Dr Weizhai (Frank) BAO      

Distinguished Professor, School of Chemistry and Materials Science; Nanjing University of Information Science & Technology

OFFICE: Yifu Building, Room S103

Address: No.219, Ning Liu Road, Nanjing, Jiangsu Province

P: +18013849865

E: baoweizhai@@gmail.com; weizhai.bao@@nuist.edu.cn; baoweizhai6@@foxmail.com (Del~one @~)

Google Scholar: https://scholar.google.com/citations?user=_ub1fEUAAAAJ&hl=en&oi=ao

Publons: https://publons.com/researcher/4200135/weizhai-bao/

Orcid ID: htLtps://orcid.org/0000-0002-8779-643X

Researchgate :https://www.researchgate.net/profile/Weizhai_Bao

LinkedIn : //www.linkedin.com/in/weizhai-bao-7877bab7/

个人主页：https://www.x-mol.com/people/baoweizhai

Personal Review

Dr Weizhai BAO joined NUIST in 2020 as Distinguished Professor in School of Chemistry and Materials Science.  he received a Doctor of Science (D.Sc.) degree in Materials Engineering  from University of Technology Sydney (UTS) in 2019 (Full scholarship supported by Australian Renewable Energy Agency and rewarded the scholarship for international students funded by China Scholarship Council (Bonus AUD 8500, only two winners from UTS in 2019), and continued to engage as a postdoc research fellow for one year in the same research institute under the supervisor of Distinguished Professor Guoxiu Wang with more than 40 000 citations, a famous expert in energy storage materials. In 2018, he visited Drexel University in Philadelphia, US for 1 years in Professor Yury Gogotsi’s group, who is the inventor of two-dimensional layered ceramic material (MXene) with more than 60 000 citations, and he is also the associate editor of ACS Nano ( one of the top journal in the field of energy and nano materials science).

I has published or accepted more  57 refereed journal papers (12 papers as 1st author) in the prestige journals with high impact factors. Google Scholar: cited 4500, H-index: 18, i10-index: 20 ; Chinese invention patent : 6 (authorized). A series of breakthrough research results were published in the top journals of the field as the first author, and have been widely recognized by international peers, such as (Advanced Energy Materials, 2017, 8, 1870060-1870068 (impact factor : 25.25; cited 101 times, cover paper); Advanced Functional Materials, 2016, 268746-8752; (impact factor : 16.83, cited 94 times) ; Advanced Materials, 20191902393-1902399 (impact factor : 27.41); ACS Nano, 2019, 13, 10, 11500 – 11509 (impact factor : 14.58)) ; 2 paper in Journal of Power Sources (impact factor : 8.25 ) ; Chemistry – a European Journal, 2017, 23. The energy density of the finished battery is as high as 400 Wh/kg, which has great commercial application prospect.(Figure 1 Large scale company level commercial products) The results of our project are very cutting-edged. It is of great significance to guide and promote the development of new energy materials and devices in Australia. To ensure that Australia's new energy technology will continue to be at the forefront of the world.

MXene material is a kind of metal carbide and metal nitride material with two-dimensional layered structure. Its shape is similar to graphene. It is a very popular functional material with ultra-high electronic conductivity and abundant surface functional groups. It has a broad application prospect in the field of energy (Nature 557.7705 (2018): 409-412.). My research activities involve the design, investigation and development of novel MXene nanostructured materials for advanced energy storage applications.

I obtained my Bachelor's degree and master's degree from Central South University (985 top universities；Double first class universities；Double first class Majors) in 2011 and 2014 (first class), a top university in the field of energy and metallurgy technology among the world. During my master study (Full Scholarship), I published 5 peer-referred papers and win the Postgraduate National Scholarship in 2013 (top 3/100 competitors ; Bonus RMB 20 000) ; “XIAN DAO” Scholarship in 2012 (Bonus RMB 5 000 ) and Hunan Province “Outstanding Graduate Student” (only 20 winner in whole univeristy in 2014 ; Bonus RMB 3 000 ) .

Three scientists who invented lithium-ion batteries won the Nobel Prize in chemistry in 2019,which makes lithium-ion battery and energy storage & conversion become a hot research topic in the world again. Currently, my original research related to advanced energy storage and conversion, including rechargeable lithium-ion, lithium-sulfur, sodium-sulfur, potassium- sulfur batteries, supercapacitors, and capacitive deionization. Especially, I am a pioneer in the study of advanced energy storage using two-dimensional layered ceramic material (MXene). 

As the researcher team leader, I has undertaken the research project of cathode materials for lithium sulfur batteries of Australian Renewable Energy Agency (ARENA 2014/RND106, AUD 1.0 million) for Electric Vehicle, which is a a global recognition hot high-tech new energy industry. lithium-sulfur batteries (Li-S) have been considered as one of the most promising systems for next generation of high-energy rechargeable lithium batteries because of their high theoretical specific capacity (~1680 mAh g^-1) and energy density (2600 Wh kg^-1). During the project, I have successfully developed a foldable Li-S pouch full cell with excellent cycle performance by using high-performance MXene material as the skeleton material.

Figure 1. Cover page pubulished for Advanced Energy Materials (2017, 8, 1870060-1870068 (impact factor : 25.25; cited 130 times, ESI Highly Cited Papers); (left) ; Foldable pouch Li-S full cells (size 25 × 25 cm) using MXene/Sulfur composite cathode for Electric Vehicle (ARENA 2014/RND106)(right)

During my postdoc research periode, I engaged in the project from Rail Manufacturing Cooperative Research Centre (RMCRC) named ‘ Hybrid supercapacitors with high energy and power densities for rail industry applications’ (AUD 1.0 million) which can apply to energy storage system in the new generation of Metro Trains in Australia. I am responsible for the research and development of anode materials for hybrid supercapacitors. In depth cooperation with HEC Industrial Development Co., Ltd. (HEC Group,the world's top 500 companies) and Rail Manufacturing Cooperative Research Centre (RMCRC), we have successfully developed a hybrid supercapacitors with an energy density of 50 Wh/kg (75% higher than the traditional product). The large-scale product will be available in 2021.

At the same time, I carried out research on controllable assembly and regulation of surface and interface properties technology of MXene based functional materials for commercial application in energy storage industry. I organized and established Australia's first MXene material research team and filled the gap in the field of MXene materials in Australian academic circles, and led the Australian team to take the lead in reporting the effective improvement of lithium-sulfur battery by using MXene based composite materials. A series of breakthrough research results were published in the top journals of the field as the first author, and have been widely recognized by international peers, such as (Advanced Energy Materials, 2017, 8, 1870060-1870068 (impact factor : 25.25; cited 101 times, cover paper); Advanced Functional Materials, 2016, 268746-8752; (impact factor : 16.83, cited 94 times) ; Advanced Materials, 20191902393-1902399 (impact factor : 27.41); ACS Nano, 2019, 13, 10, 11500 – 11509 (impact factor : 14.58)) ; 2 paper in Journal of Power Sources (impact factor : 8.25 ) ; Chemistry – a European Journal, 2017, 23. Because of my high research performance in the research field of MXene, I got the opportunity to visit Professor Yury Gogotsi’s group, I designed and prepared the capacitive deionization (CDI) device with aerogel porous MXene as carrier, working with the American team. The device exhibited excellent performance in high solution salinity, which could provide extremely high electrical adsorption capacity, at very high concentration of brine (10000 A high adsorption capacity of 118 mg / cm² can be obtained, which is an order of magnitude higher than that of traditional carbon based electrode materials. Porous mxene CDI devices significantly improve the adsorption efficiency of CDI technology, making the development of CDI technology enter a new stage of industrial scale seawater desalination. The relevant achievements were published in Joule (2018, 2778-787; impact factor : 27.03) and have been cited for 60 times (Figure 2).

代表性论文（# -co-first，*-Corresponding ，PDF-contact: weizhai.bao@nuist.edu.cn）

[57] Bao, W.*, H Shen, C Qian, D Cui, J Xia,F Yu, H Liu, C Guo, J Li,* K Sun* Rejuvenating manganese-based rechargeable batteries: fundamentals, status and promise Journal of Materials Chemistry A 2024 恭喜慎浩（研一，学生一作）、诚飞（国家电网），丁宇（大三），靖杰（大三），感谢于峰教授、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW)

[56] Bao, W.*, R Wang, C Qian, H Shen, F Yu, H Liu, C Guo, J Li,* K Sun*.Light‐Assisted Lithium Metal Anode Enabled by In Situ Photoelectrochemical Engineering Small  2024 20 (9), 2307179 恭喜镕浩(学生一作)、诚飞（学生一作）、恭喜慎浩（研一，学生一作），感谢于峰教授、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW) 

[55]  Bao, W.*, Shen H, Qian, C., Wang, R.,  Cui, D,.  Xia J.,  Liu, H., Guo, C., Yu, F.,  Li,  J., Sun, K. Photo-assisted rechargeable batteries: principles, performance, and development. Journal of Materials Chemistry A. 2023 11 (35), 18605-18625 恭喜慎浩（研一，学生一作）、镕浩(中科大读博)、诚飞，丁宇，靖杰，感谢于峰教授、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW)

[54] Qian, C., Wang, R., Sun, K., Liu, H., Guo, C., Yu, F.,  Li,  J. Bao,W.*,Computational-Guided Design of Photoelectrode Active Materials for Light-assisted Energy Storage. Small 2023 2304045. 恭喜诚飞、镕浩(中科大读博)、感谢于峰老师、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW)  (Invited contribution, 邀稿)

[53] Si, R., Yi, S., Liu, H., Yu, F., Bao, W., Guo, C*., & Li, J. Engineering Oxygen Vacancies on VO2 multilayered Structures for Efficient Zn2+ Storage. Chemistry–A European Journal, e202300409. 2023, 恭喜司锐、感谢于峰教授、郭聪教授、刘鹤教授、李敬发教授

[52] Li, L., Wang, Y., Meng, J., Shen, N., Liu, H., Guo, C.,Bao, W., Li, J., Yu, F.*  Boosting the capacitance of MOF-derived carbon-based supercapacitors by redox-active bromide ions. Chemical Engineering Journal Advances 2023 14, 100484.恭喜立德(研一、一作)、王毅（研二）、申楠（研二），感谢于峰教授、郭聪教授、刘鹤教授、李敬发教授

[51] Liu, H., Wu, P., Wang, R., Meng, H., Zhang, Y., Bao, W. Li, J.*  2023. A Photo-rechargeable Aqueous Zinc–Tellurium Battery Enabled by the Janus-Jointed Perovskite/Te Photocathode. ACS nano 2023 17 (2), 1560–1569. 恭喜红敏(学生一作，读博)、攀坤（研二）、镕浩，雅琪（研一），感谢李敬发教授

[50]  Wang, R., Qian, C., Zhang, Z.,  Shen, H,. Xia,J.,  Cui,D.,  Guo, C., Yu, F., Liu, H.,  Li, J.  Sun, K., Bao, W.*, Advance of Prussian Blue-Derived Nanohybrids in Energy Storage: Current Status and Perspective. Small 2023 https://doi.org/10.1002/smll.202206848.   恭喜镕浩(学生一作)、诚飞（学生一作）、浙锐（学生一作,上大读研），慎浩（研一），靖杰（大二）、丁宇（大二），感谢于峰老师、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW) 

[49] Bao, W.*, Wang, R., Sun, K., Qian, C., Li, M,. Liu, H., Guo, C., Yu, F., Li, J.* Photoassisted  High-Performance Lithium Anode Enabled by Oriented Crystal Planes. ACS nano 2022 16, 10, 17454-17465.https://doi.org/10.1021/acsnano.2c08684. 恭喜镕浩(学生一作)、诚飞（研一）、沐函（大三）、感谢于峰老师、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW) 

[48] Yi, S., Si, R., Su, Y., Bao, W., Guo, C.*,  Li, J. ZnTe/rGO composite as the Fully‐Zinced Conversion‐Type Cathodes for Aqueous Zinc Ion Batteries. Chemistry-A European Journal 2023 29(12) e202203339. 恭喜善君(学生一作)、司锐、郭聪教授、李敬发教授 

[47] Wang, R., Liu, H., Zhang, Y., Sun, K., Bao, W.* Integrated Photovoltaic Charging and Energy Storage Systems: Mechanism, Optimization, and Future. Small, 2022 , 2203014. 恭喜镕浩（一作）、红敏、宇豪（保研上硅所）、Prof. Kaiwen Sun (UNSW)，期刊热点论文，国际顶级光伏杂志PV magazine专题报道，南信大首篇。

[46] Cui, D., Wang, R., Qian, C., Shen, H., Xia, J., Sun, K., Liu, H., Guo, C., Li, J., Yu, F. and Bao, W.* 2023. Achieving High Performance Electrode for Energy Storage with Advanced Prussian Blue-Drived Nanocomposites-A Review. Materials, 16(4), p.1430. 恭喜丁宇（学生一作,大二）,镕浩(学生一作)、诚飞（学生一作），慎浩（研一），靖杰（大二），感谢于峰老师、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW)  (Invited contribution, 邀稿)

[45] Bao, W.*, Wang, R., Sun, K., Qian, C., Zhang, Y.,  Li, J.* Interface Crystallographic Optimization of Crystal Plane for Stable Metallic Lithium Anode. ACS Applied Materials & Interfaces. 2022, 14 (33), 38696-38705. 恭喜镕浩（学生一作） 诚飞（研一），宇豪（保研），感谢李敬发 教授、Prof. Kaiwen Sun  (UNSW)

[44] Liu, H., Sun, X., Cheng, X.B., Guo, C., Yu, F., Bao, W., Wang, T., Li, J. and Zhang, Q.,. Working Principles of Lithium Metal Anode in Pouch Cells. Advanced Energy Materials, 2022, p.2202518. 恭喜刘鹤 教授、孙鑫（研一、学生一作）、于峰 教授、郭聪 教授、感谢李敬发 教授、程新兵 教授（东南大学）、张强 教授（清华大学）

[43] Xia, J.,#  Wang, R.,# Qian, C., # Sun, K., Liu, H., Guo, C., Yu, F.,  Li,  J. Bao,W.*, Superca pacitors of Nanocrystalline Covalent Organic Frameworks. Crystal 2022 12(10) 1350. 恭喜靖杰(大一、一作)、镕浩（共一）、诚飞（共一、研一）、感谢于峰教授、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW) (Invited contribution, 邀稿)

[42] Wang, R., Sun, K., Liu, H., Qian, C., Li, M., Zhang, Y.,  Bao, W.* . Integrating a redox-coupled FeSe2/N-C photoelectrode into potassium ion hybrid capacitors for photoassisted charging. Journal of Materials Chemistry A, 2022. 10 (21)11504-11513.恭喜镕浩（一作）、红敏、诚飞（研一）、沐函（大三）、宇豪（上硅所保研）、Prof. Kaiwen Sun  (UNSW)

[41] Wang, R., Li, M., Sun, K., Zhang, Y., Li, J., Bao, W.*. Element‐Doped MXenes: Mechanism, Synthesis, and Applications. Small, 2022, 2201740 恭喜镕浩（一作）、沐函（大三）、宇豪（保研）、感谢李敬发教授、Prof. Kaiwen Sun (UNSW)

[40] Wang, R., Zhang, Y., Sun, K., Qian, C. Bao, W.*. Emerging Green Technologies for Recovery and Reuse of Spent Lithium-ion Batteries-A Review. Journal of Materials Chemistry A. 2022,  10, 17053-17076. 恭喜镕浩（一作）、诚飞（研一）、宇豪（保研）、Prof. Kaiwen Sun (UNSW)

[39] Bao, W.;* Wang R.; Qian C.; J. Li,;* Liu, F. Y.* Stable alkali metal anodes enabled by crystallographic optimization-A review Journal of Materials Chemistry A, 2021 ,9, 20957-20984. 恭喜镕浩（学生一作，研一）、诚飞，感谢李敬发教授、刘芳洋教授（中南大学）

[38] Wang, R., Sun, K., Zhang, Y., Li, B., Qian, C., Li, J., Liu, F. Bao, W.* . Nanoscale interface engineering of inorganic Solid-State electrolytes for High-Performance alkali metal batteries. Journal of Colloid and Interface Science, 2022 621, pp.41-66. 恭喜镕浩（一作）、诚飞（研一）、宇豪（保研）、感谢李敬发教授、刘芳洋教授（中南大学）、Prof. Kaiwen Sun (UNSW)

[37] Bao, W.; Wang R.; Qian C.; Zhang Z.; Wu. R.; Zhang Y.; Li, J.,* Liu, F.* Wang, G*.; Porous heteroatom-doped MXene microspheres enable strong adsorption and encapsulation of sodium polysulfides for long-life room-temperature Na-S Batteries ACS nano 2021, 15 (10), 16207-16217. 恭喜镕浩(学生一作，研一)、诚飞，浙锐、瑞君、宇豪，感谢李敬发教授、刘芳洋教授（中南大学）、Prof. Guoxiu.Wang (UTS)

[36] Bao, W.;# Shuck, C. E.;# Zhang, W.; Guo, X.; Gogotsi, Y.; Wang, G., Boosting Performance of Na-S Batteries Using Sulfur-Doped Ti₃C₂T_x MXene Nanosheets with a Strong Affinity to Sodium Polysulfides. ACS nano 2019, 13, 11500-11509. 感谢 Prof. Chris、 张文雪教授（长安大学）、Dr. Xin Guo (UTS)、Prof. Guoxiu Wang (UTS)、Prof. Gogotsi Yury  (Drexel University )

[35] Wang R.; Zhang Y.; Qian C.; Bao, W.* Dimensional optimization enable high-performance capacitive deionization. J. Mater. Chem. A, 2022 10(12), 6414-6441. 恭喜镕浩（一作）、宇豪（保研）、诚飞（研一）

[34] Li, J.;* Liu, H.; Wang R.; Qian C.; Bao, W.* Dual-Functional Iodine Photoelectrode Enabling High Performance Photo-assistant Rechargeable Lithium Iodine Batteries. Journal of Materials Chemistry A 2022.10(13), 7326-7332. 恭喜红敏（学生一作）、镕浩、诚飞（研一）、李敬发教授

[33] Li, J., Niu, Z., Guo, C., Li, M., Bao, W. Catalyzing the polysulfide conversion for promoting lithium sulfur battery performances: A review. Journal of Energy Chemistry, 2021, 54, 434-451.恭喜志豪（大三）、沐函（大二）、郭老师、李老师,高被引论文（80+）.

[32] Qian C.;Sun K.; Bao, W.* Recent Advance on Machine Learning of MXenes for Energy Storage and Conversion. International Journal of Energy Research, 2022. SCI一区，恭喜诚飞 (一作、研一)、Prof. Kaiwen Sun (UNSW)（入选专题特刊）

[31] Qian, C.,# Wang, R.,# Sun, K., Bao, W.*.  Dimensional engineering of anode materials for high performance potassium ion hybrid capacitor-A review. International Journal of Energy Research. 2022 accepted SCI一区，恭喜诚飞 (一作、研一),镕浩（共一） 、Prof. Kaiwen Sun (UNSW)

[30] Qian, C., # Wang, R.,# Sun, K., Liu, H., Guo, C., Yu, F.,  Li,  J. Bao,W.*, Conductive Covalent Organic Frameworks Meet Micro-Electrical Energy Storage: Mechanism, Synthesis and Applications—A Review. Crystal 2022 12(10) 1405. 、诚飞（共一、研一）、镕浩（共一）、感谢于峰老师、郭聪教授、刘鹤教授、李敬发教授、Prof. Kaiwen Sun (UNSW) (Invited contribution, 邀稿)

[29] Wang, R., Li, M., Zhang, Y., Sun, K.,  Bao, W.* Atomic surface modification strategy of MXene materials for high‐performance metal sulfur batteries. International Journal of Energy Research. 2022, 46 (9) Pages 11659-11675 恭喜镕浩（一作）、沐函（大三）、宇豪（保研） 、Prof. Kaiwen Sun (UNSW)

[28] Yu, F., Wang, Y., Guo, C., Liu, H., Bao, W., Li, J., Zhang, P. and Wang, F. Spinel LiMn2O4 Cathode Materials in Wide Voltage Window: Single-Crystalline versus Polycrystalline. Crystals, 2022, 12(3), p.317. 恭喜王毅（研一，学生一作）、感谢于峰老师、郭聪教授、刘鹤教授、李敬发教授，Prof Zhang, P|、 Prof Wang, F

[27] Xiao, X.,# Wang, H.,# Bao, W.,# Urbankowski, P., Yang, L., Yang, Y., Maleski, K., Cui, L., Billinge, S.J., Wang, G. and Gogotsi, Y., Two‐Dimensional Arrays of Transition Metal Nitride Nanocrystals. Advanced Materials 2019: 31（33）190239. 感谢肖旭教授（电子科技大学）、王昊研究员（南京大学）、Dr. Urbankowski, Prof. Guoxiu Wang (UTS), Prof. Gogotsi, Yury  (Drexel University )

[20] Yang, J., # Bao, W., # Jaumaux, P., Zhang, S., Wang, C., & Wang, G. (2019). MXene‐based composites: synthesis and applications in rechargeable batteries and supercapacitors. Advanced Materials Interfaces, 2019, 6(8), 1802004.高被引论文.感谢杨剑博士、王赪胤教授（扬州大学）、Prof. Guoxiu Wang （高被引）

[18] Bao, W.,# Tang, X.,# Guo, X.,# Choi, S., Wang, C., Gogotsi, Y. and Wang, G., Porous cryo-dried MXene for efficient capacitive deionization. Joule 2018 2(4), pp.778-787. 封面论文，高被引论文. 感谢唐啸教授（青岛大学）、Dr. Guo (UTS)、Dr. Choi（LG Chem）、王赪胤教授（扬州大学）、Prof. Guoxiu Wang（UTS）、 Prof. Gogotsi, Yury (Drexel University )

[17] Bao, W.;# Liu, L.,# Wang, C., Choi, S., Wang, D. and Wang, G., Facile Synthesis of Crumpled Nitrogen‐Doped MXene Nanosheets as a New Sulfur Host for Lithium-Sulfur Batteries. Advanced Energy Materials 2018, 8(13), 1702485. 封面论文，高被引论文.感谢刘琳博士、Dr.Choi（LG Chem)、王赪胤教授（扬州大学）、王丹教授（中科院过程所）、Prof. Guoxiu Wang（UTS）

[16] Bao, W.; Su, D.; Zhang, W.; Guo, X.; Wang, G. 3D Metal Carbide@Mesoporous Carbon Hybrid Architecture as a New Polysulfide Reservoir for Lithium-Sulfur Batteries. Advanced Functional Materials 2016, 26（47）, 8746-8756. 高被引论文，感谢Dr. Xin Guo (UTS)、Dr. Su (UTS)、 张文雪教授（长安大学）、Prof. Guoxiu Wang（UTS）

[13] Bao, W.; X, Xie.; Xu, J.; Guo, X.; J, Song Su, D.; Wang, G. Confine sulfur in 3D flexible hybrid MXene/reduced graphene oxide nanosheets for lithium sulfur battery. Chemistry-A European Journal 2017, 23, 1-8. 感谢解修强教授（湖南大学）、 徐晶教授（郑州大学）、张文雪教授（长安大学）、宋建军（青岛大学）、Prof. Guoxiu Wang（UTS），高被引（150+）

[12] Bao, W.; Mondal, A. K.; Xu, J.; Wang, C.; Su, D.; Wang, G. 3D hybrid-porous carbon derived from carbonization of metal organic frameworks for high performance supercapacitors. Journal of Power Sources 2016, 325, 286-291.

[14] Bao, W.; Zhang, Z.; Zhou, C.; Lai, Y.; Li, J. Multi-walled carbon nanotubes @ mesoporous carbon hybrid nanocomposites from carbonized multi-walled carbon nanotubes@metal-organic framework for lithium sulfur battery. Journal of Power Sources 2014, 248, 570-576. 感谢周成坤博士、张治安教授（中南大学）、赖延清教授（中南大学），李劼教授（中南大学）高被引（100+）

[13] Bao, W.; Zhang, Z.; Chen, W.; Zhou, C.; Lai, Y.; Li, J. Facile synthesis of graphene oxide@mesoporous carbon hybrid nanocomposites for lithium sulfur battery. Electrochimica Acta 2014, 127, 342-348. 感谢陈巍博士、周成坤博士、张治安教授（中南大学）、赖延清教授（中南大学），李劼教授（中南大学）

[12] Bao, W.; Zhang, Z.;Qu, Y.; Zhou, C.;Wang, X.; Li, J. Confine sulfur in mesoporous metal–organic framework@reduced graphene oxide for lithium sulfur battery. Journal of Alloys and Compounds 2014, 582, 334-340.  感谢周成坤博士、王习文教授（湖南大学）、张治安教授（中南大学），李劼教授（中南大学）、高被引（150+）

[11] Bao, W.; Zhang, Z.; Qu, Y.; Zhou, C.; Wang, X.; Li, J. Enhanced cyclability of sulfur cathodes in lithium-sulfur batteries with Na-alginate as a binder. Journal of Energy Chemistry 2013, 22(5), 790-794.感谢周成坤博士、王习文教授（湖南大学）、张治安教授（中南大学），李劼教授（中南大学）

[10] Li, H.; Jin, T.; Chen, X.; Lai, Y.; Zhang, Z., Bao, W.; Jiao, L., Rational Architecture Design Enables Superior Na Storage in Greener NASICON‐Na₄MnV (PO₄)₃ Cathode. Advanced Energy Materials 2018, 8(24), p.1801418.感谢李煌旭博士（City University of Hong Kong）、张治安教授（中南大学），焦立芳教授（南开大学）

[9] Li, H., Zhang, Z., Xu, M., Bao, W., Lai, Y., Zhang, K. and Li, J., 2018. Triclinic Off-Stoichiometric Na_3.12Mn_{2. 44} (P₂O₇)₂/C Cathode Materials for High-Energy/Power Sodium-Ion Batteries. ACS applied materials & interfaces 2018, 10(29), pp.24564-24572.感谢李煌旭博士（City University of Hong Kong）、张治安教授（中南大学）、赖延清教授（中南大学）、李劼教授（中南大学）

[8]Li, H., Chen, X., Jin, T., Bao, W.; Zhang, Z. and Jiao, L., Robust graphene layer modified Na₂MnP₂O₇ as a durable high-rate and high energy cathode for Na-ion batteries. Energy Storage Materials 2019, 16, pp.383-390.感谢李煌旭博士（City University of Hong Kong）、张治安教授（中南大学），焦立芳教授（南开大学）

[7] Shanmukaraj, D., Kretschmer, K., Sahu, T., Bao, W., Rojo, T., Wang, G., & Armand, M. (2018). Highly efficient, cost effective, and safe sodiation agent for high‐performance sodium‐ion batteries. ChemSusChem, 2018, 11(18), 3286-3291. 感谢Dr. D. Shanmukaraj （CIC energiGUNE）、Dr. Katja Kretschmer (TU Braunschweig) , Prof. Guoxiu Wang（UTS）Prof. Michel Armand（CIC energiGUNE）

[6] Guo, X., Li, K., Bao, W., Zhao, Y., Xu, J., Liu, H. and Wang, G., Highly Reversible Lithium Polysulfide Semiliquid Battery with Nitrogen‐Rich Carbon Fiber Electrodes. Energy Technology 2018, 6(2), pp.251-256. 感谢 Dr. Xin Guo (UTS)、李克非博士、Prof. Hao Liu（UTS)、 Prof. Guoxiu Wang（UTS）

[5] Xu, J.; Su, D.;Zhang, W.; Bao, W.; Wang, G. A nitrogen-sulfur co-doped porous graphene matrix as a sulfur immobilizer for high performance lithium-sulfur batteries. J. Mater. Chem. A, 2016, 4, 17381-17393.

[4] Song, J.; Su D, Xie X, Su, D.; Guo, X.; Bao, W.; Wang. Immobilizing Polysulfides with MXene-Functionalized Separators for Stable Lithium–Sulfur Batteries. ACS applied materials & interfaces 2016, 8(43): 29427-29433.

[3] Xu, J.; Su, D.; Bao, W.; Wang, G. Rose flower–like NiCo₂O₄ with hierarchically porous structures for highly reversible lithium storage. Journal of Alloys and Compounds 2016, 684: 691-698.

[2] Chen, W.;Zhang, Z.; Bao, W.; Lai, Y.;Li, J.;Gan, Y.; Wang, J. Hierarchical mesoporous γ-Fe₂O₃/carbon nanocomposites derived from metal organic frameworks as a cathode electrocatalyst for rechargeable Li-O₂ batteries. Electrochimica Acta 2014, 134, 293-301

[1] Zhang, Z.; Bao, W.; Chen, W.;Zhou, C.;Lai, Y.; Li. Water-soluble polyacrylic acid as a binder for sulfur cathode in lithium–sulfur battery. ECS Electrochemistry Letters, 2012, 1(2), pp.A34-A37. (本人学生第一作者，研一)、 感谢张治安教授