Hybrid and Aqueous Lithium‐Air Batteries A Manthiram, L Li Advanced Energy Materials 5 (4), 1401302, 2015 | 163 | 2015 |
Enhanced Cycling Stability of Hybrid Li–Air Batteries Enabled by Ordered Pd3Fe Intermetallic Electrocatalyst Z Cui, L Li, A Manthiram, JB Goodenough Journal of the American Chemical Society 137 (23), 7278-7281, 2015 | 161 | 2015 |
Advanced hybrid Li–air batteries with high-performance mesoporous nanocatalysts L Li, SH Chai, S Dai, A Manthiram Energy & Environmental Science 7 (8), 2630-2636, 2014 | 154 | 2014 |
Molecular understanding of polyelectrolyte binders that actively regulate ion transport in sulfur cathodes L Li, TA Pascal, JG Connell, FY Fan, SM Meckler, L Ma, YM Chiang, ... Nature communications 8 (1), 2277, 2017 | 138 | 2017 |
A dual-electrolyte rechargeable Li-air battery with phosphate buffer catholyte L Li, X Zhao, A Manthiram Electrochemistry Communications, 2011 | 134 | 2011 |
Long‐Life, High‐Voltage Acidic Zn–Air Batteries L Li, A Manthiram Advanced Energy Materials 6 (5), 1502054, 2016 | 121 | 2016 |
Hierarchical pore-in-pore and wire-in-wire catalysts for rechargeable Zn–and Li–air batteries with ultra-long cycle life and high cell efficiency L Li, C Liu, G He, D Fan, A Manthiram Energy & Environmental Science 8 (11), 3274-3282, 2015 | 119 | 2015 |
VO 2/rGO nanorods as a potential anode for sodium-and lithium-ion batteries G He, L Li, A Manthiram Journal of Materials Chemistry A 3 (28), 14750-14758, 2015 | 111 | 2015 |
Co3O4 nanocrystals coupled with O-and N-doped carbon nanoweb as a synergistic catalyst for hybrid Li-air batteries L Li, S Liu, A Manthiram Nano Energy 12, 852-860, 2015 | 110 | 2015 |
Delineating the roles of Co 3 O 4 and N-doped carbon nanoweb (CNW) in bifunctional Co 3 O 4/CNW catalysts for oxygen reduction and oxygen evolution reactions S Liu, L Li, HS Ahn, A Manthiram Journal of Materials Chemistry A 3 (21), 11615-11623, 2015 | 104 | 2015 |
O-and N-Doped Carbon Nanowebs as Metal-Free Catalysts for Hybrid Li-Air Batteries. L Li, A Manthiram Advanced Energy Materials 4 (10), 2014 | 99 | 2014 |
Design rules for membranes from polymers of intrinsic microporosity for crossover-free aqueous electrochemical devices MJ Baran, MN Braten, S Sahu, A Baskin, SM Meckler, L Li, L Maserati, ... Joule 3 (12), 2968-2985, 2019 | 93 | 2019 |
Dual-electrolyte lithium-air batteries: Influence of catalyst, temperature, and solid-electrolyte conductivity on the efficiency and power density A Manthiram, L Li J. Mater. Chem. A, 2013 | 71 | 2013 |
Nanoporous polymer films with a high cation transference number stabilize lithium metal anodes in light-weight batteries for electrified transportation L Ma, C Fu, L Li, KS Mayilvahanan, T Watkins, BR Perdue, KR Zavadil, ... Nano letters 19 (2), 1387-1394, 2019 | 67 | 2019 |
Decoupled bifunctional air electrodes for high-performance hybrid lithium-air batteries L Li, A Manthiram Nano Energy 9, 94-100, 2014 | 67 | 2014 |
Understanding and controlling the chemical evolution and polysulfide-blocking ability of lithium–sulfur battery membranes cast from polymers of intrinsic microporosity SE Doris, AL Ward, PD Frischmann, L Li, BA Helms Journal of Materials Chemistry A 4 (43), 16946-16952, 2016 | 58 | 2016 |
Polyprotic acid catholyte for high capacity dual-electrolyte Li-air batteries A Manthiram, L Li, X Zhao, Y Fu Physical Chemistry Chemical Physics, 2012 | 49 | 2012 |
Materials genomics screens for adaptive ion transport behavior by redox-switchable microporous polymer membranes in lithium–sulfur batteries AL Ward, SE Doris, L Li, MA Hughes Jr, X Qu, KA Persson, BA Helms ACS Central Science 3 (5), 399-406, 2017 | 45 | 2017 |
Imidazole-buffered acidic catholytes for hybrid Li–air batteries with high practical energy density L Li, Y Fu, A Manthiram Electrochemistry communications 47, 67-70, 2014 | 41 | 2014 |
Expandable-graphite-derived graphene for next-generation battery chemistries C Zu, L Li, L Qie, A Manthiram Journal of Power Sources 284, 60-67, 2015 | 34 | 2015 |