Vikram Pande
Vikram Pande
Senior Research Engineer, Tesla Inc
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Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O2 battery capacity
CM Burke, V Pande, A Khetan, V Viswanathan, BD McCloskey
Proceedings of the National Academy of Sciences 112 (30), 9293-9298, 2015
Comment on “Cycling Li-O2 batteries via LiOH formation and decomposition”
V Viswanathan, V Pande, KM Abraham, AC Luntz, BD McCloskey, ...
Science 352 (6286), 667, 2016
Single-ion homopolymer electrolytes with high transference number prepared by click chemistry and photoinduced metal-free atom-transfer radical polymerization
S Li, AI Mohamed, V Pande, H Wang, J Cuthbert, X Pan, H He, Z Wang, ...
ACS Energy Letters 3 (1), 20-27, 2017
Quantifying the promise of ‘beyond’Li–ion batteries
O Sapunkov, V Pande, A Khetan, C Choomwattana, V Viswanathan
Translational Materials Research 2 (4), 045002, 2015
Criteria and Considerations for the Selection of Redox Mediators in Nonaqueous Li–O2 Batteries
V Pande, V Viswanathan
ACS Energy Letters 2 (1), 60-63, 2017
Computational screening of current collectors for enabling anode-free lithium metal batteries
V Pande, V Viswanathan
ACS Energy Letters 4 (12), 2952-2959, 2019
Quantifying confidence in DFT-predicted surface pourbaix diagrams of transition-metal electrode–electrolyte interfaces
O Vinogradova, D Krishnamurthy, V Pande, V Viswanathan
Langmuir 34 (41), 12259-12269, 2018
Lithium metal electrodes and batteries thereof
YM Chiang, V Viswanathan, L Li, V Pande, D Krishnamurthy, Z Ahmad, ...
US Patent App. 15/480,235, 2017
Robust high-fidelity DFT study of the lithium-graphite phase diagram
V Pande, V Viswanathan
Physical Review Materials 2 (12), 125401, 2018
Design principles for self-forming interfaces enabling stable lithium-metal anodes
Y Zhu, V Pande, L Li, B Wen, MS Pan, D Wang, ZF Ma, V Viswanathan, ...
Proceedings of the National Academy of Sciences 117 (44), 27195-27203, 2020
Understanding ion pairing in high-salt concentration electrolytes using classical molecular dynamics simulations and its implications for nonaqueous Li–O2 batteries
A Khetan, HR Arjmandi, V Pande, H Pitsch, V Viswanathan
The Journal of Physical Chemistry C 122 (15), 8094-8101, 2018
Mechanism for Singlet Oxygen Production in Li-Ion and Metal–Air Batteries
G Houchins, V Pande, V Viswanathan
ACS Energy Letters 5 (6), 1893-1899, 2020
Vulnerabilities of electric vehicle battery packs to cyberattacks on auxiliary components
S Sripad, S Kulandaivel, V Pande, V Sekar, V Viswanathan
CoRR, 2017
Effect of Liquid Electrolyte Soaking on the Interfacial Resistance of Li7La3Zr2O12 for All-Solid-State Lithium Batteries
MM Besli, C Usubelli, M Metzger, V Pande, K Harry, D Nordlund, S Sainio, ...
ACS applied materials & interfaces 12 (18), 20605-20612, 2020
Descriptors for electrolyte-renormalized oxidative stability of solvents in lithium-ion batteries
V Pande, V Viswanathan
The journal of physical chemistry letters 10 (22), 7031-7036, 2019
Theoretical characterization of structural disorder in the tetramer model structure of eumelanin
O Sapunkov, A Khetan, V Pande, V Viswanathan
Phys. Rev. Materials 3 (10), 105403, 2019
Role of Disorder in NaO2 and Its Implications for Na–O2 Batteries
O Sapunkov, V Pande, A Khetan, V Viswanathan
The Journal of Physical Chemistry C 122 (33), 18829-18835, 2018
Impact of Size and Position of Lithium Metal Reference Electrodes on the Measurement of Lithium-Plating Overpotential
V Pande, A Abbasalinejad, J Hammond, J Christensen, SU Kim
Journal of The Electrochemical Society 168 (9), 090534, 2021
The Oxygen Reduction Reaction Kinetics on a Platinum/Graphene Surface
G Diankov, S Hong, J Xu, V Pande, J Park, R Sinclair, V Visvanathan, ...
ECS Meeting Abstracts, 1185, 2020
Electrolytes for lithium metal electrodes and rechargeable batteries using same
YM Chiang, V Viswanathan, L Li, V Pande, D Wang
US Patent App. 16/430,803, 2020
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