孙宝全 教授-尊龙凯时

发布时间:2023-05-16访问量:26361





孙宝全  (baoquan sun)

2008/10-       苏州大学功能纳米与软物质材料研究院,教授/博士生导师;

2007/05-2008/10,美国能源部洛斯安洛莫斯国家实验室(lanl),博士后;

2002/08-2007/04,英国剑桥大学卡文迪许实验室,博士后;

1997/09-2002/07,北京清华大学化学系,硕博研究生;

1993/09-1997/07,山东青岛科技大学应用化学系,本科生;

 

课题组主要成员:宋涛副教授王玉生副教授,邵贝贝博士

 

欢迎访问课题组网页

 

主要研究方向:

  • 半导体材料与器件,柔性电子材料,纳米硅结构,太阳能电池,新型发光二级管及显示技术,共轭高分子和半导体纳米结构的光电特性及器件,光电薄膜表面和界面物理;

  • 硅基光伏电池,电池器件结构设计、电荷传输机理、钝化修饰,新型金属化技术及材料研发,topcon.电池,hjt电池;

  • 新型发光二极管或光伏电池的器件性质及相关的物理机制,主要包括基于半导体纳米结构的发光二极管和光伏电池如硅基/钙钛矿叠层电池,基于相关器件的表面与界面分析;

  • 半导体纳米结构的光电性质界面调控,通过控制半导体纳米结构的形貌和表面修饰,调控其光诱导的电荷产生、解离、复合和电荷迁移机制;

  • 柔性器件,柔性发光显示材料与器件柔性能源器件,柔性导电材料与衰减机理

 

主要荣誉:

  • 2016年度入选英国皇家学会材料领域前1%中国作者名单;

  • 2016年获得nano research最佳论文奖;

  • 2017年获得江苏省科学技术一等奖;

  • 2018-连续两年入选爱思唯尔(elsevier)中国高被引学者(chinese most cited researchers)榜单(材料科学);

  • 2019年获得江苏省科学技术二等奖;

  • 2019年入选金鸡湖科技领军人才计划;

  • 2019 年入选国家级人才计划

 

近期代表性论文(他引>17000 , h-index: 70)

 

已经发表“sci”收录文章200余篇,相关工作曾经被nature photonicsnature climate change, 泰晤士报、the guardian、美国化学化学会、新华网等国内外200多家科学杂志或媒体报道。

 

50. zou, y.; teng, p.; xu, w.*; zheng, g.; lin, w.; yin, j.; kobera, l.; abbrent, s.; li, x.; steele, j. a.; solano, e.; roeffaers, m. b. j.; li, j.; cai, l.; kuang, c.; scheblykin, i. g.; brus, j.; zheng, k.; yang, y.; mohammed, o. f.; bakr, o. m.; pullerits, t.; bai, s.; sun, b.*; gao, f.*, manipulating crystallization dynamics through chelating molecules for bright perovskite emitters. nature communications 2021,12(1), 4831

49. li, p.; fang, j.; wang, y.; manzhos, s.; cai, l.; song, z.; li, y.; song, t.; wang, x.; guo, x.; zhang, m*.; ma, d*.; sun, b*., synergistic effect of dielectric property and energy transfer on charge separation in non-fullerene-based solar cells. angewandte chemie international edition 2021,60 (27), 15054-15062.

48. wang, y*.; zhang, g.; wu, h.; sun, b*, simultaneously harvesting friction and solar energy via organic/silicon heterojunction with high directcurrent generation. adv energy mate, 2021,11 (21), 2100578.

47. shao, b.; song, z.; chen, x.; wu, y.; li, y.; song, c.; yang, f.; song, t.; wang, y.*; lee, s. t*.; sun, b.*,bioinspired hierarchical nanofabric electrode for silicon hydrovoltaic device with record power output. acs nano 2021,15 (4), 7472-7481.

46. liu, y.; cai, l.; xu, y.; li, j.; qin, y.; song, t.; wang, l.; li, y.; ono, l. k.; qi, y.*; sun, b*., in-situ passivation perovskite targeting efficient light-emitting diodes via spontaneously formed silica network. nano energy 2020,78, 105134.

45. liu, y.; li, y.; wu, y.; yang, g.; mazzarella, l.; procel-moya, p.; tamboli, a. c.; weber, k.; boccard, m.; isabella, o.; yang, x.*; sun, b.*, high-efficiency silicon heterojunction solar cells: materials, devices and applications. materials science and engineering: r: reports 2020, 142, 100579.

44. wu, t.; li, j.; zou, y.; xu, h.; wen, k.; wan, s.; bai, s.*; song, t.*; mcleod*, j. a.; duhm, s.; gao, f.; sun, b.*, high-performance perovskite light-emitting diode with enhanced operational stability using lithium halide passivation. angewandte chemie international edition 2020,59 (10), 4099-4105.

43. wang, r.; wang, y.; wu, c.; zhai, t.; yang, j.; sun, b.*; duhm, s.*; koch, n.*, direct observation of conductive polymer induced inversion layer in nsi and correlation to solar cell performance. advanced functional materials 2020,30 (4), 1903440.

42. qin, y.; wang, y.; sun, x.; li, y.; xu, h.; tan, y.; li, y.; song, t.; sun, b.*, constant electricity generation in nanostructured silicon by evaporation-driven water flow. angew chem int ed engl 2020,59 (26), 10619-10625.

40.  liu, y.; li, y.; wu, y.; yang, g.; mazzarella, l.; procel-moya, p.; tamboli, a. c.; weber, k.; boccard, m.; isabella, o.; yang, x.*; sun, b.*, high-efficiency silicon heterojunction solar cells: materials, devices and applications. materials science and engineering: r: reports 2020,142, 100579.

39. liu, y.; cai, l.; xu, y.; li, j.; qin, y.; song, t.; wang, l.; li, y.; ono, l. k.; qi, y.*; sun, b.*, in-situ passivation perovskite targeting efficient light-emitting diodes via spontaneously formed silica network. nano energy 2020,78, 105134.

38. ban, m.; zou, y.; rivett, j. p. h.; yang, y.; thomas, t. h.; tan, y.; song, t.; gao, x.; credington, d.; deschler, f.; sirringhaus, h.; sun, b.*, solution-processed perovskite light emitting diodes with efficiency exceeding 15% through additive-controlled nanostructure tailoring. nature communications 2018,9 (1), 3892.

37. wu, c.; wu, t.; yang, y.; mcleod, j. a.; wang, y.; zou, y.; zhai, t.; li, j.; ban, m.; song, t.; gao, x.; duhm, s.; sirringhaus, h.; sun, b.*, alternative type two-dimensional-three-dimensional lead halide perovskite with inorganic sodium ions as a spacer for high-performance light-emitting diodes. acs nano 2019,13 (2), 1645-1654.

36. tan, y.; li, r.; xu, h.; qin, y.; song, t.; sun, b.*., ultrastable and reversible fluorescent perovskite films used for flexible instantaneous display. advanced functional materials 2019,0 (0), 1900730.

35. liu, y.; cheng, p.; li, t.; wang, r.; li, y.; chang, s. y.; zhu, y.; cheng, h. w.; wei, k. h.; zhan, x.; sun, b.*; yang, y., unraveling sunlight by transparent organic semiconductors toward photovoltaic and photosynthesis. acs nano 2019,13 (2), 1071-1077.

34. liu, r.; kuang, x.; deng, j.; wang, y.-c.; wang, a. c.; ding, w.; lai, y.-c.; chen, j.; wang, p.; lin, z.; qi, h. j.; sun, b.*; wang, z. l.*, shape memory polymers for body motion energy harvesting and self-powered mechanosensing. advanced materials 2018, 1705195.

33. hu, h.; wu, l.; tan, y.; zhong, q.; chen, m.; qiu, y.; yang, d.; sun, b.*; zhang, q.; yin, y., interfacial synthesis of highly stable cspbx3/oxide janus nanoparticles. j am chem soc 2018,140 (1), 406-412.

32. zou, y.; ban, m.; cui, w.; huang, q.; wu, c.; liu, j.; wu, h.; song, t.; sun, b.*, a general solvent selection strategy for solution processed quantum dots targeting high performance light-emitting diode. advanced functional materials 2017,27 (1), 1603352.

31. wu, l.; hu, h.; xu, y.; jiang, s.; chen, m.; zhong, q.; yang, d.; liu, q.; zhao, y.; sun, b.*; zhang, q.*; yin, y.*, from nonluminescent cs4pbx6 (x = cl, br, i) nanocrystals to highly luminescent cspbx3 nanocrystals: water-triggered transformation through a csx-stripping mechanism. nano lett 2017,17 (9), 5799-5804.

30. wu, c.; zou, y.; wu, t.; ban, m.; pecunia, v.; han, y.; liu, q.; song, t.; duhm, s.*; sun, b.*, improved performance and stability of all-inorganic perovskite light-emitting diodes by antisolvent vapor treatment. advanced functional materials 2017,27 (28), 1700338.

29. wang, y.; xia, z.; liu, l.; xu, w.; yuan, z.; zhang, y.; sirringhaus, h.; lifshitz, y.; lee, s. t.; bao, q.*; sun, b.*, the light-induced field-effect solar cell concept - perovskite nanoparticle coating introduces polarization enhancing silicon cell efficiency. advanced materials 2017,29 (18), 1606370.

28. liu, y.; zhang, j.; wu, h.; cui, w.; wang, r.; ding, k.; lee, s.-t.; sun, b.*, low-temperature synthesis tiox passivation layer for organic-silicon heterojunction solar cell with a high open-circuit voltage. nano energy 2017,34 (supplement c), 257-263.

27. liu, r.; wang, j.; sun, t.; wang, m.; wu, c.; zou, h.; song, t.; zhang, x.; lee, s.-t.; wang, z. l.*; sun, b.*, silicon nanowire/polymer hybrid solar cell-supercapacitor: a self-charging power unit with a total efficiency of 10.5%. nano letters 2017,17 (7), 4240-4247.

26. liu, j. w.; ji, y. j.; liu, y. q.; xia, z. h.; han, y. j.; li, y. y.*; sun, b.*., doping-free asymmetrical silicon heterocontact achieved by integrating conjugated molecules for high efficient solar cell. adv energy mater 2017,7 (19), 1700311.

25. han, y.; liu, y.; yuan, j.*; dong, h.; li, y.; ma, w.; lee, s.-t.; sun, b.*, naphthalene diimide-based n-type polymers: efficient rear interlayers for high-performance silicon–organic heterojunction solar cells. acs nano 2017,11 (7), 7215-7222.

24. chen, m.; zou, y.; wu, l.; pan, q.; yang, d.; hu, h.; tan, y.; zhong, q.; xu, y.; liu, h.; sun, b.*; zhang, q.*, solvothermal synthesis of high-quality all-inorganic cesium lead halide perovskite nanocrystals: from nanocube to ultrathin nanowire. advanced functional materials 2017,27 (23), 1701121.

23. zhao, s.; pi, x.*; mercier, c.; yuan, z.; sun, b.*; yang, d., silicon-nanocrystal-incorporated ternary hybrid solar cells. nano energy 2016,26, 305-312.

22. zhang, y.; wang, y.; xu, z.-q.; liu, j.; song, j.; xue, y.; wang, z.; zheng, j.; jiang, l.; zheng, c.; huang, f.; sun, b.*; cheng, y.-b.; bao, q.*, reversible structural swell–shrink and recoverable optical properties in hybrid inorganic–organic perovskite. acs nano 2016,10 (7), 7031-7038.

21. wu, s.; cui, w.; aghdassi, n.; song, t.; duhm, s.; lee, s.-t.; sun, b.*, nanostructured si/organic heterojunction solar cells with high open-circuit voltage via improving junction quality. advanced functional materials 2016,26 (28), 5035-5041.

20. wang, y.-k.; yuan, z.-c.; shi, g.-z.; li, y.-x.; li, q.; hui, f.; sun, b.*; jiang, z.-q.*; liao, l.-s.*, dopant-free spiro-triphenylamine/fluorene as hole-transporting material for perovskite solar cells with enhanced efficiency and stability. advanced functional materials 2016,26 (9), 1375-1381.

19. sun, b.*; shao, m.; lee, s.-t., nanostructured silicon used for flexible and mobile electricity generation. advanced materials 2016,28 (47), 10539-10547.

18. liu, y.; zhang, z.; xia, z.; zhang, j.; liang, f.; li, y.; song, t.; yu, x.; lee, s.-t.; sun, b.*, high performance nanostructured silicon-organic quasi p-n junction solar cells via low-temperature deposited hole and electron selective layer. acs nano 2016,10 (1), 704-712.

17. cui, w.; wu, s.; chen, f.; xia, z.; li, y.; zhang, x.-h.; song, t.; lee, s.-t.; sun, b.*, silicon/organic heterojunction for photoelectrochemical energy conversion photoanode with a record photovoltage. acs nano 2016,10 (10), 9411-9419.

16. zhang, y.; cui, w.; zhu, y.; zu, f.; liao, l.; lee, s.-t.; sun, b.*, high efficiency hybrid pedot:pss/nanostructured silicon schottky junction solar cells by doping-free rear contact. energy & environmental science 2015,8 (1), 297-302.

15. yuan, z.; wu, z.; bai, s.; xia, z.; xu, w.; song, t.; wu, h.; xu, l.; si, j.; jin, y.; sun, b.*, hot-electron injection in sandwiched tiox-au-tiox structure for high performance planar perovskite solar cells. adv energy mater 2015,5 (10), 1500038.

14. bai, s.; jin, y.*; liang, x.; ye, z.; wu, z.; sun, b.*; ma, z.; tang, z.; wang, j.; würfel, u.; gao, f.; zhang, f., ethanedithiol treatment of solution-processed zno thin films: controlling the intragap states of electron transporting interlayers for efficient and stable inverted organic photovoltaics. adv energy mater 2015,5 (5), 1401606.

13. zhang, y.; zu, f.; lee, s.-t.; liao, l.; zhao, n.; sun, b.*, heterojunction with organic thin layers on silicon for record efficiency hybrid solar cells. adv energy mater 2014,4 (2), 1300923.

12. zhang, j.; song, t.; shen, x.; yu, x.; lee, s.-t.; sun, b.*, a 12%-efficient upgraded metallurgical grade silicon–organic heterojunction solar cell achieved by a self-purifying process. acs nano 2014,8 (11), 11369-11376.

11. liu, r.; lee, s.-t.; sun, b.*, 13.8% efficiency hybrid si/organic heterojunction solar cells with moo3 film as antireflection and inversion induced layer. advanced materials 2014,26 (34), 6007-6012.

10. bai, s.; cao, m.; jin, y.*; dai, x.; liang, x.; ye, z.; li, m.; cheng, j.; xiao, x.; wu, z.; xia, z.; sun, b.*; wang, e.; mo, y.; gao, f.; zhang, f., low-temperature combustion-synthesized nickel oxide thin films as hole-transport interlayers for solution-processed optoelectronic devices. adv energy mater 2014,4 (6), 1301460.

9.  gu, x.; cui, w.; li, h.; wu, z.; zeng, z.; lee, s.-t.; zhang, h.; sun, b.*, a solution-processed hole extraction layer made from ultrathin mos2nanosheets for efficient organic solar cells. adv energy mater 2013,3 (10), 1262-1268.

8.  song, t.; lee, s. t.; sun, b.*, silicon nanowires for photovoltaic applications: the progress and challenge. nano energy 2012,1, 654-673.

7. shen, x.; sun, b.*; liu, d.; lee, s.-t.*, hybrid heterojunction solar cell based on organic–inorganic silicon nanowire array architecture. journal of the american chemical society 2011,133 (48), 19408-19415.

6. zou, g.; luo, h.; ronning, f.; sun, b.*; mccleskey, t. m.; burrell, a. k.; bauer, e.; jia, q. x.*, facile chemical solution deposition of high-mobility epitaxial germanium films on silicon. angewandte chemie international edition 2010,49 (10), 1782-1785.

5. shen, x.; sun, b.*; yan, f.; zhao, j.; zhang, f.; wang, s.; zhu, x.; lee, s.*, high-performance photoelectrochemical cells from ionic liquid electrolyte in methyl-terminated silicon nanowire arrays. acs nano 2010,4 (10), 5869-5876.

4.  sun, b.; findikoglu, a. t.; sykora, m.; werder, d. j.; klimov, v. i., hybrid photovoltaics based on semiconductor nanocrystals and amorphous silicon. nano letters 2009,9 (3), 1235-1241.

3.  sun, b.*; sirringhaus, h., surface tension and fluid flow driven self-assembly of ordered zno nanorod films for high-performance field effect transistors. journal of the american chemical society 2006,128 (50), 16231-16237.

2. sun, b.*;; sirringhaus, h., solution-processed zinc oxide field-effect transistors based on self-assembly of colloidal nanorods. nano letters2005, 5 (12), 2408-2413.

1. sun, b.; marx, e.; greenham, n. c.*, photovoltaic devices using blends of branched cdse nanoparticles and conjugated polymers. nano letters2003, 3 (7), 961-963.

 

讲述课程:

 

新能源材料与技术(36课时,本科生,每年春季学期);

光伏器件物理 (36课时,研究生,每年春季学期)

 

招生及招聘

本课题组在半导体器件包括发光二极管、太阳电池和薄膜场效应管方面具有良好的实验条件,欢迎有化学及化工、物理学、电子学、材料学和新能源等相关专业的本科生和硕士生报考,欢迎本科生来课题组学习和交流,同时欢迎博士生和博士后加盟。

 

尊龙凯时的联系方式

e-mail: bqsun@suda.edu.cn

website:

 

 

tel: 86-512-65880951
 fax: 86-512-65882846

苏州大学纳米科学技术学院910302a


责任编辑:杨娟







/


网站地图