廖良生
教授、博士生导师
1982.1毕业于江西大学(现为南昌大学)物理系,获理学学士学位;1982.1-1993.9先后任江西大学物理系助教、讲师、副教授(其间于1989.6-1990.9,在美国California State University, Northridge进修访问);1988.6、1996.5先后获南京大学理学硕士学位和理学博士学位;1996.3-1997.12,在复旦大学物理系和应用表面物理国家重点实验室从事博士后研究;随后留任副教授(其间于1998.12-2000.6,任香港城市大学超金刚石及先进薄膜研究中心特邀研究员);2000.12-2009.3,任美国柯达公司研发部研究员,从事有机半导体器件和材料研究;2009.3回国全职加盟苏州大学,任苏州大学功能纳米与软物质研究院教授、博士生导师,曾任苏州大学功能纳米与软物质研究院副院长(2009.3-2016.9);现兼任江苏省产业技术研究院有机光电技术研究所执行所长。
课题组网页:www.funsom.com
研究领域和招生方向:
(1)有机光电器件:重点研究和制备高效率长寿命有机固态照明器件和有机发光显示器件、有机太阳能电池、高效钙钛矿太阳能电池等;
(2)有机光电物理:重点研究有机光电器件和材料的载流子注入、传输、复合、界面缺陷、电荷积累、能级匹配等,力求为有机发光器件和太阳能电池性能的改善和材料的设计提供重要依据;
(3)有机光电材料:重点针对有机光电器件,设计并合成新型有机发光材料、新型有机光伏材料和新型有机微纳晶体材料,力求不断提高有机光电器件的工作性能。
本研究组招收硕士研究生和博士研究生。招生专业包括“物理(070200)”、“化学(070300)”、和“材料科学与工程(080500)”。我组同时招收上述方向的博士后研究人员,并提供有竞争力的优厚待遇。联系电话:0512-65880945;电子邮箱:lsliao@suda.edu.cn
主要成果和技术贡献:
(1)申请各国专利300多项,获授权的中国专利80多项,获授权的美国专利42项;
(2)发表SCI学术论文300多篇,论文的引用次数为9500多次(SCI h-index = 49),2014年至2018年连续五年进入Elsevier发布的“中国高被引学者榜单”。
(3)发明了具有全有机连接层结构的叠层(Tandem)OLED,制备了高性能的OLED显示器件和OLED照明器件,曾为美国柯达公司OLED显示和照明技术的发展做出过重要贡献;回国后,主持设计和制造了中国第一条国产OLED生产线,并且制备了国内发光面积最大的OLED照明面板;
(4)制备了高效率低铅钙钛矿太阳能电池(PSC)、高效有机太阳能电池(OPV)、高效量子点发光二极管(QLED)和高效近红外有机发光二极管(NIR OLED)。
近年来,共主持8项国家科研课题,其中包括主持国家“863”计划重大项目课题1项,国家重点研发计划项目1项,国家科技重大专项(02专项)子课题1项,主持国家自然科学基金重点项目1项、国际(地区)合作与交流项目1项、面上项目3项。
主要荣誉和奖励:
2018年获高等教育国家级教学成果奖二等奖(排名第五)
2017年获教育部高等学校科学研究优秀成果奖技术发明二等奖(排名第一)
2017年获江苏省教学成果奖(高等教育类)特等奖(排名第六)
2015年被评为苏州市劳动模范
2014年获国家半导体照明工程研发及产业联盟颁发的“十年贡献奖”
2013年起享受国务院特殊津贴
2013年获 江苏侨界贡献奖
2012年获苏州市优秀教育工作者称号
获苏州市2011年度十佳魅力科技人物入围奖
2010年、2011年分别获苏州大学重大项目个人杰出贡献奖
2010年被评为苏州工业园区首届海外高层次领军人才
2009年被评为苏州市紧缺人才
2009年12月入选江苏省高层次创新创业人才引进计划
获2007年美国柯达公司 杰出发明人奖
获2006年国际信息显示学会(SID)最佳论文奖
获1998年江苏省科学技术进步一等奖(排名第六)
主要学术兼职:
美国《Applied Physics Letters》副主编(2015-)
《影像科学与光化学》学报编辑委员会委员(2011-2018)
《International Journal of Photonics》客座编辑(2014)
“十二五”国家科技重点专项(半导体照明专项)专家组专家(2012-2015)
江苏省自然科学基金委员会信息学科组专家(2010-)
中国有色金属学会宽禁带半导体专业委员会委员(2016-)
美国SID学会半导体照明分会委员(2017-)
苏州大学学术委员会副主任委员(2015-)
论文发表情况:
https://zz.glgoo.top/citations?hl=zh-CN&user=EgHWH8MAAAAJ
代表性论文(*为通迅作者):
20. C. C. Zhang, Z. K. Wang*, S. Yuan, R. Wang, M. Li, M. F. Jimoh, L. S. Liao*, Y. Yang*, “Polarized ferroelectric polymers for high‐performance perovskite solar cells”, Adv. Mater. 31, 1902222 (2019).
19. M. Li, Y. G. Yang, Z. K. Wang*, T. Kang, Q. Wang, S. Turren‐Cruz, X. Y. Gao, C. S. Hsu, L. S. Liao* A. Abate*, “Perovskite grains embraced in a soft fullerene network make highly efficient flexible solar cells with superior mechanical stability”, Adv. Mater. 31, 1901519 (2019).
18. M. P. Zhuo, J. J. Wu, X. D. Wang*, Y. C. Tao, Y. Yuan, L. S. Liao*, “Hierarchical self-assembly of organic heterostructure nanowires”, Nat. Commun. 10, 3839 (2019).
17. S. Yuan, Z. K. Wang*, L. X. Xiao, C. F. Zhang, S. Y. Yang, B. B. Chen, H. T. Ge, Q. S. Tian, Y. Jin, L. S. Liao*, “Optimization of low‐dimensional components of quasi‐2D perovskite films for deep‐blue light‐emitting diodes”, Adv. Mater. 1904319 (2019).
16. Y. L. Zhang, Q. Ran, Q. Wang, Y. Liu, C. Hänisch, S. Reineke, J. Fan*, L. S. Liao*, “High‐efficiency red organic light‐emitting diodes with external quantum efficiency close to 30% based on a novel thermally activated delayed fluorescence emitter”, Adv. Mater. 31, 1902368 (2019).
15. S. Yuan, Z. K. Wang*, M. P. Zhuo, Q. S. Tian, Y. Jin, L. S. Liao*, Self-assembled high quality CsPbBr3 quantum dot films toward highly efficient light-emitting diodes, ACS Nano, 12, 9541 (2018).
14. M. Li, Z. K. Wang*, M.P. Zhuo, Y. Hu, K. H. Hu, Q. Q. Ye, S. M. Jain, Y. G. Yang, X. Y. Gao, L. S. Liao*, Pb-Sn-Cu ternary organometallic halide perovskite solar cells, Adv. Mater. 30, 1800258 (2018).
13. L. S Cui, S. B. Ruan, F. Bencheikh, R. Nagata, L. Zhang, K. Inada, H. Nakanotani, L. S. Liao*, and C. Adachi*, “Long-lived efficient delayed fluorescence organic light-emitting diodes using n-type hosts”,
Nat. Commun. 8, 2250 (2017).
12. Y. Li, L. Zhong, B. Gautam, H. J. Bin, J.D. Lin, F.P. Wu, Z. Zhang, Z.Q. Jiang*, Z. G. Zhang*, K. Gundogdu*, Y. F. Li, and L. S. Liao*, “A near-infrared non-fullerene electron acceptor for high performance polymer solar cells” Energy Environ. Sci. 10, 1610 (2017).
11. M. K. Fung, Y. Q. Li, and L. S. Liao*, “Tandem organic light-emitting diodes”,
Adv. Mater. 28, 10381 (2016).
10. L. S. Cui, Y. L. Deng, D. P. K. Tsang, Z. Q. Jiang, Q. Zhang*, L. S. Liao*, C. Adachi*, “Controlling synergistic oxidation processes for efficient and stable blue thermally activated delayed fluorescence devices”, Adv. Mater. 28, 7620 (2016).
9. Z. K. Wang, M. Li, Y. G. Yang, Y. Hu, H. Ma, X. Y. Gao*, L. S. Liao*, “High efficiency Pb–In binary metal perovskite solar cells”, Adv. Mater. 28, 6695 (2016).
8. Z. K. Wang, X. Gong, M. Li, Y. Hu, J. M. Wang, H. Ma, L. S. Liao*, “Induced crystallization of perovskites by a perylene underlayer for high-performance solar cells” ACS Nano. 10, 5479 (2016).
7. L. S. Liao, Shuit-Tong Lee*, “Materials science in China”, Nat. Rev. Mater. 1, 16025 (2016).
6. X. B. Shi, Y. Hu, B. Wang, L. Zhang, Z. K. Wang*, L. S. Liao*, “Conductive inorganic–organic hybrid distributed Bragg reflectors”, Adv. Mater. 27, 6696 (2015).
5. L. S. Cui, Y. M. Xie, Y. K. Wang, C. Zhong, Y. L. Deng, X. Y. Liu, Z. Q. Jiang*, L. S. Liao*, “Pure hydrocarbon hosts for ≈100% exciton harvesting in both phosphorescent and fluorescent light-emitting devices”, Adv. Mater. 27, 4213 (2015).
4. Y. L. Lei, L. S. Liao*, and S. T. Lee*, “Selective growth of dual-color-emitting heterogeneous microdumbbells composed of organic charge-transfer complexes”,
J. American Chem. Soc.135, 3744 (2013).
3. Y. L. Lei, Y. Jin, D. Y. Zhou, W. Gu, X. B. Shi, L. S. Liao*, and S. T. Lee*, “White-light emitting microtubes of mixed organic charge-transfer complexes”, Adv. Mater., 24, 5345 (2012).
2. L. S. Liao*, W. K. Slusarek, T.K. Hatwar, M.L. Ricks, and D.L. Comfort, “Tandem organic light-emitting diode using hexaazatriphenylene hexacarbonitrile in the intermediate connector”, Adv. Mater. 20(2), 324 (2008).
1. L. S. Liao*, K.P. Klubek, and C.W. Tang, “High-efficiency tandem organic light-emitting diodes”,
Appl. Phys. Lett. 84(2), 167 (2004).
代表性美国专利:
20. L.S.Liao, M.W.Culver, and C.W.Tang, “Fluorocarbon electrode modification layer”,
US7,799,439 B2 (September 21, 2010).
19. L.S.Liao, W.Slusarek, M.Ricks, R.H.Young, and D.L.Comfort,
“OLED electron-injecting layer”,US7,629,741 B2 (December 8, 2009).
18. L. S. Liao, T. K. Hatwar, K. P. Klubek, D. L. Comfort, and C. W. Tang,
“White OLEDs having a color compensated electroluminescent unit”, US7,560,862 B2 (July 14, 2009).
17. L.S. Liao, K.P. Klubek, and C.W. Tang, “Color organic OLED device”,
US7,528,545 B2 (May 5, 2009).
16. L.S. Liao, W.Slusarek, T.K. Hatwar, M.L.Ricks, and D.L. Comfort,
“Tandem OLED having an organic intermediate connector”,US7,494,722 B2 (February 24, 2009).
15. L.S. Liao, T.K. Hatwar, K.P. Klubek, and C.W. Tang,
“White OLED having multiple white electroluminescence units”, US7,273,663 B2 (September 25, 2007).
14. L.S. Liao and K.P. Klubek, “Using a crystallization-inhibitor in organic electroluminescent devices”,
US7,211,948 B2 (May 1, 2007).
13. L.S. Liao and K.P. Klubek, “Organic electroluminescent devices having a stability-enhancing layer”,
US7,138,763 B2 (November 21, 2006).
12. L.S. Liao and C.W. Tang,“Tandem OLED having stable intermediate connectors”,
US7,126,267 B2 (October 24, 2006).
11. L. S. Liao, T. K. Hatwar, K. P. Klubek, J. R. Vargas, and D. L. Comfort, “Tandem OLED having low drive voltage”, US7,075,231 B1 (July 11, 2006).
10. L.S. Liao, K.P. Klubek, and C.W. Tang, “A full-color organic display having improved blue emission”,
US7,030,554 B2 (April 18, 2006).
9. L.S. Liao, K.P. Klubek, D.L. Comfort, and C.W. Tang,
“Cascaded organic electroluminescentdevice having connecting units with n-type and p-typeorganic layers”, US6,936,961 B2 (August 30, 2005).
8. L.S. Liao and K.P. Klubek, “Blue organic electroluminescent devices having a non-hole-blocking buffer layer”,US6,881,502 B2 (April 19, 2005).
7. L.S. Liao and C.W. Tang, “Providing an organic electroluminescent device having stacked electroluminescent units”,US6,872,472 B2 (March 29, 2005).
6. L.S. Liao, K.P. Klubek, and D.L. Comfort, “Providing an emission-protecting layer in an OLED device”, US6,853,133 B2 (February 8, 2005).
5. L.S. Liao and J.K.Madathil, “Organic electroluminescent devices having a metal sub-layer within a hole-transporting region”, US6,818,329 B1 (November 16, 2004).
4. L.S. Liao, J.K.Madathil, P.K.Raychaudhuri, and C.W. Tang,
“Organic electroluminescent device having an adhesion-promoting layer for use with a magnesium cathode”, US6,794,061 B2 (September 21, 2004).
3. L.S. Liao, J.K.Madathil, K.P. Klubek, D.L. Comfort, and C.W. Tang,
“OLED device with a performance-enhancing layer”, US6,781,149 B1 (August 24, 2004).
2. L. S. Liao, K. P. Klubek, D. L. Comfort, and C. W. Tang, “Cascaded organic electroluminescent devices with improved voltage stability”, US6,717,358 B1 (April 6, 2004).
1. L.S. Liao, J.K.Madathil, K.P. Klubek, and C.W. Tang,“Organic light-emitting diode having an interface layer between the hole-transporting layer and the light-emitting layer”, US6,603,150 B2 (August 5, 2003).
联系电话:0512-65880945
E-mail: lsliao@suda.edu.cn
责任编辑:杨娟