代表性论文(通讯/共同通讯作者)
[1] Realizing four-electron conversion chemistry for all-solid-state Li||I2 batteries at room temperature.Nature Communications, 2025,16,1723.
[2] Boosting the Li-O2 pouch cell beyond 860 Wh kg−1 by an O2-enriched localized high-concentration electrolyte.National Science Review,2025,nwaf059.
[3] Boosting Li−CO2 Battery Performance via High-Entropy Alloy Catalysts: Insights into Configurational Entropy Effect.Angewandte Chemie International Edition, 2025,e202424121.
[4] Lithium extraction from low-quality brines.Nature, 2024,636,309-321.
[5] A solid-state lithium-ion battery with micronsized silicon anode operating free from external pressure.Nature Communications, 2024, 15, 2263.
[6] Boosting a practical Li-CO2 battery through dimerization reaction based on solid redox mediator.Nature Communications, 2024, 15, 803.
[7] Binuclear Cu complex catalysis enabling Li–CO2 battery with a high discharge voltage above 3.0 V.Nature Communications, 2023,14,536.
[8] Covalent Organic Frameworks with Ni–Bis(dithiolene) and Co–Porphyrin Units as Bifunctional Catalysts for Li–O2 Batteries. Science Advances, 2023, 9(5), eadf2398.
[9] Carbon-free and binder-free Li-Al alloy anode enabling an all-solid-state Li-S batterywith high energy and stability.Science Advances, 2022, 8(15), eabn4372.
[10] Achieving long cycle life for all-solid-state rechargeable Li-I2 battery by a confined dissolution strategy. Nature Communication, 2022, 13, 125.(《LITHIUM-IODINE Confine the dissolution》Highlighted by Editor in Nature Energy, 2022, 7, 120.)
[11] Integrating Multiple Redox-Active Units into Conductive Covalent Organic Frameworks for High-Performance Sodium-Ion Batteries, Angewandte Chemie International Edition, 2024,e202417493.
[12] A Rechargeable “Rocking Chair” Type Zn−CO2 Battery, Angewandte Chemie International Edition, 2024, 63(39), e202409977.
[13] Lithium Metal Recovery from Sea Water by a Flexible and Scalable Membrane with Lithium-Ion Exclusive Channels, Angewandte Chemie International Edition, 2024,63(51),e202411957.
[14] Solvation-tailored PVDF-based Solid-state Electrolyte for Highvoltage Lithium Metal Batteries, Angewandte Chemie International Edition, 2024, 63(18), e202401428.
[15] Realizing the compatibility of a Li metal anode in an all-solid-state Li−S battery by chemical iodine–vapor deposition, Energy & Environmental Science, 2022,15, 3236-3245.120.
[16] A Low-Charge-Overpotential Lithium-CO2 Cell Based on Binary Molten Salt electrolyte.Energy & Environmental Science, 2021, 14(7), 4107-4114.
[17] Revealing the Impact of Space-Charge Layers on the Li-Ion Transport in All-Solid-State Batteries.Joule, 2020, 4(6), 1311-1323.
[18] Solar-driven all-solid-state lithium–air batteries operating at extreme low temperatures.Energy & Environmental Science, 2020, 13(4), 1205-1211.
[19] Li-CO2 and Na-CO2 Batteries: Toward Greener and Sustainable Electrical Energy Storage.Advanced Materials, 2019, 32(27), 1903790.
[20] Versatile Halide Ester Enabling Li Anode Stability and High Rate Capability of Lithium-Oxygen Batteries.Angewandte Chemie International Edition, 2019, 58(8), 2355-2359.
[21] A Concentrated Ternary-Salts Electrolyte for High Reversible Li Metal Battery with Slight Excess Li.Advanced Energy Materials,2019, 9(6), 1803372.
[22] Lithium Metal Extraction from Seawater.Joule, 2018, 2(9), 1648-1651.
[23] Developing water-defendable” and “dendrite free” lithium metal anode using a simple and promising GeCl4 pretreatment method.Advanced Materials, 2018, 30(36), 1705711.
[24] Direct Visualization of the Reversible O2/O− Redox Process in Li-Rich Cathode Materials. Advanced Materials, 2018, 30(14), 1705197.
[25] A reversible Lithium-CO2 battery with Ru nanoparticles as cathode catalyst.Energy & Environmental Science, 2017, 10(4), 972-978.
[26] Exploring the Electrochemical Reaction Mechanism of Carbonate Oxidation in Li-Air/CO2 Battery through Tracing Missing Oxygen.Energy & Environmental Science, 2016, 9(5), 1650-1654.
