团队简介

目标使命:纤维素基多极结构材料的物理加工与绿色智造

行业领域:环境与能源材料

科研理念:注重材料性能、综合成本与环境生态友好的兼顾

      主要从事非粮农林生物质物理可塑性加工及其多级结构的微观调控机理、方法等研究,开发新兴的生态安全友好的膜、人造纤维、泡沫弹性体及板材的关键制备理论与技术,推动其在生态降解、纺织包装、保温降噪、发热与制冷、过滤与净化、绿色能源等关键材料领域的应用,旨在推进有望满足工业规模化实际应用和减碳减排的核心需求。我们将鼓励以更健康、更清洁、更低碳的技术路径积极应对现代工业、生活中的科技挑战,并为我们的未来提供可持续的科学发展策略。

     已在国际高质量期刊Small, Energy & Environmental Science, Advanced Materials, Nano Energy, Advanced Science, Advanced Functional Materials, Applied Catalysis B: Environmental等发表高水平论文70余篇,科研成果多次被麻省理工科技评论、网易等专题报道。指导学生荣获“挑战杯”全国大学生课外学术科技作品竞赛省赛(特等奖)、荣获中国“互联网+”大学生创新创业大赛决赛(铜奖)、中国“互联网+”大学生创新创业大赛广东省分赛高教主赛道决赛(金奖)等.  荣获IAAM杰出科学家奖、广东省首批专项“特支计划”科技创新青年拔尖人才(新材料领域)、广东省高等学校百千人才工程培养对象等人才称号.

      与浙江大学、华中科技大学、南方科技大学、美国东北大学、美国马里兰大学、英国曼切斯特大学、德国汉诺威大学、澳大利亚昆士兰大学、澳门大学、亚洲理工学院等境外高水平大学长期开展联合研究. 

      主持国家自然科学基金青年基金、广东省重点领域研发计划(子课题)、广东省自然科学基金项目、广东省粤港澳联合创新领域项目、广州市国际科技合作重大专项等多项。与多家企业开展长期产学研合作,多项科研成果实现批量化.


Mainly engaged in soluble processing of agricultural and forestry biomass cellulose, micro-nano structure control and functional composite structure design, developing emerging low-carbon green environmental and energy material key technologies, and promoting its application in biodegradable film materials, building insulation and noise reduction materials, ionic electronic conductors, heating and cooling, filtration and purification, clean wet and thermal energy and other key fields. It aims to promote the core needs that are expected to meet the practical application and carbon reduction of industrial scale. We will encourage a healthier, cleaner and lower carbon technology path to actively respond to the scientific and technological challenges in modern industry and life, and provide sustainable scientific development strategies for our future. At present, it has carried out long-term joint research with Zhejiang University, Huazhong University of Science and Technology, Southern University of Science and Technology, Northeastern University, University of Maryland, University of Manchester, University of Hannover, University of Queensland, University of Macau, Asian Institute of Technology and other high-level overseas universities.


研究兴趣与方向:

Research Interest

- 农林生物质纤维素可溶性加工与组装策略

   Agricultural/forestry dissolution processing

- 离子电子纳米流体传输结构设计

   Agricultural/forestry-derived biodegradable materials

- 生物基功能结构设计与材料创制

   Design and functional creation of biological carbon-based functional template

多功能材料技术集成与工程化

   Multifunctional technology integration and engineering




个人简介

Individual Resume 

- 19798月出生于中国江西省鄱阳县

  He was born in Poyang County, Jiangxi Province, China, on August 1979.

- 2002年在中南林业科技大学获得木材科学与工程学士学位

 He graduated from Central South University of Forestry Science and Technology in 2002 with 

  a bachelor's degree in Wood Science and Engineering.

- 2005年在中南林业科技大学获得木材科学与技术硕士学位

 From Central South University of Forestry and Technology, he earned a master's degree in          Wood Science and Technology in 2005.

- 2008年在华南理工大学获得制浆造纸工程博士学位

 He received a Ph.D degree in Pulp&Papermaking Engineering from South China Uniersity of      Technology in 2008.

- 自2008年起在华南理工大学留校工作,在轻工科学与工程学院从事教学与科研工作至今

  He began working as a teacher as well as researcher in the School of Light Industry Science       and Engineering in 2008 after earning his PhD from South China University of Technology.



学术活动与荣誉

Awards and Academic Events 

- 2022 年  荣获具有世界影响力的非营利性国际先进材料协会(International Association of Advanced Materials, IAAM) IAAM杰出科学家奖(IAAM Scientist Award)”,以表彰其在可持续先进材料科学、工程和新能源技术方面的杰出贡献.  瑞典

He win the IAAM Scientist Award prize from the International Association of Advanced Materials (IAAM), a non-profit organization with worldwide influence, due to his outstanding contributions to sustainable advanced materials science, engineering and new energy technologies. Finland.

- 2021 年当选材料科学、工程和技术国际Vebleo会士,Vebleo委员会委员,新加坡

He was selected as a Vebleo Fellow and a committee member for the Vebleo webinar in Singapore on materials science, engineering, and technology.

- 2020年当选国际先进材料协会(IAAM)会士.

In the Webinar on Materials Science, Engineering and Technology at the International  Association of Advanced Materials (IAAM), he was selected as a IAAM Fellow and received the IAAM Scientist Award in 2022.

- 2016年 南京市创新创业领军人才计划

He was awarded to a Nanjing Innovation and Entrepreneurship Leading Talents Program, in Jiangsu Province, China.

- 2015年 广东省首批专项“特支计划”科技创新青年拔尖人才(新材料领域)

He received recognition as one of the First Batch of Young Top Talents in the   Guangdong Province Special Support Plan for Scientific and Technological   Innovation  (New Materials Field).

- 2014年 广东省高等学校 百千人才工程培养对象

He was elected for the Guangdong Province, China, Hundreds of Thousands of Talents Project of Institutions of Higher Learning's Training Objects.


其他学术与社会活动:

Other academic activities

-  - 国家、省、市科技计划项目评审及国际知名期刊论文函评专家

      Served as the project's evaluation expert for the national, provincial, and  municipal science      and technology plans, he had also reviewed more than100 articles for prestigious publications on famous Journals such as AM, EES, AFM, JMAC, NE, and CST.

-  - 2022年 国际仿生工程学会会员

     He is invited as as a Member of the International Society of Bionic Engineering

- 2020年 中国复合材料学会青年工作委员会委员、中国复合材料学会高级会员

   He served as a Premium Member in 2019 and was appointed to the China   Composites Society's Youth Working Committee.

- 2018年 汽车表面材料产业技术创新联盟技术委员会小组成员

 He was selected as a member of the Automotive Surface Materials Industry Technology Innovation Alliance's Technical Committee.

-  英国RSC会员、美国ACS会员、美国TAPPI会员等

  In the US and the UK, he received memberships in the RSC, ACS, and TAPPI.

-  广东省质量技术监督局评审专家

  He was an evaluation expert for the Guangdong Provincial Bureau of Quality and   Technical Supervision.

-  广东省科技金融产业创新联盟专家组成员

       He worked as a member of the Guangdong Science and Technology Finance Industry   Innovation Alliance expert group.

-  地级市人民政府企业创新创业发展专家成员

  His selection to the Local municipal People's Government Expert Committee on Enterprise Innovation and Entrepreneurship

- 清远市化工专业专业技术资格评审委员会评委专家

   He was selected as the Qingyuan Chemical Industry professional technical Qualification Assessment Committee judge expert



学术会议活动

Synergistic activities 

- 20238月 邀请学术报告,中国化学会第三届全国纤维素学术研讨会,在分会做木材离子导体结构设计及其在水伏能源收集、固态电芬顿技术中的应用初探学术报告,2023年88日至811日在贵阳召开.

Invitation for Academic Presentation in August 2023 - 3rd National Cellulose Academic Symposium of the Chinese Chemical Society. I will be delivering a presentation titled Exploration of Wood-Ionic Conductor Structure Design and Its Application in Water Energy Harvesting and Solid-State Electro-Fenton Technology in the sub-session. The symposium will take place from August 8th to August 11th, 2023 in Guiyang, China..

- 20236月 邀请学术报告,2023年国际纸页物理会议(International Paper Physics Conference 2023,IPPC2023),在分会做”Cellulose Dissolution for Sustainable Nanocellulose, Paper and Wood Materials“学术报告,2023年531日至62日在华南理工大学五山校区.

As an Invited speaker, he will give a tentative speech entitled “Cellulose Dissolution for Sustainable Nanocellulose, Paper and Wood Materials”, on International Paper Physics Conference 2023 (IPPC2023),  May 31 to June 2, 2023 at the Wushan Campus of South China University of Technology, Guangzhou City.


- 2023年 邀请学术报告,澳門大學應用物理及材料工程研究院,中国澳门(横琴校区). 

As an Invited speaker, he will give a tentative speech entitled “Sustainable Useful Hygroelectric Energy and Catalysis”, on Institute of Applied Physics and Materials Engineering at the University of Macau, in Macau, China.


- 2022年 邀请学术报告,组委会成员,全国电子信息材料与器件会议是一个关于电子信息材料     和未来的科学家论坛,中国厦门. 

The National Conference on electronic information materials and devices is a Scientist Forum on electronic information materials and the future, and it will be held in Xiamen, China. He was invited to give a speech and am also a member of the organizing committee, presenting a tentative speech entitled" Sustainable Wood Cellulose Materials for Flexible Electronics."

- 2022年 邀请学术报告人,题目为 Sustainable Useful Hygroelectric Energy and Catalysis from Ambient Air and Water by Ionic Woods,2022年国际能源化学和工程大会(ICECE-2022),中国西安. 

As an Invited speaker, he will give a speech entitled “Sustainable Useful Hygroelectric Energy and Catalysis from Ambient Air and Water by Ionic Woods”, on International Congress on Energy Chemistry and Engineering 2022 (ICECE-2022), in Xi’an city, China.

- 2022年 特邀演讲人,演讲题目为 Sustainable Wood Cellulose Technologies for Emerging Applications,世界生物技术产业大会(WBC-2022),将于20221019-21在韩国首尔举行. 

As an invited speaker, he will give a tentative speech at the World Biotechnology Industry Conference (WBC-2022), which will take place in Seoul, South Korea, from October 19–21, 2022, with the working title Sustainable Wood Cellulose Technologies for Emerging Applications.

- 2021 邀请学术报告, Sustainable Wood Cellulose Materials by Controllable Surface Engineering Technology,第三届纳米纤维素材料国际研讨会,中国广州. 

As Oral speaker, he had a presentation of lecture reports entitled “Sustainable Wood Cellulose Materials by Controllable Surface Engineering Technology”, 3rd International Symposium on Nanocellulosic Materials, Guangzhou, China.

 - 2021年国际Vebleo主旨演讲,木材衍生的功能性生物复合材料,柔性电子和能源设备。从微米级到纳米级,科学、工程和技术网络研讨会. 

As a Keynote talk speaker, he has reported a lecture entitled “Wood-derived functional biocomposites, flexible electronics and energy devices: From micron to nanoscale”, Vebleo Webinar on Science, Engineering and Technology, Singapore.

 - 2019年特邀讲座报告,纸基信息功能材料和能源器件 ,华中科技大学(HUST),由光电学院陶光明教授邀请,201912月,湖北武汉. 

Huazhong University of Science and Technology (HUST) invited him to deliver a lecture on Paper based information functional materials and energy devices, organized by Prof. Guangming Tao in the School of Optoelectronics, December 2019.

 - 2018年特邀演讲,Natural Wood Fibrous Composite Materials: From Micron to Nanoscale,粤港澳大湾区物理学会联合年会,中国澳门. 

As an Invited speaker, he gave a speech entitled “Natural Wood Fibrous Composite Materials: From Micron to Nanoscale”, Joint Annual Conference of Physical Societies in Guangdong-Hong Kong-Macao Greater Bay Area, Macao, China.

- 2018年 特邀报告人,Natural Wood Composite Materials.  第11届亚澳复合材料会议,澳大利亚,凯恩斯. 

As an Invited speaker, he has reported a lecture entitled “Natural Wood Derived Materials with Multi-functionalization. 11th Asian-Australasian Conference on Composite Materials”, Austria, Cairns.

 - 2017年 特邀报告人,Functionalization of Natural Wood Fiber Toward Highly Transparent Nanofibrous Paper第八届先进纤维和聚合物材料国际会议,中国,上海. 

As an Invited speaker, he delivered a speech entitled “Functionalization of Natural Wood Fiber Toward Highly Transparent Nanofibrous Paper”, 8th International Conference on Advanced Fibers and Polymer Materials, China, Shanghai.

 - 2017年 特邀发言人,天然木纤维复合材料的制备、结构、性能。从微米级到纳米级,第三届中国国际复合材料大会,中国,杭州. 

As a guest speaker, he had delivered a speech entitled “Preparation, Structures, Properties of Natural Wood Fibrous Composite Materials: From Micron to Nanoscale”, The 3rd China International Congress on Composite Materials, China, Hangzhou.

 - 2012年 受邀担任Curr. Org. Org. Chem. 客座编辑,并主持出版了 Lignocelluloses Purification and Modifications for Natural Products 专刊,共有13篇高质量的SCI论文,由KTH、The University of Florida等众多业内权威专家撰写. 

Served as a Guest editor for Journal of “Curr. Org. Chem.” and chaired the publication of the special issue “Lignocelluloses Purification and Modifications for Natural Products”, totally 13 high-quality SCI articles written by many authoritative experts in the industry, such as KTH, The University of Florida.


研究兴趣与领域

Research interests and fields

1. 可持续生物质基环境可降解材料

Sustainable biomass-derived cellulosic materials

与不可再生的传统石化资源相比,自然界广泛存在的可再生农林生物质资源(如纤维素、农业秸秆、竹材等)是地球上最丰富的可持续利用的自然资源,具有生物可降解性和可再生性,且在石化替代方面具有减碳减排效应,助力碳中和、碳达峰长远战略。我们致力于创新发展农林生物质组分与结构的可控溶解加工等方法,开发可降解环境材料(包括纳米纤维素、纤维素纸膜、泡沫木材、木材气凝胶、健康板材等),特别值得注意的是,我们更加关注开发清洁和绿色的制备方法与工程化技术,以可行的技术措施推动大规模生产,使其具有成本效益和市场竞争力。在这里,我们对创造可持续的生态健康材料感兴趣,这些材料能够真正帮助我们人居的生活环境变得更加安全、绿色、低碳和健康。

Compared with non-renewable traditional petrochemical resources, widely existing renewable agricultural and forestry biomass resources (such as cellulose, agricultural straw, bamboo, etc.) are the most abundant sustainable natural resources on earth. They are biodegradable and renewable, and have carbon reduction and emission reduction effect in petrochemical substitution, which contributes to the long-term strategy of carbon neutralization and carbon peak. We are committed to the innovative development of controlled dissolution processing methods of agricultural and forestry biomass components and structures, and the development of degradable environmental materials (including nanocellulose, cellulose paper film, foam wood, wood aerogel, health boards, etc.). In particular, we pay more attention to the development of clean and green preparation methods and engineering technologies. Promote mass production with feasible technical measures to make it cost-effective and competitive in the market. Here, we are interested in creating sustainable ecologically healthy materials that can really help make our living environment safer, greener, low-carbon and healthy.


                Figure 1. Sustainable biomass-derived cellulosic materials


2. 绿色离子电子输运结构

Structure design for green Ionotronics transport 

大多数生物基木本或草本含有丰富的垂直排列的自上而下的微孔道结构,有助于推动氧气、水分子、电子和离子的高效率输运。我们致力于农林生物质生物结构及其可溶性制备策略,通过表面操纵技术构筑绿色离子、电子输运结构,积极探索其在绿色电子、绿色催化、绿色能源。以环境污染控制为例,我们利用多孔性天然木材连续贯穿的多孔结构优势,通过光聚合及冷冻盐析技术在腔壁表面构筑快速离子、O2及水分子输运结构,不仅可替代传统液态电解质和昂贵的离子交换膜,构建新型的固态电芬顿策略,持续高效生成高浓度H2O2强氧化性OH•(氧化还原电位~2.8 V),其能快速分解绝大多数的水体、气态有机污染物与病毒、细菌等有机质,并生成无毒害产物。此外,我们还通过对天然木材胞腔壁表面纤维素可溶性策略制备高强度木材气凝胶,并通过可控的冷冻盐析促使在胞腔壁表面构筑一层类蜘蛛网状的Li+和水分子快速运输结构, 能够自发高效呼吸空气水分子充放电,在湿气产电能力及其稳定性、充放电方面取得了突破。另外,我们还利用纤维素纸表面打印一层双功能离子-电子输运结构,构筑一种全印刷的柔性纸制湿热发电机,依靠环境湿气和废热协同混合产湿热能源。在在普通的湿热环境下,它在普通的湿热环境中,它产生了非常规的湿热电输出模式,并相比传统热电显示出几乎十几倍的增长。出现的湿热发电从周围的湿热资源中获取的战略提供了一种为下一代混合能源提供了革命性的方法,为下一代混合能源提供了成本效益、灵活性和可持续性,并实现了大规模的卷对卷生产。

Most biobase trees or herbs contain abundant vertically arranged top-down microchannel structures that help drive efficient transport of oxygen, water molecules, electrons, and ions. We are committed to the structure of agricultural and forestry biomass and its soluble preparation strategy, construct green ion and electron transport structure through surface manipulation technology, and actively explore its role in green electronics, green catalysis, green energy. Taking environmental pollution control as an example, we take advantage of the porous structure of porous natural wood, and construct rapid ion, O2 and water molecule transport structures on the surface of the cavity wall through photopolymerization and frozen salting out technology, which can not only replace the traditional liquid electrolyte and expensive ion exchange membrane, but also construct a new solid-state electric Fenton strategy. High concentration H2O2 and strong oxidizing OH• (REDOX potential ~ 2.8V) are continuously and efficiently generated, which can quickly decompose most of the water, gaseous organic pollutants, viruses, bacteria and other organic matter, and generate non-toxic products. In addition, we also prepared high-strength wood aerogel through the soluble strategy of cellulose on the surface of natural wood cell wall, and constructed a spider-like network of Li+ and water molecule rapid transport structure on the surface of cell wall through controlled frozen salting out, which could spontaneously and efficiently breathe air and water molecule charge and discharge. A breakthrough has been made in electricity generating capacity, stability, charging and discharging of moisture gas. In addition, we also use cellulose paper to print a layer of dual-function ion-electron transport structure to construct a fully printed flexible paper damp-heat generator, which relies on the collaborative mixing of environmental moisture and waste heat to produce damp-heat energy. In ordinary humid and thermal environments, it produces an unconventional mode of humid and thermal electrical output, and shows an increase of almost ten times compared to conventional thermoelectricity. The emerging strategy of generating wet heat from surrounding wet heat resources offers a revolutionary approach to the next generation of hybrid energy, providing cost effectiveness, flexibility and sustainability, and enabling large-scale roll-to-roll production. 

               Figure 2 Green Ionotronics transport for electrochemistry and hygroelectricity