Lithium-sulfur batteries: attaining the critical metrics A Bhargav, J He, A Gupta, A Manthiram Joule 4 (2), 285-291, 2020 | 521 | 2020 |
Highly solvating electrolytes for lithium–sulfur batteries A Gupta, A Bhargav, A Manthiram Advanced energy materials 9 (6), 1803096, 2019 | 199 | 2019 |
Organotrisulfide: a high capacity cathode material for rechargeable lithium batteries M Wu, Y Cui, A Bhargav, Y Losovyj, A Siegel, M Agarwal, Y Ma, Y Fu Angewandte Chemie International Edition 55 (34), 10027-10031, 2016 | 190 | 2016 |
Molybdenum Boride as an Efficient Catalyst for Polysulfide Redox to Enable HighEnergyDensity Lithium–Sulfur Batteries J He, A Bhargav, A Manthiram Advanced Materials 32 (40), 2004741, 2020 | 163 | 2020 |
1T′ReS2 Nanosheets In Situ Grown on Carbon Nanotubes as a Highly Efficient Polysulfide Electrocatalyst for Stable Li–S Batteries J He, A Bhargav, H Yaghoobnejad Asl, Y Chen, A Manthiram Advanced Energy Materials 10 (23), 2001017, 2020 | 163 | 2020 |
Anode-free, lean-electrolyte lithium-sulfur batteries enabled by tellurium-stabilized lithium deposition S Nanda, A Bhargav, A Manthiram Joule 4 (5), 1121-1135, 2020 | 128 | 2020 |
Highly reversible diphenyl trisulfide catholyte for rechargeable lithium batteries M Wu, A Bhargav, Y Cui, A Siegel, M Agarwal, Y Ma, Y Fu ACS Energy Letters 1 (6), 1221-1226, 2016 | 91 | 2016 |
High-energy-density, long-life lithium–sulfur batteries with practically necessary parameters enabled by low-cost Fe–Ni nanoalloy catalysts J He, A Bhargav, A Manthiram ACS nano 15 (5), 8583-8591, 2021 | 86 | 2021 |
Influence of lithium polysulfide clustering on the kinetics of electrochemical conversion in lithium–sulfur batteries A Gupta, A Bhargav, JP Jones, RV Bugga, A Manthiram Chemistry of Materials 32 (5), 2070-2077, 2020 | 84 | 2020 |
The unique chemistry of thiuram polysulfides enables energy dense lithium batteries A Bhargav, Y Ma, K Shashikala, Y Cui, Y Losovyj, Y Fu Journal of materials chemistry A 5 (47), 25005-25013, 2017 | 82 | 2017 |
Stable dendrite-free sodium–sulfur batteries enabled by a localized high-concentration electrolyte J He, A Bhargav, W Shin, A Manthiram Journal of the American Chemical Society 143 (48), 20241-20248, 2021 | 77 | 2021 |
Phenyl selenosulfides as cathode materials for rechargeable lithium batteries Y Cui, JD Ackerson, Y Ma, A Bhargav, JA Karty, W Guo, L Zhu, Y Fu Advanced functional materials 28 (31), 1801791, 2018 | 76 | 2018 |
A class of organopolysulfides as liquid cathode materials for high-energy-density lithium batteries A Bhargav, ME Bell, J Karty, Y Cui, Y Fu ACS applied materials & interfaces 10 (25), 21084-21090, 2018 | 76 | 2018 |
Nanostructured Anatase Titania as a Cathode Catalyst for Li–CO2 Batteries R Pipes, A Bhargav, A Manthiram ACS applied materials & interfaces 10 (43), 37119-37124, 2018 | 74 | 2018 |
Polyphenylene tetrasulfide as an inherently flexible cathode material for rechargeable lithium batteries A Bhargav, ME Bell, Y Cui, Y Fu ACS Applied Energy Materials 1 (11), 5859-5864, 2018 | 67 | 2018 |
High-Performance Anode-Free Li–S Batteries with an Integrated Li2S–Electrocatalyst Cathode J He, A Bhargav, A Manthiram ACS Energy Letters 7 (2), 583-590, 2022 | 66 | 2022 |
Bis (aryl) tetrasulfides as cathode materials for rechargeable lithium batteries W Guo, ZD Wawrzyniakowski, MM Cerda, A Bhargav, MD Pluth, Y Ma, ... Chemistry–A European Journal 23 (67), 16941-16947, 2017 | 66 | 2017 |
Covalent Organic Framework as an Efficient Protection Layer for a Stable LithiumMetal Anode J He, A Bhargav, A Manthiram Angewandte Chemie 134 (18), e202116586, 2022 | 61 | 2022 |
Rationally designed high-sulfur-content polymeric cathode material for lithium–sulfur batteries A Bhargav, CH Chang, Y Fu, A Manthiram ACS applied materials & interfaces 11 (6), 6136-6142, 2019 | 61 | 2019 |
Mixture is better: enhanced electrochemical performance of phenyl selenosulfide in rechargeable lithium batteries W Guo, A Bhargav, JD Ackerson, Y Cui, Y Ma, Y Fu Chemical communications 54 (64), 8873-8876, 2018 | 56 | 2018 |