General

Changshui Huang,  Qingdao Institute of Bioenergy and Bioprocess Technology, Chinese Academy of Sciences
Email: huangcs@qibebt.ac.cn
Telephone: 0532-80662743 
Address: No.189 Songling Road , Laoshan District , Qingdao  
Postcode:  266101

Group Web: http://cs.qibebt.ac.cn/

Research Areas

1)Preparation of molecule materials with tailored nano- and molecular  architectures for preselected opticalelectronical properties 

2)Carbon materials, such as Graphidyne and Graphene, and their application in Energy storage and Photovoltaics


Education

HUANG Changshui received a B.S. from University of Science and  Technology of China in 2003 and a PhD from Institute of Chemistry, Chinese  Academy of Sciences (CAS) in 2008. He then did his postdoctoral research at  Institute of Chemistry, CAS. From 2010 to 2014, he worked at University of  Wisconsin-Madison as a postdoctor and associate researcher.


Experience

HUANG Changshui received a B.S. from  University of Science and Technology of China in 2003 and a PhD from Institute  of Chemistry, Chinese Academy of Sciences (CAS) in 2008. He then did his  postdoctoral research at Institute of Chemistry, CAS. From 2010 to 2014, he  worked at University of Wisconsin-Madison as a postdoctor and associate  researcher, before joining Qingdao Institute of  Bioenergy and Bioprocess Technology (QIBEBT), CAS in 2014. He is currently  a professor and the leader of Advanced Carbon for  Renewable Energy Group, and a recipient of the Hundred Talents Program of  CAS. 


Publications

Selected Publications 

1.     “Bulk graphdiyne powder applied for highly  efficient lithium storage”, ZHANG S., LIU H., HUANG C.*, CUI G., LI Y., Chemical  Communications, 2015, 51:  1834. 

2.     “Conjugated microporous polymers with excellent  electrochemical performance for lithium and sodium storage”, ZHANG S.,  HUANG W., HU P., HUANG C.*, SHANG C., ZHANG C., YANG  R., CUI G., Journal of Materials Chemistry A, 2015, 3: 1896.  

3.     “Self-catalyzed growth of large-area nanofilms of  two-dimensional carbon”, QIAN X., LIU H., HUANG C., CHEN S., ZHANG L., LI Y.,  WANG J., LI Y., Scientific Reports, 2015, 5: 7756. 

4.     “Graphdiyne for high capacity and long-life  lithium storage”, HUANG C., ZHANG S., LIU H., LI Y., CUI G., LI Y., Nano Energy,  2015, 11: 481.  

5.    “Raman enhancement of a dipolar molecule on graphene”, HUANG  C., KIM M., WONG B. M., SAFRON N. S., ARNOLD M. S., GOPALAN P., Journal  of Physical Chemistry C, 2014, 118: 2077. 

6.    “Orientation of a monolayer of dipolar molecules on graphene from  X-ray absorption spectroscopy”, JOHNSON P. S., HUANG C., KIM M., SAFRON N. S.,  ARNOLD M. S., WONG B. M., GOPALAN P., HIMPSEL F. J., Langmuir, 2014, 30:  2559. 

7.     “Reproducible one-step fabrication of compact  MAPbI3–xClxThin films derived from mixed-lead-halide  precursors”, WANG D., LIU Z., ZHOU Z., ZHU H., ZHOU Y., HUANG C., WANG Z., XU  H., JIN Y., FAN B., PANG S., CUI G., Chemistry of Materials, 2014, 26:  7145. 

8.    Anticorrosive flexible pyrolytic polyimide  graphite film as a cathode current collector in lithium bis(trifluoromethane  sulfonyl) imide electrolyte”, HAN P., ZHANG B., HUANG C., GU L., LI H., CUI G.,  Electrochemistry Communications, 2014, 44: 70. 

9.    “RuSe/reduced graphene  oxide: an efficient electrocatalyst for VO2+/VO2+ redox  couples in vanadium redox flow batteries”, HAN P., WANG X., ZHANG L., WANG T.,  YAO J., HUANG C., GU L., CUI G., RSC Advances, 2014, 4: 20379. 

10.  “One-step,  solution-processed formamidinium lead trihalide  (FAPbI3−xClx) for mesoscopic perovskite–polymer solar  cells”, LV S., PANG S., ZHOU Y., Nitin P. Padture, HU H., WANG L., ZHOU X., ZHU  H., ZHANG L., HUANG C., CUI G., Physical Chemistry Chemical Physics, 2014, 16:  19206.