010-2012 | Argonne National Laboratory |
Rees B. Rankin | post-doc | 2009-2013 | Purdue (Physics Tree) |
Andre Clayborne | post-doc | 2012-2013 | Purdue |
William David Parker | post-doc | 2012-2015 | Purdue (Physics Tree) |
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Publications
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Sawant KJ, Zeng Z, Greeley JP. (2023) Origin of Stability and Activity Enhancements in Pt-based Oxygen Reduction Reaction Catalysts via Defect-Mediated Dopant Adsorption. Angewandte Chemie (International Ed. in English). 63: e202312747 |
Bukowski BC, Purdy SC, Wegener EC, et al. (2023) Intermetallic alloy structure-activity descriptors derived from inelastic X-ray scattering. Physical Chemistry Chemical Physics : Pccp |
Ghanekar PG, Deshpande S, Greeley J. (2022) Adsorbate chemical environment-based machine learning framework for heterogeneous catalysis. Nature Communications. 13: 5788 |
Zhao Q, Xu Y, Greeley J, et al. (2022) Deep reaction network exploration at a heterogeneous catalytic interface. Nature Communications. 13: 4860 |
LiBretto NJ, Xu Y, Quigley A, et al. (2021) Olefin oligomerization by main group Ga and Zn single site catalysts on SiO. Nature Communications. 12: 2322 |
Bates JS, Bukowski BC, Greeley J, et al. (2020) Structure and solvation of confined water and water-ethanol clusters within microporous Brønsted acids and their effects on ethanol dehydration catalysis. Chemical Science. 11: 7102-7122 |
Dionigi F, Zeng Z, Sinev I, et al. (2020) In-situ structure and catalytic mechanism of NiFe and CoFe layered double hydroxides during oxygen evolution. Nature Communications. 11: 2522 |
Purdy SC, Seemakurthi RR, Mitchell G, et al. (2020) Structural trends in the dehydrogenation selectivity of palladium alloys Chemical Science. 11: 5066-5081 |
Harris JW, Bates JS, Bukowski BC, et al. (2020) Opportunities in Catalysis over Metal-Zeotypes Enabled by Descriptions of Active Centers Beyond Their Binding Site Acs Catalysis. 10: 9476-9495 |
Majidi L, Hemmat Z, Warburton RE, et al. (2020) Highly Active Rhenium-, Ruthenium-, and Iridium-Based Dichalcogenide Electrocatalysts for Oxygen Reduction and Oxygen Evolution Reactions in Aprotic Media Chemistry of Materials. 32: 2764-2773 |