Google Scholar               

                                                                                                                                                    * corresponding author

31. Boosting cycling stability and rate capability of Li-CO2 battery via synergistic photoelectric effect and plasmonic interaction

K. Zhang, J. Li, W. Zhai, C. Li, Z. Zhu, X. Kang, M. Liao, L. Ye,  T. Kong, C. Wang, Y. Zhao, P. Chen, Y. Gao, B. Wang*, H. Peng*

Angewandte Chemie International Edition just accepted (2022)

30. High-Efficiency and Stable Li−CO2 Battery Enabled by Carbon Nanotube/Carbon Nitride Heterostructured Photocathode

J. Li, K. Zhang, Y. Zhao, C. Wang, L. Wang, L. Wang, M. Liao, L. Ye,  Z. Ye, Y. Gao, B. Wang*, H. Peng*

Angewandte Chemie International Edition 61, e202114612 (2022)

29. Making SOCl2 rechargeable

F. Shen, S. Wang, Y. Gao*

Joule 5 (11), 2766  (2021)

28. Lithium metal anodes working at 60 mA cm-2 and 60 mAh cm-2 through nanoscale lithium-ion adsorbing

L. Ye, M. Liao, X. Cheng, X. Zhou, Y. Zhao, Y. Yang, C. Tang, H. Sun, Y. Gao, B. Wang*, H. Peng*

Angewandte Chemie International Edition 60, 17419 (2021)

Before Fudan

27. Computer-free autonomous navigation and power generation using electro-chemotaxis

M. Wang, Y. Gao, J. Pikul*

Advanced Intelligent Systems 2000255 (2021)

26. A High Throughput Optical Method for Studying Compositional Effects in Electrocatalysts for CO2 Reduction

J. L. Hitt, Y. C. Li, S. Tao, Z. Yan, Y. Gao, S. J. L. Billinge, and T. E. Mallouk*

Nature Communications 12, 1114 (2021)

25. Confining Sulfur in Porous Carbon by Vapor Deposition to Achieve High-Performance Cathode for All-Solid-State Lithium-Sulfur Batteries

A. Alzahrani, M. Otaki, D. Wang, Y. Gao, T. Arthur, S. Liu, D. Wang*

ACS Energy Letters 6 (2), 413–418 (2021)

24. Stable metal anodes enabled by a labile organic molecule bonded to a reduced graphene oxide aerogel

Y Gao, D Wang, S Liu, YK Shin, Z Yan, Z Han, K Wang, MJ Hossain, S Shen, A AlZahrani, ACT van Duin, T Mallouk, D Wang*

Proceedings of the National Academy of Sciences 117 (48), 30135-30141 (2020)

23. Low-temperature and high-rate-charging lithium metal batteries enabled by an electrochemically active monolayer-regulated interface

Y Gao, T Rojas, K Wang, S Liu, D Wang, T Chen, H Wang, AT Ngo, D Wang*

Nature Energy 5 (7), 534-542 (2020)

22. A new approach to both high safety and high performance of lithium-ion batteries

S Ge, Y Leng, T Liu, RS Longchamps, XG Yang, Y Gao, D Wang, D Wang, CY Wang*

Science Advances 6 (9), eaay7633 (2020)

21. Asymmetric temperature modulation for extreme fast charging of lithium-ion batteries

XG Yang, T Liu, Y Gao, S Ge, Y Leng, D Wang, CY Wang*

Joule 3 (12), 3002-3019 (2020)

20. Supremely elastic gel polymer electrolyte enables a reliable electrode structure for silicon-based anodes

Q Huang, J Song, Y Gao, D Wang, S Liu, S Peng, C Usher, A Goliaszewski, D Wang*

Nature Communications 10 (1), 1-7 (2019)

19. Stable Li metal anode by a polyvinyl alcohol protection layer via modifying solid-electrolyte interphase layer

Y Zhao, D Wang, Y Gao, T Chen, Q Huang, D Wang*

Nano Energy 64, 103893 (2019)

18. Electrokinetic Phenomena Enhanced Lithium‐Ion Transport in Leaky Film for Stable Lithium Metal Anodes

G Li, Z Liu, D Wang, X He, S Liu, Y Gao, A AlZahrani, SH Kim, LQ Chen, D Wang*

Advanced Energy Materials 9 (22), 1900704 (2019)

17. Stable Li metal anode by a hybrid lithium polysulfidophosphate/polymer cross-linking film

Y Zhao, G Li, Y Gao, D Wang, Q Huang, D Wang*

ACS Energy Letters 4 (6), 1271-1278(2019)

16. Polymer–inorganic solid–electrolyte interphase for stable lithium metal batteries under lean electrolyte conditions

Y Gao, Z Yan, JL Gray, X He, D Wang, T Chen, Q Huang, YC Li, H Wang, SH Kim, T Mallouk, D Wang*

Nature Materials 18 (4), 384-389 (2019)

15. Synthesis and understanding of Na11Sn2PSe12 with enhanced ionic conductivity for all-solid-state Na-ion battery

Z Yu, SL Shang, D Wang, YC Li, HP Yennawar, G Li, HT Huang, Y Gao, T Mallouk, ZKLiu, D Wang*

Energy Storage Materials 17, 70-77 (2019)

14. Stable metal battery anodes enabled by polyethylenimine sponge hosts by way of electrokinetic effects

G Li, Z Liu, Q Huang, Y Gao, M Regula, D Wang, LQ Chen, D Wang*

Nature Energy 3 (12), 1076-1083 (2018)

13. Salt‐Based Organic–Inorganic Nanocomposites: Towards A Stable Lithium Metal/Li10GeP2S12 Solid Electrolyte Interface

Y Gao, D Wang, YC Li, Z Yu, TE Mallouk, D Wang*

Angewandte Chemie International Edition 57 (41), 13608-13612 (2018)

12. A quaternary sodium superionic conductor-Na10.8Sn1.9PS11.8

Z Yu, SL Shang, Y Gao, D Wang, X Li, ZK Liu, D Wang*

Nano Energy 47, 325-330 (2018)

11. Self-formed hybrid interphase layer on lithium metal for high-performance lithium–sulfur batteries

G Li, Q Huang, X He, Y Gao, D Wang, SH Kim, D Wang*

ACS Nano 12 (2), 1500-1507 (2018)

10. General method of manipulating formation, composition, and morphology of solid-electrolyte interphases for stable Li-alloy anodes

Y Gao, R Yi, YC Li, J Song, S Chen, Q Huang, TE Mallouk, D Wang*

Journal of the American Chemical Society 139 (48), 17359-17367 (2017)

9. Interfacial chemistry regulation via a skin-grafting strategy enables high-performance lithium-metal batteries

Y Gao, Y Zhao, YC Li, Q Huang, TE Mallouk, D Wang*

Journal of the American Chemical Society 139 (43), 15288-15291(2017)

8. Organosulfide-plasticized solid-electrolyte interphase layer enables stable lithium metal anodes for long-cycle lithium-sulfur batteries

G Li, Y Gao, X He, Q Huang, S Chen, SH Kim, D Wang*

Nature Communications 8 (1), 1-10 (2017)

7. Chitosan nanoparticles based nanovaccines for cancer immunotherapy

PG Chen, ZH Huang, ZY Sun, Y Gao, YF Liu, L Shi, YX Chen, YF Zhao, YM Li*

Pure and Applied Chemistry 89 (7), 931-939 (2017)

6. High capacity of lithium-sulfur batteries at low electrolyte/sulfur ratio enabled by an organosulfide containing electrolyte

S Chen, Y Gao, Z Yu, ML Gordin, J Song, D Wang*

Nano Energy 31, 418-423 (2017)

5. Scalable process for application of stabilized lithium metal powder in Li-ion batteries

G Ai, Z Wang, H Zhao, W Mao, Y Fu, R Yi, Y Gao, V Battaglia, D Wang, S Lopatin, G Liu*

Journal of Power Sources 309, 33-41 (2016)

4. Functional organosulfide electrolyte promotes an alternate reaction pathway to achieve high performance in lithium–sulfur batteries

S Chen, F Dai, ML Gordin, Z Yu, Y Gao, J Song, D Wang*

Angewandte Chemie International Edition 55 (13), 4231-4235 (2016)

3. Glycopeptide nanoconjugates based on multilayer self-assembly as an antitumor vaccine

YF Liu, ZY Sun, PG Chen, ZH Huang, Y Gao, L Shi, YF Zhao, YX Chen, YM Li*

Bioconjugate Chemistry 26 (8), 1439-1442 (2015)

2. Covalent bond or noncovalent bond: a supramolecular strategy for the construction of chemically synthesized vaccines

Y Gao, ZY Sun, ZH Huang, PG Chen, YX Chen, YF Zhao, YM Li*

Chemistry–A European Journal 20 (42), 13541-13546 (2014)

1. Strategy for designing a synthetic tumor vaccine: Multi-component, multivalency and antigen modification

ZH Huang, ZY Sun, Y Gao, PG Chen, YF Liu, YX Chen, YM Li*

Vaccines 2 (3), 549-562 (2014)