專家信息：

唐群委，男，1980年8月生于山東濰坊，中國海洋大學材料科學與工程研究院教授，博士生導師，“青年英才工程”第一層次。

教育及工作經歷：

2012.8-今，中國海洋大學材料科學與工程研究院教授、博導。

2011.7-2012.7，美國南卡羅萊納大學博士后。

2010.9-2011.7，華僑大學訪問學者。

2009.9-2010.8，法國斯特拉斯堡大學博士后。

2004.9-2009.6，華僑大學工學博士。

2000.8-2004.7，山東大學工學學士。

學術兼職及社會任職：

1. 擔任Journal ofNanoscience Letters副編輯。

2. 擔任Angew Chem Int Ed、AdvMater、NanoEnergy、Langmuir、J Phys Chem、JHazard Mater、J Power Sources、J Mater Chem A等國際知名雜志審稿人。

3. 擔任2013年度與2014年度國家科技進步獎評審專家。

4. 擔任第55批中國博士后科學基金評審專家。

主講課程：

資料更新中……

培養研究生情況：

資料更新中……

教學成果：

1. 2014年，獲山東省研究生優秀科技創新成果獎三等獎（指導教師）。

2. 2015年，獲中國海洋大學“優秀教師”。

招生情況：

課題組每年招收學術型和專業型碩士研究生共9名，博士研究生1名，歡迎有事業心、團隊合作精神，對探索自然奧秘懷有好奇心和濃厚興趣、愿在科學上勇攀高峰的青年學子加盟。

研究方向：

1. 鈣鈦礦太陽能電池 (Perovskite Solar Cells)

2. 染料敏化太陽電池 (Dye-Sensitized Solar Cells)

3. 海水分解制氫 (Seawater Splitting forHydrogel Evolution) 

承擔科研項目情況：

1. 2013.01-2014.12，中國海洋大學高層次人才科研啟動基金。

2. 2013.01-2015.12，青年教師科研專項基金。

3. 2013.10-2015.10，山東省優秀中青年科學家科研獎勵基金。

4. 2014.01-2016.12，教育部博士點基金。

5. 2014.01-2015.12，國家自然科學基金云南聯合基金項目。 

科研成果：

1. 長期從事新型材料和化學領域研究，在功能性水凝膠、自組裝導電多層膜、染料敏化太陽能電池等領域取得突出的研究成果，已在Adv Mater, Adv Energy Mater, Chem Commun,J Mater Chem等國際權威雜志發表SCI80余篇，申請國家發明專利12項。博士學位論文“導電多層膜的層層自組裝及性能研究”獲得2012年福建省優秀博士學位論文。2013年獲教育部自然科學獎二等獎，2014年獲山東高等學校優秀科研成果獎二等獎。

2. 首次提出“自組裝導電多層膜”的概念并成功發現自組裝導電多層膜的電導率隨組裝層數的滲濾現象，提出了新的導電機理，奠定了自組裝導電多層膜在光電子納米器件中應用的理論基礎。

3. 首次開發了低鉑、非鉑合金對電極材料，相對于全鉑對電極，對電解質的催化效果提高2～3倍，而成本僅為其1/50。

4. 開發了雙面同時透射提高染料敏化太陽能電池性能的技術，相對于單面透射，染料敏化太陽能電池的光電轉換效率提高了30%以上。

5. 針對光陽極中因入射太陽光衰減導致染料激發不完全的難題，設計了一系列具有明顯增透效果的光陽極材料，所制備的染料敏化太陽能電池的光電轉換效率提高至11%，達到國際先進水平。 

發明專利：

1 一種微/納米Cu2O/ZnO 復合材料及其制備方法與它的用途 閆雪峰;李如;于良民;李昌誠;姜曉輝;唐群委;趙海洲;董磊專利號：201410515220

2 基于二氧化硅/二氧化鈦復合光陽極的染料敏化太陽能電池及其制備方法和應用 唐群委;徐珮珮;賀本林;陳曉旭 專利號：201310342850

3 基于二元低鉑合金對電極的染料敏化太陽能電池及其制備方法和應用 唐群委;孟昕;賀本林;陳曉旭;蔡紅遠專利號：201310342851

4 多孔水凝膠基中高溫質子交換膜及其制備方法和應用 唐群委;陳海燕;賀本林;陳曉旭;蔡紅遠;初蕾 專利號：201310033362

5 疏水凝膠基中高溫質子交換膜及其制備方法和應用 唐群委;陳海燕;陳曉旭;蔡紅遠;袁雙雙;袁偉強 專利號：201210520540

6 聚苯胺透明對電極基雙面染料敏化太陽能電池及其制備方法和應用 唐群委;賀本林;陳海燕;初蕾;陳曉旭 專利號：201310026549

7 水凝膠基中高溫質子交換膜及其制備方法和應用 唐群委;陳海燕;陳曉旭;蔡紅遠;袁雙雙;袁偉強 專利號：201210520544

8 吸附型固體酒精的制備方法 吳季懷;唐子穎;林建明;唐群委;范樂慶;黃妙良;李清華;蘭章 專利號：200910193679

9 聚吡咯／聚丙烯酸系復合凝膠電解質的制備方法 吳季懷;唐子穎;林建明;李清華;范樂慶;黃妙良;唐群委;蘭章;林幼貞 專利號：200910193672

10 膨脹蛭石/聚丙烯酸鉀－丙烯酰胺高吸水性復合材料的制備方法林建明;唐群委;吳季懷;黃妙良 專利號：200610037802

11 石墨/聚丙烯酸鉀導電水凝膠及其制備方法吳季懷;唐群委;林建明;黃妙良 專利號：20061003780112

12 互穿網絡水凝膠的制備方法 吳季懷;唐群委;林建明;黃妙良 專利號：200710008807

已在Adv Mater, Adv Energy Mater, Chem Commun,J Mater Chem等國際權威雜志發表SCI80余篇。

代表性英文論文：

2015：

1. Xiaoxu Chen, Qunwei Tang*, Zhiyuan Zhao, Xinghui Wang, Benlin He, and Liangmin Yu*, One-Step Growth of Well-Aligned TiO2 Nanorod Arrays for Flexible Dye-Sensitized Solar Cells, Chem. Commun., 2015, 51: 1945-1948.

2. Yanyan Duan, Qunwei Tang*, Yuran Chen, Zhiyuan Zhao, Yang Lv, Mengjin Hou, Peizhi Yang, Benlin He*, and Liangmin Yu*, Solid-State Dye-Sensitized Solar Cells from Poly(Ethylene Oxide)/Polyaniline Electrolytes with Catalytic and Hole-Transporting Characteristics, J. Mater. Chem. A, 2015, 3, 5368-5374.

3. Huihui Zhang, Benlin He*, Qunwei Tang*, and Liangmin Yu*, Bifacial Dye-Sensitized Solar Cells from Covalent-Bonded Polyaniline-Multiwalled Carbon Nanotube Complex Counter Electrodes, J. Power Sources, 2015, 275: 489-497.

4. Chunqing Ma, Qunwei Tang*, Danyang Liu, Zhiyuan Zhao, Benlin He, Haiyan Chen, and Liangmin Yu*, A Bifacial Quantum Dot-Sensitized Solar Cell with All-Cadimium Sulfide Photoanode, J. Power Sources, 2015, 276: 215-221.

5. Chunqing Ma, Qunwei Tang*, Zhiyuan Zhao, Mengjin Hou, Yuran Chen, Benlin He, and Liangmin Yu*, Bifacial Quantum Dot-Sensitized Solar Cells with Transparent Cobalt Selenide Counter Electrodes, J. Power Sources, 2015, 278: 183-189.

6. Zubin Wang, Qunwei Tang*, Benlin He, Xiaoxu Chen, Haiyan Chen, and Liangmin Yu*, Titanium Dioxide/Calcium Fluoride Nanocrystallite for Efficient Dye-Sensitized Solar Cell. A Strategy of Enhancing Light Harvest, J. Power Sources, 2015, 275: 175-180.

7. Juan Liu, Qunwei Tang*, Benlin He, and Liangmin Yu*, Cost-Effective Bifacial Dye-Sensitized Solar Cells with Transparent Iron Selenide Counter Electrodes. An Avenue of Enhancing Rear-Side Electricity Generation Capability, J. Power Sources, 2015, 275: 288-293.

8. Yanyan Duan, Qunwei Tang*, Ru Li, Benlin He*, and Liangmin Yu*, An Avenue of Sealing Liquid Electrolyte in Flexible Dye-Sensitized Solar Cells, J. Power Sources, 2015, 274: 304-309.

9. Shuangshuang Yuan, Qunwei Tang*, Benlin He, and Liangmin Yu*, Conducting Gel Electrolytes with Microporous Structures for Efficient Quasi-Solid-State Dye-Sensitized Solar Cells, J. Power Sources, 2015, 273: 1148-1155.

10. Pinjiang Li, Yanyan Duan*, Qunwei Tang*, Benlin He, and Ru Li*, An Avenue of Expanding Triiodide Reduction and Shortening Charge-Diffusion Length in Solid-State Dye-Sensitized Solar Cells, J. Power Sources, 2015, 273: 180-184.

11. Ru Li, Liangmin Yu, Xuefeng Yan*, Qunwei Tang*, Efficient Photocatalysts from Polymorphic Cuprous Oxide/Zinc Oxide Microstructures, RSC Adv., 2015, 5: 11917-11924.

12. Benlin He, Qunwei Tang*, Liangmin Yu*, and Peizhi Yang, Cost-Effective Alloy Counter Electrodes as a New Avenue for High-Efficiency Dye-Sensitized Solar Cells, Electrochim. Acta, 2015, 158: 397-402.

13. Hongyuan Cai, Qunwei Tang*, Benlin He, and Shuangshuang Yuan, Insights on Tunneled Electrons for Electrical and Photoelectric Behaviors in Conducting Multilayer Films, Polym. Eng. Sci., 2015, 55: 107-112.

14. Xiaopeng Wang, Qunwei Tang*, Benlin He, Ru Li, and Liangmin Yu*, 7.35% Efficiency Rear-Irradiated Flexible Dye-Sensitized Solar Cells by Sealing Liquid Electrolyte in a Groove, Chem. Commun., 2015, 51: 491-494.

15. Qunwei Tang*, Juan Liu, Huihui Zhang, Benlin He, Liangmin Yu*, Cost-effective counter electrode electrocatalysts from iron@palladium and iron@platinum alloy nanospheres for dye-sensitized solar cells, J. Power Sources, 2015, 297: 1-8.

16. Peizhi Yang, Zhiyuan Zhao, Ling Zhu, Qunwei Tang*, Counter electrodes from Mo-Se nanosheet alloys for bifacial dye-sensitized solar cells, J. Alloy. Compd., 2015, 648: 930-936.

17. Zubin Wang, Qunwei Tang, Benlin He, Haiyan Chen, Liangmin Yu*, Efficient dye-sensitized solar cells from curved silicate microsheet caged TiO2 photoanodes. An avenue of enhancing light harvesting, Electrochim. Acta, 2015, 178: 18-24.

18. Peizhi Yang, Jialong Duan, Danyang Liu, Qunwei Tang*, Benlin He, Multi-interfacial polyaniline-graphene/platinum counter electrodes for dye-sensitized solar cells, Electrochim. Acta, 2015, 173: 331-337.

19. Juan Liu, Qunwei Tang*, Benlin He, Liangmin Yu*, Cost-effective, transparent iron selenide nanoporous alloy counter electrode for bifacial dye-sensitized solar cell, J. Power Sources, 2015, 282: 79-86.

20. Jialong Duan, Huihui Zhang, Qunwei Tang*, Benlin He, Liangmin Yu*, Recent advances in critical materials for quantum dot-sensitized solar cells: a review, J. Mater. Chem. A, 2015, 3: 17497-17510.

21. Huihui Zhang, Qunwei Tang*, Benlin He, Alloying of platinum and molybdenum for transparent counter electrodes. A strategy of enhancing power output for bifacial dye-sensitized solar cells, RSC Adv., 2015, 5, 51600-51607.

22. Peizhi Yang, Qunwei Tang*, Benlin He, Toward elevated light harvesting: efficient dye-sensitized solar cells with titanium dioxide/silica photoanodes, RSC Adv., 2015, 5, 46260-46266.

23. Xiaoxu Chen, Qunwei Tang*, Benlin He, Haiyan Chen, Graphene-incorporated quasi-solid-state dye-sensitized solar cells, RSC Adv., 2015, 5: 43402-43407.

24. Jialong Duan, Qunwei Tang*, Benlin He, Haiyan Chen, All-solid-state quantum dot-sensitized solar cell from plastic crystal electrolyte, RSC Adv., 2015, 5: 33463-33467.

25. Peizhi Yang, Qunwei Tang*, A nanoporous titanium dioxide framework for dye-sensitized solar cell, Mater. Lett., doi: 10.1016/j.matlet.2015.08.104.

26. Yanyan Duan, Qunwei Tang*, Benlin He, Liangmin Yu*, Transparent counter electrode from palladium selenide for bifacial dye-sensitized solar cell, Mater. Lett., doi: 10.1016/j.matlet.2015.08.035.

27. Qunwei Tang*, Jialong Duan, Yanyan Duan, Benlin He, Liangmin Yu*, Recent advances in alloy counter electrodes for dye-sensitized solar cells. A critical review, Electrochim. Acta, doi: 10.1016/j.electacta.2015.08.072.

28. Peizhi Yang, Qunwei Tang*, Chenming Ji, Haobo Wang, A strategy of combining SILAR with solvothermal process for In2S3 sensitized quantum dot-sensitized solar cells, Appl. Surf. Sci. accepted.

29. Qunwei Tang*, Huihui Zhang, Yuanyuan Meng, Benlin He, Liangmin Yu*, Dissolution engineering of platinum alloy counter electrodes in dye-sensitized solar cells, Angew. Chem. Int. Ed., doi: 10.1002/anie.201505339.

30. Bingbing Hu, Fengying Dai, Zhanming Fan, Guanghui Ma, Qunwei Tang*, Xin Zhang*, Nanotheranostics: Congo red/rutin-MNPs with enhanced magnetic resonance imaging and H2O2-responsive therapy of Alzheimer’s disease in APPswe/PS1dE9 transgenic mice, Adv. Mater., doi: 10.1002/adma.201502227.

31. Yanyan Duan, Yuran Chen, Qunwei Tang*, Zhiyuan Zhao, Mengjin Hou, Ru Li, Benlin He*, Liangmin Yu*, Peizhi Yang, and Zhiming Zhang, A Dye-Sensitized Solar Cell Having Polyaniline Species in Each Component with 3.1%-Efficiency, J. Power Sources, 2015, 284: 178-185.

32. Jialong Duan, Qunwei Tang*, Ru Li, Benlin He*, Liangmin Yu*, and Peizhi Yang, Multifunctional graphene incorporated polyacrylamide conducting gel electrolytes for efficient quasi-solid-state quantum dot-sensitized solar cells, J. Power Sources, 2015, 284: 369-376.

33. Yanyan Duan, Qunwei Tang*, Benlin He, Zhiyuan Zhao, Ling Zhu, and Liangmin Yu*, Bifacial dye-sensitized solar cells with transparent cobalt selenide alloy counter electrodes, J. Power Sources, 2015, 284: 349-354.

2014：

1. Shuangshuang Yuan, Qunwei Tang*, Benlin He, Haiyan Chen, Qinghua Li, Chunqing Ma, Suyue Jin, Zhichao Liu, H3PO4 imbibed polyacrylamide-graft-chitosan frameworks for high-temperature proton exchange membranes, Journal of Power Sources, 2014, 249, 277-284.

2. Qinghua Li, Xiaoxu Chen, Qunwei Tang*, Hongyuan Cai, Yuancheng Qin, Benlin He, Mingjun Li, Suyue Jin, Zhichao Liu, Journal of Power Sources, 2014, 248, 923-930.

3. Qinghua Li, Qunwei Tang*, Nan Du, Yuancheng Qin, Jin Xiao, Benlin He, Haiyan Chen, Lei Chu, Employment of ionic liquid-imbibed polymer gel electrolyte for efficient quasi-solid-state dye-sensitized solar cells, Journal of Power Sources, 2014, 248, 816-821.

4. Xiaoxu Chen, Hongyuan Cai, Qunwei Tang*, Danwei Liang, Min Wang, Benlin He, Growth of hexagonal polyaniline fibers with polyacrylamide pendants, Polymer Composites, 2014, 35, 253-262.

5. Shuangshuang Yuan, Qunwei Tang*, Bingbing Hu, Chunqing Ma, Jialong Duan, Benlin He, Efficient quasi-solid-state dye-sensitized solar cells from graphene incorporated conducting gel electrolytes, Journal of Materials Chemistry A, 2014, 2, 2814-2821.

6. Benlin He, Qunwei Tang*, Tianlun Liang, Qinghua Li, Efficient dye-sensitized solar cells from polyaniline-single wall carbon nanotube complex counter electrodes, Journal of Materials Chemistry A, 2014, 2, 3119-3126.

7. Qi Qin, Qunwei Tang*, Qinghua Li, Benlin He, Haiyan Chen, Xin Wang, Peizhi Yang, Incorporation of H3PO4 into three-dimensional polyacrylamide-graft-starch hydrogel frameworks for robust high-temperature proton exchange membrane fuel cells, International Journal of Hydrogen Energy, 2014, 39, 4447-4458.

8. Shuangshuang Yuan, Qunwei Tang*, Benlin He, Peizhi Yang, Efficient quasi-solid-state solar cells employing polyaniline and polypyrrole incorporated microporous conducting gel electrolytes, Journal of Power Sources, 2014, 254, 98-105.

9. Peipei Xu, Qunwei Tang*, Haiyan Chen, Benlin He, Insights of close contact between polyaniline and FTO substrate for enhanced photovoltaic performances of dye-sensitized solar cells, Electrochimica Acta, 2014, 125, 163-169.

10. Qinghua Li, Qunwei Tang*, Haiyan Chen, Haitao Xu, Yuancheng Qin, Benlin He, Zhichao Liu, Suyue Jin, Lei Chu, Quasi-solid-state dye-sensitized solar cells from hydrophobic poly(hydroxyethyl methacrylate/glycerin)/polyaniline gel electrolyte, Materials Chemistry and Physics, 2014, 144, 287-292.

11. Benlin He, Qunwei Tang*, Jinghuan Luo, Qinghua Li, Xiaoxu Chen, Hongyuan Cai, Rapid charge-transfer in polypyrrole-single wall carbon nanotube complex counter electrodes: Improved photovoltaic performances of dye-sensitized solar cells, Journal of Power Sources, 2014, 256, 170-177.

12. Xiaoxu Chen, Qunwei Tang*, Benlin He, Efficient dye-sensitized solar cell from spiny polyaniline nanofiber counter electrode, Materials Letters, 2014, 119, 28-31.

13. Hongyuan Cai, Qunwei Tang*, Benlin He, Min Wang, Shuangshuang Yuan, Haiyan Chen, Self-assembly of graphene oxide/polyaniline multilayer counter electrodes for efficient dye-sensitized solar cells, Electrochimica Acta, 2014, 121, 136-142.

14. Benlin He, Qunwei Tang*, Min Wang, Chunqing Ma, Shuangshuang Yuan, Complexation of polyaniline and graphene for efficient counter electrodes in dye-sensitized solar cells: Enhanced charge transfer ability, Journal of Power Sources, 2014, 256, 8-13.

15. Hongyuan Cai, Qunwei Tang*, Benlin He, Pinjiang Li, PtRu nanofiber alloy counter electrodes for dye-sensitized solar cells, Journal of Power Sources, 2014, 258, 117-121.

16. Min Wang, Qunwei Tang*, Peipei Xu, Benlin He, Lin Lin, Haiyan Chen, Counter electrodes from polyaniline-graphene complex/graphene oxide multilayers for dye-sensitized solar cells, Electrochimica Acta, 2014, 137, 175-182.

17. Qinghua Li, Qunwei Tang*, Lin Lin, Xiaoxu Chen, Haiyan Chen, Lei Chu, Haitao Xu, Mingjun Li, Yuancheng Qin, Benlin He, A simple approach of enhancing photovoltaic performances of quasi-solid-state dye-sensitized solar cells by integrating conducting polyaniline into electrical insulating gel electrolyte, Journal of Power Sources, 2014, 245, 468-474.

18. Shuangshuang Yuan, Qunwei Tang*, Benlin He, Long Men, Haiyan Chen, Transmission enhanced photoanodes for efficient dye-sensitized solar cells, Electrochimica Acta, 2014, 125, 646-651.

19. Xiaoxu Chen, Hongyuan Cai, Qunwei Tang*, Yingchao Yang, Benlin He, Solar photocatalysts from Gd-La codoped TiO2 nanoparticles, Journal of Materials Science, 2014, 49, 3371-3378.

20. Hongyuan Cai, Qunwei Tang*, Benlin He, Shuangshuang Yuan, Insights on tunneled electrons for electrical and photoelectric behaviors in conducting multilayer films, Polymer Engineering & Science, doi: 10.1002/pen.23880.

21. Yuancheng Qin, Xiaoxu Chen, Qunwei Tang*, Qinghua Li, Benlin He, Kexin Chen, Suyue Jin, Weili Dai, Mingjun Li, Yu Xie, Yunhua Gao, Microporous gel electrolyte for quasi-solid-state dye-sensitized solar cell, Polymer Engineering & Science, doi: 10.1002/pen23808.

22. Min Wang, Qunwei Tang*, Haiyan Chen, Benlin He, Peculiar electrical and photoelectric behaviors in conducting multilayers: Insights into accumulative charge tunneling, Journal of Applied Polymer Science, doi: 10.1002/app.40258.

23. Qi Qin, Qunwei Tang*, Benlin He, Haiyan Chen, Shuangshuang Yuan, Xin Wang, Enhanced proton conductivity from phosphoric acid-incorporated 3D polyacrylamide-graft-starch hydrogel materials for high-temperature proton exchange membranes, Journal of Applied Polymer Science, doi: 10.1002/app.40622.

24. Hongyuan Cai, Xiaoxu Chen, Qunwei Tang*, Min Wang, Danwei Liang, Polypyrrole nanoflake array for glucose biosensing, Materials Research Innovations, doi: 10.1179/1433075X13Y.0000000165.

25. Hongyuan Cai, Xiaoxu Chen, Qunwei Tang*, Benlin He, Enhancing methanol oxidation reaction by incorporating La2O3 into eggshell membrane templated Pd as electrocatalyst, Materials Research Innovations, doi: 10.1179/1433075X13Y.0000000183.

26. Xiaoxu Chen, Hongyuan Cai, Qunwei Tang*, Benlin He, Haiyan Chen, Eggshell membrane templated Y2O3@Pd catalyst for enhanced methanol oxidation and CO tolerance,Materials Research Innovations,doi:10.1179/1433075X13Y.0000000148.

27. Jihuai Wu, Yan Li, Qunwei Tang*, Gentian Yue, Jianming Lin, Miaoliang Huang, Lijian Meng, Bifacial dye-sensitized solar cells: A strategy to enhance overall efficiency based on transparent polyaniline electrode, Scientific Reports, 2014, 4, 4028.

28. Shuangshuang Yuan, Qunwei Tang*, Benlin He, Yun Zhao, Multifunctional graphene incorporated conducting gel electrolytes in enhancing photovoltaic performances of quasi-solid-state dye-sensitized solar cells, Journal of Power Sources, 2014, 260, 225-232.

29. Benlin He, Xin Meng, Qunwei Tang*, Pinjiang Li, Shuangshuang Yuan, Peizhi Yang, Low-cost CoPt alloy counter electrodes for efficient dye-sensitized solar cells, Journal of Power Sources, 2014, 260, 180-185.

30. Benlin He, Xin Meng, Qunwei Tang*, Low-cost counter electrodes from CoPt alloys for efficient dye-sensitized solar cells, ACS Applied Materials & Interfaces, 2014, 6, 4812-4818.

31. Peipei Xu, Qunwei Tang*, Benlin He, Qinghua Li, Haiyan Chen, Transmission booster from SiO2 incorporated TiO2 crystallites: Enhanced conversion efficiency in dye-sensitized solar cells, Electrochimica Acta, doi: 10.1016/j.electacta.2014.03.121.

32. Qinghua Li, Qunwei Tang*, Benlin He, Peizhi Yang, Full-ionic liquid gel electrolytes: Enhanced photovoltaic performances in dye-sensitized solar cells, Journal of Power Sources, doi: 10.1016/j.jpowsour.2014.04.095.

33. Pinjiang Li, Shuangshuang Yuan, Qunwei Tang*, Benlin He, Robust conducting gel electrolytes for efficient quasi-solid-state dye-sensitized solar cells, Electrochimica Acta, doi: 10.1016/j.electacta.2014.04.093.

34. Shuangshuang Yuan, Qunwei Tang*, Benlin He, Three-dimensional hydrogel frameworks for high-temperature proton exchange membrane fuel cells, Journal of Materials Science, doi: 10.1007/s10853-014-8261-9.

35. Bingbing Hu, Qunwei Tang*, Benlin He, Lin Lin, Haiyan Chen, Mesoporous TiO2 anodes for efficient dye-sensitized solar cells: An efficiency of 9.86% under one sun illumination, Journal of Power Sources, 2014, 267, 445-451.

36. Yanyan Duan, Qunwei Tang*, Zihan Chen, Benlin He, Haiyan Chen, Enhanced dye illumination in dye-sensitized solar cells employing TiO2/GeO2 photoanodes, Journal of Materials Chemistry A, 2014, 2, 12459-12465.

37. Benlin He, Qunwei Tang*, Min Wang, Haiyan Chen, Shuangshuang Yuan, Robust polyaniline-graphene complex counter electrodes for efficient dye-sensitized solar cells, ACS Applied Materials & Interfaces, 2014, 6, 8230-8236.

38. Juan Liu, Qunwei Tang*, Benlin He, Platinum-free binary Fe-Co nanofiber alloy counter electrodes for dye-sensitized solar cells, Journal of Power Sources, 2014, 268, 56-62.

39. Pinjiang Li, Hongyuan Cai, Qunwei Tang*, Benlin He, Lin Lin, Counter electrodes from binary ruthenium selenide alloys for dye-sensitized solar cells, Journal of Power Sources, 2014, 271, 108-113.

40. Pinjiang Li, Yanyan Duan, Qunwei Tang*, Benlin He, Ru Li, An avenue of expanding triiodide reduction and shortening charge diffusion length in solid-state dye-sensitized solar cells, Journal of Power Sources, 2015, 273, 180-184.

41. Jialong Duan, Qunwei Tang*, Benlin He, Liangmin Yu, Efficient In2S3 quantum dot-sensitized solar cells: A promising power conversion efficiency of 1.30%, Electrochimica Acta, 2014, 139, 381-385.

42. Xiaoxu Chen, Qunwei Tang*, Benlin He, Lin Lin, Liangmin Yu, Platinum-free binary Co-Ni alloy counter electrodes for efficient dye-sensitized solar cells, Angewandte Chemie International Edition, 2014, 53, 10799-10803.

43. Yanyan Duan, Qunwei Tang*, Benlin He, Ru Li, Liangmin Yu, Transparent nickel selenide alloy counter electrodes for bifacial dye-sensitized solar cells exceeding 10% efficiency, Nanoscale, 2014, doi: 10.1039/C4NR03900A.

44. Benlin He, Qunwei Tang*, Xin Meng, Liangmin Yu, Poly(vinylidene fluoride)-implanted cobalt-platinum alloy counter electrodes for dye-sensitized solar cells, Electrochimica Acta, 2014, doi: 10.1016/j.electacta.2014.09.121.

45. Shuangshuang Yuan, Qunwei Tang*, Benlin He, Liangmin Yu, Conducting gel electrolytes with microporous structures for efficient quasi-solid-state dye-sensitized solar cells, Journal of Power Sources, 2014, 273, 1148-1155.

46. Yanyan Duan, Qunwei Tang*, Ru Li, Benlin He, Liangmin Yu, An avenue of sealing liquid electrolyte in flexible dye-sensitized solar cells, Journal of Power Sources, 2015, 274, 304-309.

47. Yanyan Duan, Qunwei Tang*, Juan Liu, Benlin He, Liangmin Yu, Transparent metal selenide alloy counter electrodes for high-efficiency bifacial dye-sensitized solar cells, Angewandte Chemie International Edition, 2014, doi: 10.1002/anie.201409422.

48. Zubin Wang, Qunwei Tang*, Benlin He, Xiaoxu Chen, Haiyan Chen, Liangmin Yu, Journal of Power Sources, doi: 10.1016/j.jpowsour.2014.11.006.

49. Juan Liu, Qunwei Tang*, Benlin He, Liang Yu, Cost-effective bifacial dye-sensitized solar cells with transparent iron selenide counter electrodes. An avenue of enhancing rear-side electricity generation capability, Journal of Power Sources, doi: 10.1016/j.jpowsour.2014.10.152.

50. Xiaopeng Wang, Qunwei Tang*, Benlin He, Ru Li, Liangmin Yu, 7.35%-Efficiency rear-irradiated flexible dye-sensitized solar cell by sealing liquid electrolyte in a groove, Chemical Communications, doi: 10.1039/C4CC07549H.

51. Hongyuan Cai, Qunwei Tang*, Benlin He, Ru Li, Liangmin Yu, Bifacial dye-sensitized solar cells with enhanced rear efficiency and power output, Nanoscale, 2014, doi: 10.1039/C4NR04911J.

2013：

1. Qinghua Li, Haiyan Chen, Lin Lin, Pinjiang Li, Yuancheng Qin, Mingjun Li, Benlin He, Lei Chu, Qunwei Tang*, Quasi-solid-state dye-sensitized solar cell from polyaniline integrated poly(hexamethylene diisocyanate tripolymer/polyethylene glycol) gel electrolyte, Journal of Materials Chemistry A, 2013, 1, 5326-5332.

2. Qunwei Tang*, Hongyuan Cai, Shuangshuang Yuan, Xin Wang, Counter electrodes from double-layered polyaniline nanostructures for dye-sensitized solar cell applications, Journal of Materials Chemistry A, 2013, 1, 317-323.

3. Jihuai Wu, Gentian Yue, Yaoming Xiao, Jianming Lin, Miaoliang Huang, Zhang Lan, Qunwei Tang, Yunfang Huang, Leqing Fan, Shu Yin, Tsugio Sato, An ultraviolet responsive hybrid solar cell based on titania/poly(3-hexylthiophene), Scientific Reports, 2013, 3, 1283 (6 pages).

4. Lin Lin, Chenghao Yang, Long Men, Xin Wang, Dannong He, Yuchao Chai, Bin Zhao, Soumitra Ghoshroy, Qunwei Tang*, A highly efficient TiO2@ZnO n-p-n heterojunction nanorod photocatalyst, Nanoscale, 2013, 5, 588-593.

5. Lin Lin, Yuchao Chai, Yingchao Yang, Xin Wang, Dannong He, Qunwei Tang*, Soumitra Ghoshroy, Hierarchical Gd-La codoped TiO2 microspheres as robust photocatalysts, Internation Journal of Hydrogen Energy, 2013, 38, 2634-2640.

6. Qunwei Tang, Kevin Huang, Guoqing Qian, Brian C. Benicewicz, Phosphoric acid-imbibed three-dimensional polyacrylamide/poly(vinyl alcohol) hydrogel as a new class of high-temperature proton exchange membrane, Journal of Power Sources, 2013, 229, 36-41.

7. Qunwei Tang*, Shuangshuang Yuan, Hongyuan Cai, High-temperature proton exchange membranes from microporous polyacrylamide caged phosphoric acid, Journal of Materials Chemistry A, 2013, 1, 630-636.

8. Qunwei Tang*, Hongyuan Cai, Shuangshuang Yuan, Xin Wang, Weiqiang Yuan, Enhanced proton conductivity from phosphoric acid-imbibed crosslinked 3D polyacrylamide frameworks for high-temperature proton exchange membranes, Internation Journal of Hydrogen Energy, 2013, 38, 1016-1026.

9. Qunwei Tang*, Hongyuan Cai, Shuangshuang Yuan, Xin Wang, Percolation effect and thermoplasticity of conducting [poly(acrylic acid)/C16TAB-modified graphene oxide]n multilayer films, Journal of Materials Science, 2013, 48, 1843-1851.

10. Yan Li, Gentian Yue, Xiaoxu Chen, Benlin He, Lei Chu, Haiyan Chen, Jihuai Wu*, Qunwei Tang*, Application of poly(3,4-ethylenedioxythiophene): polystyrenesulfonate in polymer heterojunction solar cells, Journal of Materials Science, 2013, 48, 3528-3534.

11. Qunwei Tang, Guoqing Qian, Kevin Huang*, Hydrophobic hydrogels caged H3PO4 as a new class of high-temperature proton exchange membranes with enhanced acid retention, RSC Advances, 2013, 3, 3520-3525.

12. Lin Lin, Yuchao Chai, Bin Zhao, Wei Wei, Dannong He, Benlin He, Qunwei Tang*, Photocatalytic oxidation for degradation of VOCs, Open Journal of Inorganic Chemistry, 2013, 3, 14-25 (Review).

13. Qinghua Li, Xiaoxu Chen, Qunwei Tang*, Haitao Xu, Benlin He, Yuancheng Qin, Imbibition of polypyrrole into three-dimensional poly(hydroxyethyl methacrylate/glycerol) gel electrolyte for robust quasi-solid-state dye-sensitized solar cells, Journal of Materials Chemistry A, 2013, 1, 8055-8060.

14. Xiaoxu Chen, Hongyuan Cai, Danwei Liang, Min Wang, Qunwei Tang*, Morphological and electrochemical properties of “polyelectrolyte multilayer films” made from polyaniline and ZnO nanoparticles: deposition as films or as clusters ? Polymer Composites, 2013, 34, 1333-1341.

15. Qunwei Tang*, Benlin He, Lei Chu, Nanoflake patterning of self-assembled multilayer films, Polymer & Polymer Composites, 2013, 21, 73-77.

16. Hongyuan Cai, Xiaoxu Chen, Qinghua Li, Benlin He, Qunwei Tang*, Enhanced photocatalytic activity from Gd, La codoped TiO2 nanotube array photocatalysts under visible-light irradiation, Applied Surface Science, 2013, 284, 837-842.

17. Danwei Liang, Qunwei Tang*, Lei Chu, Qinghua Li, Benlin He, Hongyuan Cai, Min Wang, Insights on the accumulation of charge carriers for enhanced electrical and photoelectric behaviors in conducting multilayer films, RSC Advances, 2013, 3, 25190-25196.

18. Ru Li, Xuefeng Yan, Liangmin Yu, Zhiming Zhang, Qunwei Tang, Yongping Pan, The morphology dependence of cuprous oxide and its photocatalytic properties, CrystEngComm, 2013, 15, 10049-10058.

19. Benlin He, Xin Meng, Yongbo Zhu, Qunwei Tang*, Preparation and electrochemical properties of polyanilne/α-RuCl3•xH2O composites for supercapacitor, Polymer Composites, 2013, 34, 2142-2147.

20. Jihuai Wu, Gentian Yue, Yaoming Xiao, Jianming Lin, Miaoliang Huang, Zhang Lan, Qunwei Tang, Yunfang Huang, Leqing Fan, Shu Yin, Tsugio Sato, Scientific Reports, 2013, 3, 1283.

2012：

1. Ziying Tang, Xiaoyang Wu, Zhisen Luo, Qunwei Tang, Jianming Lin, Jihuai Wu, Alcohol elastomer based on superabsorbents, Polymers for Advanced Technologies, 2012, 23, 870-876.

2. Jihuai Wu, Yaoming Xiao, Qunwei Tang, Gentian Yue, Jianming Lin, Miaoliang Huang, Yunfang Huang, Leqing Fan, Zhang Lan, Shu Yin, Tsugio Sato, A Large-Area Light-Weight Dye-Sensitized Solar Cell based on All Titanium Substrates with an Efficiency of 6.69% Outdoors, Advanced Materials, 2012, 24, 1884-1888.

3. Ziying Tang, Jihuai Wu, Qin Liu, Min Zheng, Qunwei Tang, Zhang Lan, Jianming Lin, Preparation of poly(acrylic acid)/gelatin/polyaniline gel-electrolyte and its application in quasi-solid-state dye-sensitized solar cells, Journal of Power Sources, 2012, 203, 282-287.

4. Qunwei Tang, Lin Lin, Xuan Zhao, Kevin Huang, Jihuai Wu, p-n Heterojunction on Ordered ZnO Nanowires/Polyaniline Microrods Double Array, Langmuir, 2012, 28, 3972-3978.

5. Qunwei Tang, Guoqing Qian, Kevin Huang, H3PO4-imbibed three-dimensional polyacrylamide/polyacrylamide hydrogel as a high-temperature proton exchange membrane with excellent acid retention, RSC Advances, 2012, 2, 10238-10244.

6. Qunwei Tang, Zhengping Mao, Shuguo Ma, Kevin Huang, Enhanced methanol oxidation and CO tolerance using CeO2-added eggshell membrane-templated Pd network electrocatalyst, RSC Advances, 2012, 2, 11465-11471.

7. Qunwei Tang, Jihuai Wu, Ziying Tang, Yan Li, Jianming Lin, High-temperature proton exchange membranes from ionic liquid absorbed/doped superabsorbents, Journal of Materials Chemistry, 2012, 22, 15836-15844.

8. Ziying Tang, Qunwei Tang, Jihuai Wu, Yan Li, Qin Liu, Min Zheng, Yaoming Xiao, Gentian Yue, Miaoliang Huang, Jianming Lin, Template-free synthesis of a hierarchical flower-like platinum counter electrode and its application in dye-sensitized solar cells, RSC Advances, 2012, 2, 5034-5037.

9. Ziying Tang, Jihuai Wu, Min Zheng, Qunwei Tang, Qin Liu, Jianming Lin, Jiangli Wang, High efficient PANI/Pt nanofiber counter electrode used in dye-sensitized solar cell, RSC Advances, 2012, 2, 4062-4064.

10. Qunwei Tang, Lin Lin, Zhengping Mao, Ziying Tang, Jihuai Wu, Controllably hierarchical growth of large-scale ZnO microrods, RSC Advances, 2012, 2, 2211-2216.

11. Qunwei Tang, Lin Lin, Zhengping Mao, Jihuai Wu, p-n Heterojunction on dye-sensitized ZnO nanorod arrays and macroporous polyaniline network, RSC Advances, 2012, 2, 1863-1869.

12. Jihuai Wu, Jiangli Wang, Jianming Lin, Zhang Lan, Qunwei Tang, Miaoliang Huang, Yunfang Huang, Leqing Fan, Qingbei Li, Ziying Tang, Enhancement of the Photovoltaic Performance of Dye-Sensitized Solar Cells by Doping Y0.78Yb0.20Er0.02F3 in the Photoanode, Advanced Energy Materials, 2012, 2, 78-81. 

2011：

1. Ziying Tang, Qin Liu, Qunwei Tang, Jihuai Wu, Jiangli Wang, Shuhong Chen, Cunxi Cheng, Haijun Yu, Zhang Lan, Jianming Lin, Miaoliang Huang, Preparation of PAA-g-CTAB/PANI polymer based gel-electrolyte and the application in quasi-solid-state dye-sensitized solar cells, Electrochimica Acta, 2011, 58, 52-57.

2. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jianming Lin, Jihuai Wu, Growth of large-scaled polypyrrole fibers using polyacrylamide as modifier, E-polymers, 2011.

3. Xiaoming Sun, Qunwei Tang, Jihuai Wu, KQ Xu, Xin Zhong, Jianming Lin, Miaoliang Huang, Two-step synthesis of superabsorbent conducting hydrogel based on poly(acrylamide-pyrrole) with interpenetrating network structure, Materials Research Innovations, 2011, 15, 70-74.

4. Qunwei Tang, Ziying Tang, Jihuai Wu, Jianming Lin, Miaoliang Huang, A facile route to a macroporous silver network for methanol oxidation, RSC Advances, 2011, 1, 1453-1456.

5. Qunwei Tang, Yan Li, Ziying Tang, Jihuai Wu, Jianming Lin, Miaoliang Huang, Anhydrous proton exchange membrane operated at 200 degrees C and a well-aligned anode catalyst, Journal of Materials Chemistry, 2011, 21, 16010-16017.

6. Qunwei Tang, Jihuai Wu, Ziying Tang, Yan Li, Jianming Lin, Miaoliang Huang, Flexible and macroporous network-structured catalysts composed of conducting polymers and Pt/Ag with high electrocatalytic activity for methanol oxidation, Journal of Materials Chemistry, 2011, 21, 13354-13364.

7. Qunwei Tang, Ziying Tang, Jihuai Wu, Jianming Lin, Ilkwon Oh, Highly conducting multilayer films from graphene nanosheets by a spin self-assembly method, Journal of Materials Chemistry, 2011, 21, 5378-5385.

8. Qunwei Tang, Jihuai Wu, Yan Li, Jianming Lin, Ziying Tang, Miaoliang Huang, Facile secondary-template synthesis of polyaniline microtube array for enhancing glucose biosensitivity, Journal of Materials Chemistry, 2011, 21, 12927-12934.

2010：

1. Qinghua Li, Jihuai Wu, Qunwei Tang, Sancun Hao, Yaoming Xiao, Jianming Lin, Miaoliang Huang, Low cost method to obtain counter electrode for dye sensitised solar cells, Materials Research Innovations, 2010, 14, 410-413.

2. Jianming Lin, Qunwei Tang, Jihuai Wu, Qinghua Li, A Multifunctional Hydrogel with High-Conductivity, pH-Responsive, and Release Properties from Polyacrylate/Polyptrrole, Journal of Applied Polymer Science, 2010, 116, 1376-1383.

3. Qunwei Tang, Qinghua Li, Jianming Lin, Shijun Fan, De Hu, Jihuai Wu, High Conducting Multilayer Films From Poly(acrylic acid) and Graphite by Layer-by-Layer Self-Assembly, Polymer Composites, 2010, 31, 145-151.

2009：

1. Haiyong Ao, Miaoliang Huang, Jihuai Wu, Jianming Lin, Qunwei Tang, Hui Sun, Synthesis and properties of poly(acrylamide-co-acrylic acid)/polyacrylamide superporous IPN hydrogels, Polymers for Advanced Technologies, 2009, 20, 1044-1049.

2. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jihuai Wu, Jianming Lin, A simple route to interpenetrating network hydrogel with high mechanical strength, Journal of Colloid and Interface Science, 2009, 339, 45-52.

3. Qinghua Li, Jihuai Wu, Qunwei Tang, Zhang Lan, Pinjiang Li, Tingting Zhang, Application of Polymer Gel Electrolyte With Graphite Powder in Quasi-Solid-State Dye-Sensitized Solar Cells, Polymer Composites, 2009, 30, 1687-1692.

4. Qunwei Tang, Jihuai Wu, Xiaoming Sun, Qinghua Li, Jianming Lin, Layer-by-layer self-assembly of conducting multilayer film from poly (sodium styrenesulfonate) and polyaniline, Journal of Colloid and Interface Science, 2009, 337, 155-161.

5. Qunwei Tang, Xiaoming Sun, Jihuai Wu, Qinghua Li, Jianming Lin, Design and Electrical Conductivity of Poly(acrylic acid-g-gelatin)/Graphite Conducting Gel, Polymer Engineering and Science, 2009, 49, 1871-1878.

6. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jihuai Wu, Jianming Lin, Fabrication of a high-strength hydrogel with an interpenetrating network structure, Colloids and Surfaces A-physicochemical and Engineering Aspects, 2009, 346, 91-98.

7. Jianming Lin, Qunwei Tang, De Hu, Xiaoming Sun, Qinghua Li, Jihuai Wu, Electric field sensitivity of conducting hydrogels with interpenetrating polymer network structure, Colloids and Surfaces A-physicochemical and Engineering Aspects, 2009, 346, 177-183.

8. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jihuai Wu, Jianming Lin, Miaoliang Huang, A simple route to high-strength hydrogel with an interpenetrating polymer network, E-polymers, 2009.

9. Jianming Lin, Qunwei Tang, Jihuai Wu, Hui Sun, Shijun Fan, De Hu, Two Steps Synthesis and Conductivity of Polyacrylamide/Cu Conducting Hydrogel, Polymer Composites, 2009, 30, 1132-1137.

10. Qunwei Tang, Jihuai Wu, Hui Sun, Shijun Fan, De Hu, Jianming Lin, Synthesis of Polyacrylate/Poly(ethylene glycol) Hydrogel and its Absorption Properties for Heavy Metal Ions and Dye, Polymer Composites, 2009, 30, 1183-1189.

11. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jianming Lin, Jihuai Wu, Preparation of porous polyacrylate/poly(ethylene glycol) interpenetrating network hydrogel and simplification of Flory theory, Journal of Materials Science, 2009, 44, 3712-3718.

12. Qunwei Tang, Jihuai Wu, Hui Sun, Shijun Fang, Crystallization degree change of expanded graphite by milling and annealing, Journal of Alloys and Compounds, 2009, 475, 429-433.

13. Qunwei Tang, Jihuai Wu, Xiaoming Sun, Qinghua Li, Jianming Lin, Shape and Size Control of Oriented Polyaniline Microstructure by a Self-Assembly Method, Langmuir, 2009, 25, 5253-5257.

14. Qunwei Tang, Jihuai Wu, Jianming Lin, Shijun Fan, De Hu, A multifunctional poly(acrylic acid)/gelatin hydrogel, Journal of Materials Research, 2009, 24, 1653-1661.

15. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jihuai Wu, Jianming Lin, Synthesis of polyacrylate/polyethylene glycol interpenetrating network hydrogel and its sorption of heavy-metal ions, Science and Technology of Advanced Materials, 2009, 10.

16. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jihuai Wu, Jianming Lin, Miaoliang Huang, Synthesis of oriented polyaniline flake arrays, Materials Lerrers, 2009, 63, 540-542.

17. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jianming Lin, Jihuai Wu, Synthesis of polyacrylate/polyethylene glycol interpenetrating network hydrogel and its sorption for Fe3+ ion, Journal of Materials Science, 2009, 44, 726-733.

18. Qunwei Tang, Xiaoming Sun, Qinghua Li, Jianming Lin, Jihuai Wu, Preparation and electrical conductivity of SiO2/polypyrrole nanocomposite, Journal of Materials Science, 2009, 44, 849-854.

19. Qunwei Tang, Jihuai Wu, Xiaoming Sun, Qinghua Li, Jianming Lin, Leqing Fan, Polyacrylamide-controlled growth of centimeter-scaled polyaniline fibers, Polymer, 2009, 50, 752-755.

20. Qunwei Tang, Jihuai Wu, Xiaoming Sun, Qinghua Li, Jianming Lin, Miaoliang Huang, Templateless self-assembly of highly oriented polyaniline arrays, Chemical Communications, 2009, 2166-2167.

2008：

1. Jianming Lin, Qunwei Tang, Jihuai Wu, Hui Sun, Synthesis, Characterization, and Properties of Polypyrrole/expanded Vermiculite Intercalated Nanocomposite, Journal of Applied Polymer Science, 2008, 110, 2862-2866.

2. Jihuai Wu*, Qunwei Tang, Qinghua Li, Jianming Lin, Self-assembly growth of oriented polyaniline arrays: A morphology and structure study, Polymer, 2008, 49, 5262-5267.

3. Qunwei Tang, Jihuai Wu, Qinghua Li, Jianming Lin, High conducting multilayer films from poly(sodium styrenesulfonate) and graphite nanoplatelets by layer-by-layer self-assembly, Polymer, 2008, 49, 5329-5335.

4. Qunwei Tang, Jihuai Wu, Hui Sun, Jianming Lin, Shijun Fan, De Hu, Polyaniline/polyacrylamide conducting composite hydrogel with a porous structure, Carbohydrate Polymers, 2008, 74, 215-219.

5. Qinghua Li, Jihuai Wu, Qunwei Tang, Zhang Lan, Pinjiang Li, Jianming Lin, Leqing Fan, Application of microporous polyaniline counter electrode for dye-sensitized solar cells, Electrochemistry Communications, 2008, 10, 1299-1302.

6. Qunwei Tang, Jihuai Wu, Jianming Lin, Qinghua Li, Shijun Fan, Two-step synthesis of polyacrylamide/polyacrylate interpenetrating network hydrogels and its swelling/deswelling properties, Journal of Materials Science, 2008, 43, 5884-5890.

7. Shijun Fan, Qunwei Tang, Jihuai Wu, De Hu, Hui Sun, Jianming Lin, Two-step synthesis of polyacrylamide/poly(vinyl alcohol)/polyacrylamide/graphite interpenetrating network hydrogel and its swelling, conducting and mechanical properties, Journal of Materials Science, 2008, 43, 5898-5904.

8. Qunwei Tang, Jihuai Wu, Hui Sun, Shijun Fan, De Hu, Jianming Lin, Superabsorbent conducting hydrogel from poly(acrylamide-aniline) with thermo-sensitivity and release properties, Carbohydrate Polymers, 2008, 73, 473-481.

9. Qunwei Tang, Jihuai Wu, Jianming Lin, A multifunctional hydrogel with high conductivity, pH-responsive, thermo-responsive and release properties from polyacrylate/polyaniline hybrid, Carbohydrate Polymers, 2008, 73, 315-321.

10. Jianming Lin, Qunwei Tang, Jihuai Wu, Hui Sun, Synthesis, characterization and properties of polyaniline/expanded vermiculite intercalated nanocomposite, Science and Technology of Advanced Materials, 2008, 9.

11. Jihuai Wu*, Qunwei Tang, Hui Sun, Jianming Lin, Haiyong Ao, Miaoliang Huang, Yunfang Huang, Conducting film from graphite oxide nanoplatelets and poly(acrylic acid) by layer-by-layer self-assembly, Langmuir, 2008, 24, 4800-4805.

12. Qunwei Tang, Jianming Lin, Jihuai Wu, The preparation and electrical conductivity of polyacrylamide/graphite conducting hydrogel, Journal of Applied Polymer Science, 2008, 108, 1490-1495.

13. Qunwei Tang, Jihuai Wu, Jianming Lin, Hui Sun, Haiyong Ao, A high mechanical strength hydrogel from polyacrylamide/polyacrylamide with interpenetrating network structure by two-steps synthesis method, E-polymers, 2008.

2007：

1. Qunwei Tang, Jianming Lin, Zibao Wu, Jihuai Wu, Miaoliang Huang, Yuanyuan Yang, Preparation and photocatalytic degradability of TiO2/polyacrylamide composite, European Polymer Journal, 2007, 43, 2214-2220.

2. Jianming Lin, Qunwei Tang, Jihuai Wu, The synthesis and electrical conductivity of a polyacrylamide/Cu conducting hydrogel, Reactive & Functional Polymers, 2007, 67, 489-494.

3. Qunwei Tang, Jianming Lin, Jihuai Wu, Yuwen Xu, Chuanjuan Zhang, Preparation and water absorbency of a novel poly(acrylate-co-acrylamide)/vermiculite superabsorbent composite, Journal of Applied Polymer Science, 2007, 104, 735-739.

4. Jianming Lin, Qunwei Tang, Jihuai Wu, Sancun Hao, The synthesis and electrical conductivity of a polyacrylate/graphite hydrogel, Reactive & Functional Polymers, 2007, 67, 275-281.

5. Qunwei Tang, Jianming Lin, Jihuai Wu, Chuanjuan Zhang, Sancun Hao, Two-steps synthesis of a poly(acrylate-aniline) conducting hydrogel with an interpenetrated networks structure, Carbohydrate Polymers, 2007, 67, 332-336.

6. Qunwei Tang, Jihuai Wu, Haiyong Ao, Hui Sun, Lin Lin, Jianming Lin, Preparation and conductivity of polyaniline/SiO2 composites, Polymers & Polymer Composites, 2007, 15, 605-610. 

代表性中文論文：

1 高強度PAM/PVA互穿網絡水凝膠的合成 林建明; 唐群委; 吳季懷 華僑大學學報(自然科學版) 2010-01-20

2 Ag/PVP/PVA抗菌水凝膠的制備及性能 范士軍; 唐群委; 吳季懷; 胡德; 林建明 高分子材料科學與工程 2009-11-15

3 導電多層膜的層層自組裝及性能研究 唐群委 華僑大學 2009-03-01

4 聚丙烯酸鹽/淀粉半互穿網絡水凝膠的兩步水溶液合成及性能表征 孫慧; 林建明; 唐群委; 吳季懷 華僑大學學報(自然科學版) 2009-01-20

5 凝膠中聚苯胺的合成方法研究進展 胡德; 范士軍; 唐群委; 吳季懷; 林建明 化學工程與裝備 2008-11-15

6 溫度敏感聚丙烯酸鹽/聚乙二醇互穿網絡水凝膠的合成及重金屬離子吸收 唐群委; 孫慧; 敖海勇; 林建明; 吳季懷 功能材料 2008-01-20

7 高壓縮強度聚丙烯酸鹽/聚硅氧烷互穿網絡水凝膠的制備 唐群委; 孫慧; 敖海勇; 林建明; 吳季懷 功能材料 2007-12-20

8 瓊脂改性膨潤土/聚丙烯酸鈉-丙烯酰胺高吸水復合材料的合成及性能 張傳娟; 林建明; 吳季懷; 唐群委; 張榮慶 高分子材料科學與工程 2007-11-15

9 聚丙烯酸鹽/聚苯胺導電水凝膠的合成研究 唐群委; 吳季懷; 林建明 第六屆中國功能材料及其應用學術會議論文集（9） 2007-11-01

10 海藻酸鈉改性膨潤土/聚(丙烯酸鈉-丙烯酰胺)高吸水性復合材料的合成及性能 張傳娟; 林建明; 吳季懷; 唐群委 華僑大學學報(自然科學版) 2007-10-20

11 新型聚丙烯酰胺/碳纖維/石墨導電水凝膠的制備 唐群委; 孫慧; 林建明; 林琳; 敖海勇; 吳季懷 功能材料 2007-10-20

12 聚(丙烯酸鹽共聚丙烯酰胺)/膨脹蛭石高吸水性復合材料的制備 唐群委; 吳季懷; 林建明; 張傳娟 材料導報 2007-04-15

13 膨脹蛭石/聚(丙烯酸鉀-丙烯酰胺)高吸水性復合材料的制備、性能及表征 唐群委; 林建明; 吳季懷; 張傳娟 功能材料 2006-09-20

14 國內高吸水性樹脂的應用現狀 唐群委; 林建明; 吳季懷; 郝旭 福建化工 2005-08-15

15 無機層狀礦物/聚合物高吸水性復合材料 唐群委; 林建明; 吳季懷; 郝旭; 吳子豹; 洪國瑩 應用化工 2005-06-28

16 高吸水性樹脂的研究現狀 唐群委; 林建明; 吳季懷; 郝旭; 吳子豹; 洪國瑩 福建化工 2005-06-15

10月10日下午，中國海洋大學第五屆研究生學術論壇材料分論壇閉幕式暨頒獎典禮在材料院舉行。材料院副院長陳守剛老師、材料系黨委副書記祝洪濤老師、唐群委教授、王煥磊副教授、黃明華副教授、高榮杰副教授、孫明亮副教授、劉盈副教授、材料系團委書記趙煒老師受邀參加此次活動，60余名研究生參與閉幕活動。

本屆論壇含五部分，分別是“專家講座”、“小組專題討論”、“論文征集”、“論文宣講及評審”和“論壇的交流及表彰”。閉幕式伊始，主持人首先回顧本屆論壇邀請到的五名國內外知名專家學者的報告，專家結合專業領域為同學們作精彩闡述，院系師生受益匪淺。此外，學院以2014級研究生為主體，根據分論壇主題和研究方向不同，劃分為3個學習小組，就“海洋應用”、“金屬腐蝕與防護”、“能源”三個不同主題進行學術前沿方向的資料收集、研究與討論，最終形成研究主題前沿研究情況的報告，并在閉幕式上與老師、同學們分享小組討論成果，以小組討論形式加強朋輩之間互相學習，促進學風建設。同時，論文征集活動也有序展開，共征集33篇論文，11名優秀學生帶著他們的17篇論文參加論文評比報告。最終，在陳守剛教授、唐群委教授等7名教師評委和2名學生代表評委的認真審查下，評選出一等獎一篇，二等獎兩篇，三等獎三篇以及數篇優秀論文獎，于文華、魏璐瑤等11名同學論文獲獎。

最后，陳守剛副院長總結本次論壇成果。通過舉辦學術論壇系列活動，邀請國內外專家開展學術報告，拓寬研究生視野，激發同學們的科研熱情，培養學生獨立思索創新思辨的學術品質，促進師生之間溝通交流。五年來，研究生學術論壇已發展成為院系特色品牌，今年更吸引了眾多優秀研究生參與，他希望今后大家能夠更認真地開展科研工作，收獲更多科研成績。 

來源：中國海洋大學材料科學與工程研究 2015-10-12

榮譽獎勵：

1. 2009年，獲盧嘉錫優秀研究生獎。

2. 2010年，獲華僑大學優秀博士學位論文一等獎。

3. 2010、2012年，入選Who’s Who in the World。

4. 2012年，入選中國海洋大學“青年英才工程”第一層次。

5. 2012年，獲福建省優秀博士學位論文一等獎。

6. 2013年，獲教育部自然科學獎二等獎（排名第五）。

7. 2013年，獲國際埃尼獎（Eni Award）提名。

8. 2014年，獲山東高等學校優秀科研成果獎二等獎（排名第一）。

9. 2014年，獲山東省研究生優秀科技創新成果獎三等獎（指導教師）。

10. 2015年，獲Cognizure的Nanoscience Research Leader獎。

11. 2015年，獲中國海洋大學“優秀教師”。

 

我國有豐富的太陽能資源，沒有技術創新，資源優勢不能形成產業，也不能轉化為競爭優勢。近日，在內蒙古呼和浩特召開的第五屆光伏產業大會上，中國海洋大學教授、國家科學技術獎評審專家唐群委指出，由于全球產能過剩，光伏產業唯有技術創新，走低成本、高效率的可持續發展之路。

唐群委認為，從2009年開始，我國的光伏產業接連遭到美國、歐盟的“雙反”調查，對產業的發展造成極大影響，使得我國光伏產業的發展步入了“寒冬期”，其根源來自光伏產業“兩頭在外”的發展模式。即高端的原材料依靠進口，大量的市場又在海外，光伏產業沒有形成高端原料生產和普及使用的良性循環系統。以及缺少原創性的技術創新，要想打破我國光伏產業面臨的難題，就必須在技術上敢于創新、積極創新。

目前，我國的光伏產品主要是技術相對成熟的硅太陽能電池電池新聞動態，盡管其光電轉換效率很高，但由于在生產及后處理中需要對硅材料進行提純與刻蝕，不僅工藝復雜、高耗能，而且會產生大量廢液，嚴重污染生態環境。2012年，唐群委在美國南卡羅萊納大學結束博士后工作毅然回國，帶領他的研究團隊從事染料敏化太陽能電池電池新聞的光陽極材料、對電極、電解質和染料等關鍵技術研究，以及高效染料敏化太陽能電池電池行業趨勢和動向的組裝與平臺測試。在國際上首次利用凝膠材料的三維網絡結構和獨特吸附性，將導電聚合物單體吸附于三維網絡內，并原位聚合形成互穿結構的導電凝膠，極大提高了凝膠電解質的活性，克服了液體電解質容易泄露的問題，使光電轉換效率達到7%以上。業內專家表示，該研究成果對于國內光伏產品的研發具有突破性的歷史意義，榮獲2012年高�？蒲袃炐愠晒�自然科學二等獎。

綠色環保的染料敏化太陽能電池，是一種模仿光合作用原理研制而成的新型太陽能電池，制作工藝相對簡單，生產成本僅為5―10元/峰瓦，是普通硅太陽能電池的四分之一。在整個工作過程中，除電流外，無其他物質釋放。為提高光電轉換效率和滿足產業化需要，唐群委教授的研發團隊攻克了染料敏化太陽能電池電池的最新相關信息的光電轉換效率較低這一技術難題，拉近了國內與國際最高水平的差距。并通過學科交叉，開創性地制備了一種新型復合光陽極材料，組裝的染料敏化太陽能電池的光電轉換效率逼近11%，成為目前國內的最高紀錄之一;他們制備的低鉑、非鉑對電極，相對于標準鉑對電極，對電解質的電催化效能提高了2―3倍，掌握了組裝低成本、高效率染料敏化太陽能電池的核心技術。

推進我國光伏產業技術創新是一項長期而且艱巨的任務，唐群委教授以產業技術需求為己任，以提高染料敏化太陽能電池電池新聞資訊的光電轉換效率為目標，為我國光伏產業的發展和突破作出了努力。

來源：鳳凰網 2014-07-07 

——訪中國海洋大學材料科學與工程研究院教授唐群委

0.25cm2到底有多小？還不到一個圖釘的面積。但是在這個小方寸間，卻有可以施展的大天地——占地球總能量99%的太陽能。人類正面對著最嚴重的能源危機——燃料能源即將枯竭！有沒有解決的辦法？有，那就是替代能源，或者說新能源。在新能源中，太陽能無疑有著巨大的優勢：清潔、不受地域限制，資源極其豐富并且永不枯竭。

目前，利用太陽能最直接有效的方式便是光伏轉換，即將太陽的光能直接轉換為電能而供人類使用。而目前的光伏產品主要是技術相對成熟的硅太陽能電池，盡管其光電轉換效率很高，但對硅材料的后處理會產生大量廢液，嚴重污染生態環境。長此以往，能源問題還沒解決，環境問題已經產生。怎么辦？中國海洋大學唐群委教授，給出了他的答案：染料敏化太陽能電池。

唐群委，1980年8月生于山東濰坊，歷經山東大學學士、華僑大學博士、法國斯特拉斯堡大學博士后、華僑大學訪問學者、美國南卡羅萊納大學博士后，于2012年正式學成歸來，成為了中國海洋大學材料科學與工程研究院的一名教授，碩士生導師。作為中國海洋大學最年輕的教授之一，唐群委肩負著高效染料敏化太陽能電池開發的重任。

染料敏化太陽能電池，一種模仿光合作用原理研制而成的新型太陽能電池，制作工藝相對簡單，生產成本僅為普通硅太陽能電池的1/4。在整個工作過程中，除電流外，無其他物質釋放。但目前的染料敏化太陽能電池中的光電轉換效率遠低于其理論值，因此，提高染料敏化太陽能電池光電轉換效率就成為唐群委教授及其團隊的主要目標。

唐群委教授長期從事新型材料和化學領域研究，在功能性水凝膠、自組裝導電多層膜、染料敏化太陽能電池等領域取得突出的研究成果，已在Adv Mater, Adv Energy Mater, Chem Commun,J Mater Chem等國際權威雜志發表SCI80余篇，申請國家發明專利11項。博士學位論文“導電多層膜的層層自組裝及性能研究”獲得2012年福建省優秀博士學位論文。

年輕且成績驕人。這些光環的背后，是敏銳的洞察力、艱辛的工作和大膽的創新：

——他首次提出“自組裝導電多層膜”的概念并成功發現自組裝導電多層膜的電導率隨組裝層數的滲濾現象，提出了新的導電機理，奠定了自組裝導電多層膜在光電子納米器件中應用的理論基礎。

——首次開發了低鉑、非鉑合金對電極材料，相對于全鉑對電極，對電解質的催化效果提高2～3倍，而成本僅為其1/50。

——開發了雙面同時透射提高染料敏化太陽能電池性能的技術，相對于單面透射，染料敏化太陽能電池的光電轉換效率提高了30%以上。

——針對光陽極中因入射太陽光衰減導致染料激發不完全的難題，設計了一系列具有明顯增透效果的光陽極材料，所制備的染料敏化太陽能電池的光電轉換效率提高至11%，達到國際先進水平。

但這僅僅是個開始，唐群委并沒有因已得成績而止步，染料敏化太陽能電池要真正實現產業化，還將面臨一段漫長的考驗。他深切的知道這項技術的發展和應用對于人類的能源危機意味著什么。

唐群委教授做的工作說小很“小”，他的研究對象是面積只有0.25cm2的小面積染料敏化太陽能電池。但他做的事情又很大，一旦這項技術取得突破，實現產業化，不僅能給國家帶來很大的經濟利益，還能為生態環境保護作出重大貢獻，甚至會徹底解決人類的能源危機。

作為80后，唐群委教授無疑還很年輕，年輕人更富創造力，所以他的未來充滿無限可能，而染料敏化太陽能電池的未來也是不可限量，我們共同期待著這兩者之間碰撞出最耀眼的火花!

來源：科學中國人 2013年第12期

唐群委在法國斯特拉斯堡一大從事博士后研究期間留影。

能源短缺與太陽能光伏發電絕對稱得上是當下的兩個熱門詞匯。

《世界能源統計評論》報告稱，我國化石能源儲備本世紀末將全面告急，石油資源將在本世紀30年代耗盡。同時，按照當前世界耗能每年5%的增加速度估算，煤炭、石油等化石燃料也將在百年后枯竭。人類要想生存，唯一的出路就是尋找新的可再生綠色能源。

現在，全球的目光都聚焦在太陽能上。這不僅因為它免費潔凈、分布廣泛、不受地域限制，更重要的是，它占地球總能量的99%，資源極其豐富，可謂是取之不盡用之不竭。據統計，地球上人類一年的能源總需求約為4.363×1020焦耳，而太陽每年通過大氣向地球輸送的能量高達3×1024焦耳，僅需其中的萬分之一就能滿足人類需求。

在我國，太陽能在我們三分之二的國土上，年輻射量超過60萬焦耳/平方厘米，每年地表吸收的太陽能約等于17萬億噸標準煤的能量，這相當于280倍中國的煤炭總儲量（中國煤炭的總儲量約為6000億噸），完全可以滿足我國未來穩定的能源需求。

毫無疑問，在風能、水能、生物能、地熱能等一系列綠色能源中，太陽能是最具發展潛力的可再生綠色能源，同時也是地球發展的可靠保證。

利用太陽能的最佳方式是光伏轉換。隨著全球能源短缺和環境污染等問題日益突出，太陽能光伏發電成為世界各國普遍關注和重點發展的新興產業，也成為繼IT、微電子產業之后，國際上又一爆炸式發展的行業。

我國太陽能光伏產業發展迅速，是為數不多的能夠同步參與國際競爭，并達到國際領先水平的行業。2011年我國多晶硅產量為8.4萬噸，自給率達到50%；太陽能電池產量21GW，同比增長100%，連續5年居全球第一；全年新增光伏裝機量3.5GW，同比增長400%。2012年這些數字依然持續上升。

這期間，美國對我國光伏產業實施“雙反”（反傾銷、反補貼），一度使我國光伏產業發展進入“寒冬”。然而，一波剛平一波又起。今年6月4日，歐盟宣布從6月6日至8月6日對我國光伏產品征收11.8%的臨時反傾銷稅，8月7日起這一數字將上升為47.6%。這對已處于寒冬的中國光伏產業來說，無疑又是致命的一擊。中國光伏產業要想破冰，出路何在？

反傾銷案出現以來，在人們還在就貿易保護、貿易壁壘爭執不休時，中國海洋大學教授唐群委卻看到了不一樣的發展機遇。他告訴本刊記者，光伏產品一般指的是目前已經實現產業化的硅太陽能電池，盡管其光電轉換效率很高，但由于在生產過程中需要對硅進行提純，不僅工藝復雜、高耗能，而且還會產生大量廢液廢渣，嚴重污染生態環境。歐盟國家的光伏產品價格很高，而我國光伏電池價格相對較低，這樣我們的產品就會對當地產品造成沖擊，加之歐盟各國注重環境保護，所以綜合各種原因，他們對華光伏發起反傾銷。

在唐群委看來，歐盟的反傾銷將會讓硅太陽能電池的生存面臨嚴重考驗，尋找一個能夠替代它的新型太陽能電池非常有必要，而他最看好的是染料敏化太陽能電池。

這是一種模仿光合作用原理研制而成的新型太陽能電池，全稱為“染料敏化納米晶薄膜太陽能電池”。與硅太陽能電池相比，這種電池的制備工藝相對簡單：用吸附染料的納米多孔二氧化鈦半導體膜作為光陽極，用鍍鉑的導電玻璃作為對電極，再選用適當的氧化還原電解質，就能制成一個簡單的染料敏化太陽能電池，當陽光照射到電池上，就能發電了。

據記者了解到的信息，染料敏化太陽能電池批量生產的成本大約在5～10元/峰瓦左右，而普通硅太陽能電池則在20~40元/峰瓦左右。相比之下，染料敏化太陽能電池的經濟優勢更明顯，更適合批量生產，用來滿足城市居民以及廣大農村的需要，特別是對解決我國近7000萬邊遠地區的人口用電問題更有實際意義。

從戰略角度看，我國是能源大國，電力的短缺勢必會對我國經濟發展產生嚴重影響。但無論是核電還是火電，所使用的燃料不僅有限，還會對環境造成嚴重污染，若要兼顧經濟、環境、社會的協調發展，開發利用太陽能是最佳選擇。但面對歐盟、美國的反傾銷，硅太陽能電池的生存舉步維艱，這讓染料敏化太陽能電池充滿了無限可能。

唐群委說：“效率高、成本低廉、制備工藝簡單、清潔無污染等特點，讓染料敏化太陽能電池成為目前業界公認的最具商業價值的太陽能電池之一。但是，與硅太陽能電池高達30%的光電轉化效率相比，染料敏化太陽能電池的轉化效率遜色了不少。如果不能實現更高的光電轉化效率，這將會成為限制其發展的致命硬傷。”

國際上有關染料敏化太陽能電池的研究始于上世紀80年代。1991年，瑞士洛桑聯邦理工大學Gratzel教授領銜的研究小組，首次以納米多孔二氧化鈦為半導體陽極，釕絡合物為敏化染料，I-/I3-為氧化還原電解質，鉑為對電極，開發出了染料敏化太陽能電池樣機，在國際上引發強烈關注。1997年，該課題組又率先使該電池的轉化效率達到了11%。2011年，他們又將這一數字刷新為12%。此后，為了追求更高的轉換效率，歐、美、日等發達國家投入大量資金用于研究，但直到現在，仍然沒有打破這個記錄。

唐群委告訴記者，我國染料敏化太陽能電池研究主要以華僑大學副校長吳季懷教授以及中科院長春應用化學研究所王鵬研究員為代表，在液體電解質、準固態電解質等領域取得了長足進展，光電轉化效率在6%～9%之間，離國際最高水平仍有一定差距。而縮短這個差距正是唐群委實驗室的科研目標。

2004年，唐群委首次接觸染料敏化太陽能電池，他把大部分精力都用來觀察和思考相關問題，例如為什么從1997年至今的16年間，人們一直沒法突破染料敏化太陽能電池12%的轉化記錄，怎樣才能突破這個技術壁壘。

2012年8月，唐群委加盟中國海洋大學，組建了自己的科研團隊和實驗室，開始全身心投入相關研究。他帶領學生將曾經的設想和構思付諸實際研究，證實了一個又一個想法的可行性。

首先，他們針對我國在染料敏化太陽能電池領域與國際最高水平的差距，大膽采用新工藝和新材料制備了一種新型復合光陽極材料，用它組裝的染料敏化太陽能電池的光電轉化效率達到了10.2%，這很可能是目前國內的最高紀錄。但唐群委認為，這個數字僅僅只是逼近，但沒有達到或超過國際最高紀錄，還有進一步優化上升的空間。正是因為有這樣的上升空間，才激發了許多科研人員的挑戰欲望。

唐群委研究染料敏化太陽能電池至今已有9年。他告訴記者，光陽極的研究對提高電池轉化效率至關重要，他們實驗室對此十分關注。同時，他們還關注雙面投射技術。“一般的太陽能電池采用的是單面投射，太陽光的利用率較低，激發的電子密度也比較低，光電轉化效率自然不高。”唐群委說，“如果通過分光設計，將一束太陽光分為兩束，由雙面同時入射，兩面的太陽光互相補償，就能提高太陽光的利用率，從而加速染料激發電子的速度，提高光電轉化效率。”

基于這種構想，唐群委及其團隊率先采用雙面投射技術將聚苯胺對電極基染料敏化太陽能電池的光電轉化效率由6%提高到了8.2%，并極大地降低了染料敏化太陽能電池的成本。目前，他們已將這一成果投稿給Nature子刊，文稿正在進一步修改中。唐群委還告訴記者，硅太陽能電池的產業化正是得益于雙面透光技術的應用，因此，如果這一技術能夠應用到染料敏化太陽能電池領域，很可能推動其產業化進程。

9年間，為了突破染料敏化太陽能電池光電轉效率的技術難點，唐群委還做了很多相關研究，這其中包括新型導電凝膠電解質的開發。

2004年，唐群委在國際上首次利用超吸水材料的三維網絡機結構和獨特吸附性，將苯胺、吡咯等導電聚合物單體吸附于三維網絡內，原位聚合形成了互穿結構的導電水凝膠材料。隨后，他又進一步改良這種材料的性質，使其能夠牢固吸附I-/I3-電解質，并將其應用于染料敏化太陽能電池的研究，極大地提高了凝膠電解質的活性，克服了液體電解質容易泄露的問題，在很大程度上提高了電池的光電轉化效率。這是唐群委最為滿意的成果之一，2012年獲得了教育部高等學校自然科學獎二等獎。

近幾年，國家對光伏產業扶持力度不斷加大，尤其在太陽能電池研究領域，資助的金額每年都在增加。于是，難免有人對染料敏化太陽能電池研究產生“它的效率真能高于12%，還是說只是炒作的噱頭”的質疑。

唐群委告訴記者，理論上，這種電池的光電轉化效率最高能達到29%，完全能與硅太陽能電池媲美。但為什么一直不能突破國際最高值，需要考慮很多因素，它的每一個組成部分，包括光陽極使用的二氧化鈦膜、電解質溶液以及對電極使用的材料等，目前都存在或大或小的問題，一旦這些問題都被克服，相信這種電池的光電轉化效率將會有質的飛躍。這正是唐群委以及眾多太陽能電池研究人員勵志要解決的難題。

染料敏化太陽能電池要真正實現產業化，還將面臨一段漫長的考驗。唐群委認為，如果要大面積應用，轉化效率至少要達到5%。如此一來面臨的就不僅是技術挑戰，還有工藝上的挑戰。他說：“10.2%的效率是在實驗室里實現的，而實際應用的面積比這個大幾十甚至幾百倍。在小面積的情況下，我們可以很容易制備出致密、均勻的二氧化鈦膜，但面積擴大，膜產生缺陷的幾率也會隨之增加。以目前的技術，要實現染料敏化太陽能電池的大面積應用難度較大。”

唐群委表示，下一步課題組將繼續優化電池的性能，爭取把光電轉化效率提高到11%，取得技術上的突破；另一方面，要實現該電池的應用，必須通過中試考驗，面積比實驗室大很多。所以課題組還將開展大面積的染料敏化太陽能電池研究，如果能夠使其效率達到5%～7%，課題組就將與相關單位探討產業化合作。

狄更斯說：“這是最美好的時代，也是最糟糕的時代。”

全球眾多實力非凡的科研機構都盯著染料敏化太陽能電池這塊“蛋糕”，競爭必然慘烈。唐群委要想突破保持了16年的最高記錄，搶占這塊高地，不僅要面對技術上的超高挑戰，還要與眾多競爭者展開一場殊死較量。這似乎有點兒“糟糕”。

然而，國家對光伏產業十分重視，在政策上、資金上都給予這項事業很多的支持和鼓勵。更何況，染料敏化太陽能電池仍沒有產業化，這其中孕育著無限機遇和希望。這對唐群委的研究來說，無疑又是美好的。

“染料敏化太陽能電池如果實現產業化，不僅能給國家帶來很大的經濟利益，還能為生態環境保護作出重大貢獻。更重要的是，這也許是我國光伏產業破冰的出路所在。無論如何艱難，課題組都將以縮小與國際的差距為目標，繼續向更高端的方向前進。”唐群委的意志很堅定。

來源：科技創新與品牌 2013-07-01