Multi-deimension utilization of solar energy.

Including solar rechargeable battery, secondary battery, all-solid-state battery and solar cells

Solar rechargeable battery：

1.Peng Chen, Tian-Tian Li, Yuan-Bo Yang, Guo-Ran Li, Xue-Ping Gao^*, Coupling aqueous zinc batteries and perovskite solar cells for simultaneous energy harvest, conversion and storage, Nature Communications, 2022 (Featured in Nature Communications Editors’ Highlights webpage)

2.Tian-Tian Li, Yuan-Bo Yang, Guo-Ran Li; Peng Chen*; Xue-Ping Gao*; Two-terminal Perovskite-based Tandem Solar Cells for Energy Conversion andStorage, Small, 2021

3.Peng Chen, Tian-Tian Li, Guo-Ran Li, Xue-Ping Gao^*.Quasi-solid-state solar rechargeable capacitors based on in-situ Janus modified electrode for solar energy multiplication effect. Sci. China Mater, 2020

4.Peng Chen, Guo-Ran Li, Tian-Tian Li, Xue-Ping Gao^*. Solar‐Driven Rechargeable Lithium–Sulfur Battery. Advanced Science, 2019.

All-solid-state battery：

1.Bo-Sheng Zhao,  Peng Chen*, Xue-Ping Gao*; Bulk and interface strengthened Li7P2.9Sb0.1S10.65O0.15I0.2 electrolyte via dual-source doping for all-solid-state lithium-sulfur batteries, Science China-Materials, 2022

2.Xiu Zheng, En-De Fu, Peng Chen*, Sheng Liu, Guo-Ran Li, and Xue-Ping Gao*; Li₃InCl₆-coated LiCoO₂ for high-performance all solid-state batteries, Applied Physics Letters, 2022

3.Bo-Sheng Zhao, Lu Wang, Peng Chen*, Sheng Liu, Guo-Ran Li, Ning Xu, Meng-Tao Wu, and Xue-Ping Gao*; Congener Substitution Reinforced Li₇P_2.9Sb_0.1S_10.75O_0.25 Glass-Ceramic Electrolytes for All-Solid-State Lithium–Sulfur Batteries, ACS Appl. Mater. Interfaces, 2021