Kara Fong

Kara Fong

Schmidt Science Fellow and Junior Research Fellow at Trinity College, Cambridge

Publications

Google Scholar Profile

22. P. K. Jones, K. D. Fong, K. A. Persson, A. A. Lee. “Inferring global dynamics from local structure in liquid electrolytes.” arXiv preprint, 2022, [arXiv:2208.03182].

21. J. Cheng, K. D. Fong, K. A. Persson. “Materials design principles of amorphous cathode coatings for lithium‑ion batteryapplications.” Journal of Materials Chemistry A, 2022. [doi]

20. J. Self, H. K. Bergstrom, K. D. Fong, B. D. McCloskey, K. A. Persson. “A Theoretical Model for Computing Freezing Point Depression of Lithium-Ion Battery Electrolytes.” Journal of the Electrochemical Society, 2021, 168: 120532. [doi]

19. T. Hou, K. D. Fong, J. Wang, K. A. Persson. “The Solvation Structure, Transport Properties and Reduction Behavior of Carbonate-Based Electrolytes of Lithium-Ion Batteries.” Chemical Science, 2021, 12, 44: 14740-14751. [doi]

18. A. J. Ringsby, K. D. Fong, J. Self, H. K. Bergstrom, B. D. McCloskey, K. A. Persson. “Transport Phenomena in Low Temperature Lithium-Ion Battery Electrolytes.” Journal of the Electrochemical Society, 2021, 168: 080501. [doi]

17. H. K. Bergstrom, K. D. Fong, B. D. McCloskey. “Interfacial Effects on Transport Coefficient Measurements in Li-ion Battery Electrolytes.” Journal of the Electrochemical Society, 2021, 168: 060543. [doi]

16. K. D. Fong, J. Self, B. D. McCloskey, K. A. Persson. “Ion Correlations and Their Impact on Transport in Polymer-Based Electrolytes.” Macromolecules, 2021, 54, 6: 2575-2591. [doi]

15. K. D. Fong, J. Self, B. D. McCloskey, K. A. Persson. “Onsager Transport Coefficients and Transference Numbers in Polyelectrolyte Solutions and Polymerized Ionic Liquids.” Macromolecules, 2020, 53, 21: 9503-9512. [doi]

14. K. D. Fong, H. K. Bergstrom, B. D. McCloskey, K. K. Mandadapu. “Transport Phenomena in Electrolyte Solutions: Non-Equilibrium Thermodynamics and Statistical Mechanics.” AIChE Journal, 2020, 66, 12: e17091. [doi]

13. J. Self, N. T. Hahn, K. D. Fong, S. A. McClary, K. R. Zavadil, and K. A. Persson. “Ion Pairing and Redissociaton in Low-Permittivity Electrolytes for Multivalent Battery Applications.” J. Phys. Chem. Lett, 2020, 11, 6: 2046-2052. [doi]

12. J. Self, K. D. Fong, and K. A. Persson. “Transport in Superconcentrated LiPF6 and LiBF4/Propylene Carbonate Electrolytes.” ACS Energy Letters, 2019, 4: 2843-2849. [doi]

11. J. Self, K. D. Fong, E. R. Logan, and K. A. Persson. “Ion Association Constants for Lithium Ion Battery Electrolytes from First Principles Quantum Chemistry.” Journal of the Electrochemical Society, 2019, 166: A3554-A3558. [doi]

10. K. D. Fong, J. Self, K. M. Diederichsen, B. M. Wood, B. D. McCloskey, and K. A. Persson. “Ion Transport and the True Transference Number in Nonaqueous Polyelectrolyte Solutions for Lithium-Ion Batteries.” ACS Central Science, 2019, 5: 1250-1260. [doi]

9. K. M. Diederichsen, K. D. Fong, R. C. Terrell, K. A. Persson, and B. D. McCloskey. “Investigation of Solvent Type and Salt Addition in High Transference Number Nonaqueous Polyelectrolyte Solutions for Lithium Ion Batteries.” Macromolecules, 2018, 51: 8761-8771. [doi]

8. T. Wang, H.-K. Kim, Y. Liu, W. Li, J. T. Griffiths, Y. Wu, S. Laha, K. D. Fong, F. Podjaski, C. Yun, R. V. Kumar, B. V. Lotsch, A. K. Cheetham, and S. K. Smoukov. “Bottom-up Formation of Carbon-Based Structures with Multilevel Hierarchy from MOF–Guest Polyhedra.” Journal of the American Chemical Society, 2018, 140: 6130-6136. [doi]

7. K. D. Fong, T. Wang, and S. K. Smoukov. “Mutli-Dimensional Performance Optimization of Conducting Polymer-Based Supercapacitor Electrodes.” Sustainable Energy and Fuels, 2017, 1: 1857-1874. [doi]

6. K. D. Fong,* T. Wang,* H.-K. Kim, R. V. Kumar, and S. K. Smoukov. “Semi-Interpenetrating Polymer Networks for Enhanced Supercapacitor Electrodes.” ACS Energy Letters, 2017, 2: 2014-2020. [doi]

5. T. L. Sirich, K. D. Fong, B. Larive, G. J. Beck, G. M. Chertow, N. W. Levin, A. S. Kliger, N. S. Plummer, and T. W. Meyer. “Limited Reduction in Uremic Solute Concentrations with Increased Dialysis Frequency and Time in the Frequent Hemodialysis Network Daily Trial.” Kidney International, 2017, 91: 1186-1192. [doi]

4. J. W. F. To, J. W. D. Ng, S. Siahrostami, A. L. Koh, Y. Lee, Z. Chen, K. D. Fong, S. Chen, J. He, W.-G. Bae, J. Wilcox, H. Y. Jeong, K. Kim, F. Studt, J. K. Nørskov, T. F. Jaramillo, and Z. Bao. “High-performance Oxygen Reduction and Evolution Carbon Catalysis: From Mechanistic Studies to Device Integration.” Nano Research, 2016, 10: 1163-1177. [doi]

3. F. J. O’Brien, K. D. Fong, T. L. Sirich, and T. W. Meyer. “More Dialysis Has Not Proven Much Better.” Seminars in Dialysis, 2016, 29: 481-490. [doi]

2. T.M. Meyer, T.L. Sirich, K. D. Fong, N.S. Plummer, T. Shafi, S. Hwan, T. Banerjee, Y. Zhu, N.R. Powe, X. Hai, and T.H. Hostetter. “Kt/Vurea and Nonurea Small Solute Levels in the Hemodialysis Study.” Journal of the American Society of Nephrology, 2016, 27: 3469-3478. [doi]

1. J.D. Benck, S.C. Lee, K. D. Fong, J. Kibsgaard, R. Sinclair, and T.F. Jaramillo. “Designing Active and Stable Silicon Photocathodes for Solar Hydrogen Evolution Using Molybdenum Sulfide Nanomaterials.” Advanced Energy Materials, 2014, 4: 1400739. [doi]