14. Shang Zhai. Iron-based oxides for thermochemical splitting of water and carbon dioxide. Mechanical Engineering, Stanford University (2020).
13. Andrey Poletayev. Ion conduction by the picosecond: optical probes and correlations. Materials Science & Engineering, Stanford University (2020).
12. Kipil Lim. Local Structure-redox Relationship in Li-excess Layered Oxides. Materials Science & Engineering, Stanford University (2019).
11. Peter Attia. Degradation of Cargon Negative Electrodes in Lithium-ion Batteries. Materials Science & Engineering, Stanford University (2019).
10. Nadia Ahlborg. Thermodynamics of Metal Oxides for Hydrogen via Thermochemical Cycling. Materials Science & Engineering, Stanford University (2019).
9. Antonio Baclig. Eutectic liquids for high-energy density flow batteries. Materials Science & Engineering, Stanford University (2019).
8. William Gent. Harnessing Oxygen Redox to Extend the Energy Density of Lithium-Ion Batteries. Chemistry, Stanford University (2018).
7. Zixuan Guan. Probing and Tuning the Far-from-equilibrium Oxygen Exchange Mechanism on Electrochemical Solid-gas Interfaces. Applied Physics, Stanford University (2018).
6. Madhur Boloor. Solid-State Architecture for an Elevated-Temperature Photoelectrochemical Cell. Materials Science & Engineering, Stanford University (2017).
5. Michael L. Machala. Surface Cation Heterogeneity in Perovskite Oxides Connected to Catalytic Activity and Stability. Materials Science & Engineering, Stanford University (2017).
4. Yiyang Li. Nanoscale reaction, transport, and phase transformation in LixFePO4 battery electrodes. Materials Science & Engineering, Stanford University (2016).
3. Xiaofei Ye. Elevated-Temperature Photo-electrochemical Water Splitting. Materials Science & Engineering, Stanford University (2016).
2. Yezhou Shi. Oxide Surface and Bulk Atomic Structures Studied by Real-space and Reciprocal-space Probes. Materials Science & Engineering, Stanford University (2015).
1. Zhuoluo A. Feng. In-Operando X-ray Photoelectron Spectroscopy Investigation of the Ceria/Gas Electrochemical Interface. Applied Physics, Stanford University (2015).
