摘要
富勒烯奇特物理结构使其具有许多特殊的物理化学性能,造就了其在物理、化学、生物等各领域研究和应用的非凡可能性,剖析该领域的研究热点、前沿及潜在研究具有一定理论和现实意义。基于2007~2017年SCI数据库富勒烯及其相关研究领域的原始文献数据,借助文献计量学基本原理,以及Bibexcel、CiteSpace、VOSviewer、UCinet等软件的联合应用,形成了富勒烯及其相关研究领域可视化知识图谱,进而分析富勒烯领域的研究热点、前沿及潜在研究。结果表明:研究最热热点为富勒烯的光伏电池;研究前沿包括非富勒烯聚合物、富勒烯太阳能光电转换效率、富勒烯聚合物添加剂、富勒烯材料热检测、富勒烯医药抗癌;潜在(关联)研究为用于制造石墨烯的碳纳米管。
The peculiar physical structure of fullerenes creates the extraordinary possibilities of research and application in physics,chemistry,biology and other fields,therefore,it is of theoretical and practical significance to analyze the research hotspots,fronts and potential research in this field. Basing on the original data on fullerenes and related research fields in SCI database from 2007 to 2017 and combining with the softs of Bibexcel, Cite Space, VOSviewer and UCinet,Visualization Knowledge Mapping about fullerene is obtained,and then the research hot spots,fronts and potential research of fullerenes are analyzed. The results show: fullerene-based photovoltaic cells are the hottest research hotspot; research fronts include non-fullerene polymers,fullerene solar photoelectric conversion efficiency,fullerene polymer additives,thermal detection with fullerene materials and the fullerene medicine anticancer; the potential study is the graphene production coming from carbon nanotubes.
引文
[1]Kroto H W,Heathj R,O’Briens C,et al.Nature[J],1985,318(6042):162-163.
[2]Friedman S H,De Camp D L,Subesma R P,et al.Journal of the A-merican Chemical Society[J],1993,115(15):6506.
[3]Serdar Sariciftci N.Current Opinion in Solid State&Materials Science[J],1999,4:373-378
[4]新方法合成的富勒烯硬度超钻石[N/OL].Science and Technology Daily(科技日报)2014-09-17(2)[2017-05-18].http://digitalpaper.stdaily.com/http_www.kjrb.com/kjrb/html/2014-09/17/content_277775.htm?div=-1
[5]Zhao W C,Yao H F,Zhang S Q,et al.Journal of the American Chemical Society[J],2017,139(21):7148-7151.
[6]Law J,Bauin S,Courtial J P,et al.Scientometries[J],1988,14(3/4):251-264.
[7]Law J,Whittaker J.Scientometries[J],1992,23(3):457-461.
[8]Qin H.Library Trends[J],1999,48(1):133-159.
[9]Leonard J P.Thesis for Doctorate(博士论文)[D].New York:Long Island University,2003.
[10]Yu G,Gao J,Hummelen J C,et al.Science[J],1995,270(5243):1789-1791.
[11]Bin H J,Gao L,Zhang Z G,et al.Nature Communications[J],2016(7):1-11.
[12]Liu F,Zhou Z C,Zhang C,et al.Journal of the American Chemical Society[J],2016,138(48):15523-15526.
[13]Wang Y F,Jia B Y,Qin F,et al.Polymer[J],2016(107):108-112.
[14]Song K C,Singh R,Lee J,et al.Journal of Materials Chemistry C[J],2016,4(45):10610-10615.
[15]Larson B W,Reid O G,Coffey D C.Advanced Energy Materials[J],2016,6(24):1601427.
[16]Kumano M,Ide M,Seiki N,et al.Journal of Materials Chemistry A[J],2016,4(47):18490-18498.
[17]Choi Y,Kim G,Kim H,et al.Nano Energy[J],2016(30):200-207.
[18]Kakogianni S,Andreopoulou A K,Kallitsis J K.Polymers[J],2016,8(12).
[19]Long Y,Ward A J,Ruseckas A,et al.Synthetic Metals[J],2016(216):23-30.
[20]Mikheev I V,Usoltseva L O,Ivshukov D A,et al.Journal of Physical Chemistry C[J],2016(120):28270-28287.
[21]Prylutskyy Y,Borowik A,Golunski G,et al.Materialwissenschaft und Werkstofftechnik[J],2016(47):92-97.
[22]Grynyuk I I,Prylutska S V,Franskevych D V,et al.Materialwissenschaft und Werkstofftechnik[J],2016(47):98-104.
[23]Bychko A,Sokolova V,Prylutska S,et al.Materialwissenschaft undWerkstofftechnik[J],2016(47):105-111.
[24]Wan Tingting(万婷婷),Zhu Ankang(朱安康),Guo Youmin(郭友敏),et al.Materials Review(材料导报)[J],2017,05:16-22.