|
OALib Journal期刊
ISSN: 2333-9721
费用:99美元
|
|
|
|
低聚对亚苯基亚乙烯基分子导线电子传输机理研究
DOI: 10.11777/j.issn1000-3304.2014.14138, PP. 1659-1668
Keywords: 低聚对亚苯基亚乙烯基,分子导线,电荷传输机理,连接基团
Abstract:
合成了12个OPV分子导线(分成乙酰巯基与氨基端基两个系列),采用导电原子力显微镜和扫描隧道显微镜-裂分结的方法对该类分子导线的电学性能进行了表征.通过分析单分子电阻与分子长度、温度以及电场的依赖关系,发现OPV分子导线的电子传输机理在临界长度为2.0nm处发生了由隧穿传导向跳跃传导的转变.通过对比分子末端分别为巯基和氨基的单分子电导值,考察了不同的连接基团对OPV分子导线电子传输性能的影响,发现末端基团只影响分子的接触电阻,但不改变分子导线本身的电子传输机理.利用密度泛函理论和非平衡格林函数方法对OPV分子导线的电学特性进行了理论研究,结果表明分子的前线轨道能级与金电极的相对位置决定了OPV分子导线的电子传输机理.
| [1] | 1 Aviram A, Ratner M A.Chem Phys Lett,1974,29(2):277~283
|
| [2] | 2 Song H,Reed M A,Lee T.Adv Mater,2011,23(14):1583~1608
|
| [3] | 3 Kiguchi M,Kaneko S.Phys Chem Chem Phys,2013,15(7):2253~2267
|
| [4] | 4 Sedghi G,Sawada K,Esdaile L,Hoffmann M,Anderson H,Bethell D,Haiss W,Higgins S,Nichols R.J Am Chem Soc,2008,130(27):8582~8583
|
| [5] | 5 Tour J.Acc Chem Res,2000,33(11):791~8046
|
| [6] | 6 Mccreery R L.Chem Mater,2004,16(23):4477~4496
|
| [7] | 7 Choi S H,Kim B,Frisbie C D.Science,2008,320:1482~1486
|
| [8] | 8 Lu Q,Liu K,Zhang H M,Du Z B,Wang X H,Wang F S.ACS Nano,2009,3(12):3861~3868
|
| [9] | 9 Lu Q,Yao C,Wang X H,Wang F S.J Phys Chem C,2012,116(33):17853~17861
|
| [10] | 10 Yamada R,Kumazawa H,Tanaka S,Tada H.Appl Phys Express,2009,2:0250021~0250023
|
| [11] | 11 Hines T,Diez-Perez I,Hihath J,Liu H,Wang Z S,Zhao J,Zhou G,Mulllen K,Tao N J.J Am Chem Soc,2010,132(33):11658~11664
|
| [12] | 12 Zhao X,Huang C,Gulcur M,Batsanov A S,Baghernejad M,Hong W,Bryce M R,Wandlowski T.Chem Mater,2013,25(21):4340~4347
|
| [13] | 13 Lee S K,Yamada R,Tanaka S,Chang G S,Asai Y,Tada,H.ACS Nano,2012,6(6):5078~5082
|
| [14] | 14 Fu M D,Chen P,Lu H C,Kuo C T,Tseng W H,Chen C H.J Phys Chem C,2007,111(30):11450~11455
|
| [15] | 15 Liang J,Scoles G.J Phys Chem C,2010,114(24):10836~10842
|
| [16] | 16 Liu K,Wang X,F.Wang F.ACS Nano,2008,2(11):2315~2323
|
| [17] | 17 Martín S,Haiss W F,Higgins S,Cea P,López M C,Nichols R J.J Phys Chem C,2008,112(10):3941~3948
|
| [18] | 18 Quek S Y,Venkataraman L,Choi H J,Louie S G,Hybertsen M S,Neaton J.B.Nano Lett,2007,7(11):3477~3482
|
| [19] | 19 Chen F,Li X L,Hihath J,Huang Z F,Tao N J.J Am Chem Soc,2006,128(49):15874~15881
|
| [20] | 20 Giacalone F,Segura J,Martín N,Guldi D.J Am Chem Soc,2004,126(17):5340~5341
|
| [21] | 21 Sondergaard R,Strobel S,Bundgaard E,Norrman K,Hansen A,Albert E,Csaba G,Lugli P,Tornow M,Krebs F.J.Mater Chem,2009,19(23):3899~3908
|
| [22] | 22 Lebedev N,Griva I,Trammell S,Kedziora G,Tender L,Schnur J.J Phys Chem C,2010,114(28):12341~12345
|
| [23] | 23 Danilov A,Kubatkin S,Kafanov S,Hedegard P,Stuhr-Hansen N,Moth-Poulsen K,Bjornholm T.Nano Lett,2007,8(1):1~5
|
| [24] | 24 Seferos D,Banach D,Alcantar N.Israelachvili J,Bazan,G.J Org Chem,2004,69(4):1110~1119
|
| [25] | 25 Yang J S,Hwang C Y,Hsieh C C,Chiou S Y.J Org Chem,2004,69(3):719~726
|
| [26] | 26 Jian H,Tour J.J Org Chem,2005,70(9):3396~3424
|
| [27] | 27 Wang S J,Oldham W J,Hudack R A,Bazan G.J Am Chem Soc,2000,122(24):5695~5709
|
| [28] | 28 Hilberer A,Brouwer H J,Scheer B J,Wildeman J,Hadziioannou G.Macromolecules,l995,28(13):4525~4529
|
| [29] | 29 Newton M D,Smalley J F.Phys Chem Chem Phys,2007,9(5):555~572
|
| [30] | 30 Li X,Hihath J,Chen F,Masuda T,Zang L,Tao N.J Am Chem Soc,2007,129(37):11535~11542
|
| [31] | 31 Liang J,Scoles G.J Phys Chem C,2010,114(24):10836~10842
|
| [32] | 32 Beebe J M,Kim B S,Frisbie C D,Kushmerick J G.ACS Nano,2008,2(5):827~832
|
| [33] | 33 Segal D,Nitzan A,Ratner M,Davis W B.J Phys Chem B,2000,104(13):2790~2793
|
Full-Text
|
|
Contact Us
service@oalib.com QQ:3279437679 
WhatsApp +8615387084133
|
|
