|
OALib Journal期刊
ISSN: 2333-9721
费用:99美元
|
|
|
|
二维高分子——新碳同素异形体石墨炔研究
DOI: 10.11777/j.issn1000-3304.2015.14409, PP. 147-165
Keywords: 二维高分子,碳同素异形体,石墨炔,石墨二炔
Abstract:
二维平面网络结构的石墨炔具有大的共轭体系、宽面间距、优良的化学稳定性和半导体性能.石墨炔特殊的电子结构和孔洞结构使其在信息技术、电子、能源、催化以及光电等领域具有潜在、重要的应用前景.自2010年被成功合成后,吸引了来自化学、物理、材料、电子、微电子和半导体领域的科学家,对其诱人的半导体、微纳电子、光学、储能、催化和机械性能进行了探索.本文总结了二维高分子石墨炔的研究进展,重点描述了石墨炔潜在性质和性能的理论预测,以及石墨炔的合成及其在电子、光伏、储能和催化领域的应用等.
| [1] | 1 Novoselov K S, Geim A K,Morozov S V,Jiang D,Zhang Y,Dubonos S V,Grigorieva I V,Firsov A A.Science,2004,306:666~66
|
| [2] | 2 Chung D D L.J Mater Sci,2002,37:1475~1489
|
| [3] | 3 Kr?tschmer W,Lamb L D,Fostiropoulos K,Huffman D R.Nature,1990,347:354~358
|
| [4] | 4 Wang L,Liu B B,Li H,Yang W,Ding Y,Sinogeikin S V,Meng Y,Liu Z X,Zeng X C,Mao W L.Science,2012,337:825~828
|
| [5] | 5 Sun A W,Lauher J W,Goroff N S.Science,2006,312:1030~1034
|
| [6] | 6 Liu H B,Xu J L,Li Y J,Li Y L.Acc Chem Res,2010,43:1496~1508
|
| [7] | 7 Zheng H Y,Li Y J,Liu H B, Yin X D,Li Y L.Chem Soc Rev,2011,40:4506~4524
|
| [8] | 8 Liu H B,Li Y L,Jiang L,Luo H Y,Xiao S Q,Fang H J,Li H M,Zhu D B,Yu D P,Xu J,Xiang B.J Am Chem Soc,2002,124:13370~13371
|
| [9] | 9 Hirsch A,Nat Mater,2010,9:868~871
|
| [10] | 10 Ijima S,Ichihashi T.Nature,1993,363:603~605
|
| [11] | 11 Haley M M.Pure Appl Chem,2008,80:519~532
|
| [12] | 39 Yue Q,Chang S L,Kang J,Qin S Q,Li J B.J Phys Chem C,2013,117:14804~14811
|
| [13] | 40 KimB G,Choi H J.Phys Rev B,2012,86:115435~5
|
| [14] | 41 Zheng J J,Zhao X,Zhao Y L,Gao X F.Sci Rep,2013,3:1271~7
|
| [15] | 42 Zheng Q Y,Luo G F,Liu Q H,Quhe R,Zheng J X,Tang K C,Gao Z X,Nagase S,Lu J.Nanoscale,2012,4:3990~3996
|
| [16] | 43 Leenaerts O,Partoens B,Peeters F M.Appl Phys Lett,2013,103:013105~4
|
| [17] | 44 Long M,Wang D,Li Y L,Shuai Z G.ACS Nano,2011,15:2593~2600
|
| [18] | 45 Kang J,Wu F,Li J B.J Phys Condens Matter,2012,24:165301~5
|
| [19] | 46 Yue Q,Chang S L,Tan J C,Qin S Q,Kang J,Li J.B.Phys Rev B,2012,86:235448~7
|
| [20] | 47 Rozhkov A V,Giavaras G,Bliokh Y P,Freilikher V,Nori F.Phys Rep,2011,503:77~114
|
| [21] | 48 Ouyang T,Chen Y P,Liu L M,Xie Y,Wei X L,Zhong J X.Phys Rev B,2012,85:235436~7
|
| [22] | 49 Cranford S W,Buehler M J.Nanoscale,2012,4:4587~4593
|
| [23] | 50 Zhang H Y,He X J,Zhao M W,Zhang M,Zhao L X,Feng X J,Luo Y H.J Phys Chem C,2012,116:16634~16638
|
| [24] | 51 LinS C,Buehler M J.Nanoscale,2013,5:11801~11807
|
| [25] | 52 Li C,Li J B,Wu F M,Li S S,Xia J B,Wang L W.J Phys Chem C,2011,115:23221~23225
|
| [26] | 53 Hwang H J,Kwon Y Y,Lee H Y.J Phys Chem C,2012,116:20220~20224
|
| [27] | 54 Guo Y F,Jiang K,Xu B,Xia Y D,Yin J,Liu Z G.J Phys Chem C,2012,116:13837~13841
|
| [28] | 55 Zhang H,Zhao M,He X,Wang Z,Zhang X,Liu X.J Phys Chem C,2011,115:8845~8850
|
| [29] | 56 SrinivasuK,Ghosh S K.J Phys Chem C,2012,116:5951~5956
|
| [30] | 57 Zhang H Y,Xia Y Y,Bu H X,Wang X P,Zhang M,Luo Y H,Zhao M W.J Appl Phys,2013,113:044309
|
| [31] | 58 He J J,Ma S Y,Zhou P,Zhang C X,He C Y,Sun L Z.J Phys Chem C,2012,116:26313~26321
|
| [32] | 59 Narita N,Nagai S,Suzuki S.Phys Rev B,2001,64:245408~7
|
| [33] | 60 Zhang Y Y,Pei Q X,Wang C M.Comput Mater Sci,2012,65:406~410
|
| [34] | 61 Wu P,Du P,Zhang H,Cai C X.J Phys Chem C,2012,116:20472~20479
|
| [35] | 62 Youngs W J,Tessier C A,Bradshaw J D.Chem Rev,1999,99:3153~3180
|
| [36] | 67 Bhaskar A,Guda R,Haley M M,Goodson III T.J Am Chem Soc 2006,128:13972~13973
|
| [37] | 68 Ferrara J D,Tanaka A A,Fierro C,Tessier-Youngs C A,Youngs W J.Organometallics,1989,8:2089~2098
|
| [38] | 69 Zhong J,Wang J,Zhou J G,Mao B H,Liu C H,Liu H B,Li Y L,Sham T K,Sun X H,Wang S D.J Phys Chem C,2013,117:5931~5936
|
| [39] | 70 Coluci V R,Braga S F,Legoas S B,Galvao D S,Baughman R H.Phys Rev B,2003,68:035430~3
|
| [40] | 71 Li G X,Li Y L,Qian X M,Liu H B,Lin H W,Chen N,Li Y J.J Phys Chem C,2011,115:2611~2615
|
| [41] | 72 Qian X M,Ning Z Y,Li Y L,Liu H B,Ouyang C B,Chen Q,Li Y J.Dalton Trans.,2012,41:730~733
|
| [42] | 73 Ohkita M,Kawano M,Suzuki T,Tsuji T.Chem Commun,2002,3054~3055
|
| [43] | 74 Bu H X,Zhao M W,Zhang H Y,Wang X P,Xi Y,Wang Z H.J Phys Chem A,2012,116:3934~3939
|
| [44] | 75 Liu R J,Liu H B,Li Y L,Yi Y P,Shang X K,Zhang S S,Yu X L,Zhang S J,Cao H B,Zhang G J.Nanoscale,2014,6:11336~11343
|
| [45] | 76 Wang S,Yi L X,Halpert J E,Lai X Y,Liu Y Y,Cao H B,Yu R B,Wang D,Li Y L.Small,2012,8:265~271
|
| [46] | 77 Yang N L,Liu Y Y,Wen H,Tang Z Y,Zhao H J,Li Y L,Wang D.ACS Nano,2013,7:1504~1512
|
| [47] | 78 Du H L,Deng Z B,Lü Z Y,Yin Y H,Yu L L,Wu H,Chen Z,Zou Y,Wang Y S,Liu H B,Li Y L.Synth Met,2011,161:2055~2057
|
| [48] | 12 Diederich F,Kivala M.Adv Mater,2010,22,803~812.
|
| [49] | 13 Baughman R H,Eckhardt H,Kertesz M.J Chem Phys,1987,87:6687~6699
|
| [50] | 14. aley M M,Brand S C,Pak J J.Angew Chem,Int Ed Engl,1997,36:835~838
|
| [51] | 15 Li G X,Li Y L,Liu H B,Guo Y B,Li Y J,Zhu D B.Chem Commun,2010,46:3256~3258
|
| [52] | 16 Cranford S W,Brommer D B,Buehler M J.Nanoscale,2012,4:7797~7809
|
| [53] | 17 Coluci V R,Galv?o D S,Baughman R H.J Chem Phys,2004,121:3228~3237
|
| [54] | 18 Baughman R H,Eckhardt H,Kertesz M.J Chem Phys,1987,87:6687~6699
|
| [55] | 19 Yue Q,Chang S L,Kang J,Tan J C,Qin S Q,Li J B.J Chem Phys,2012,136:244702~4
|
| [56] | 20 Carper J.Library J,1999,124:192
|
| [57] | 21 Pan L D,Zhang L Z,Song B Q,Du S X,Gao H J.Appl Phys Lett,2011,98:173102~3
|
| [58] | 22 Mirnezhad.,Ansari R,Rouhi H,Seifi M,Faghihnasiri M.Solid State Commun,2012,152:1885~1889
|
| [59] | 23 Cranford S W,Buehler M J.Carbon,2011,49:4111~4121
|
| [60] | 24 Pei Y.Physica B,2012,407:4436~4439
|
| [61] | 25 Narita N,Nagai S,Suzuki S,Nakao K.Phys Rev B:Condens Matter Mater Phys,1998,58:11009~11014
|
| [62] | 26 YangY,Xu X.Comput Mater Sci,2012,61:83~88
|
| [63] | 27 Bai H C,Zhu Y,Qiao W Y,Huang Y H.RSC Adv,2011,1:768~775
|
| [64] | 28 EnyashinA N,Ivanovskii A L.Phys.Status Solid B,2011,248:1879~1883
|
| [65] | 29. Ivanovskii A L.Prog Solid State Chem,2013,41:1~19
|
| [66] | 30 Luo G F,Qian X M,Liu H B,Qin R,Zhou J,Li L Z,Gao Z X,Wang E G,Mei W N,Lu J,Li Y L,Nagase S.Phys Rev B,2011,84:075439~5
|
| [67] | 31 Jiao Y,Du A J,Hankel M,Zhu Z H,Rudolph V,Smith S C.Chem Commun,2011,47:11843~11845
|
| [68] | 32 Psofogiannakis G M,Froudakis G E.J Phys Chem C,2012,116:19211~19214
|
| [69] | 33 Malko D,Neiss C,Viňes F,G?rling A.Phys Rev Lett,2012,108:086804~4
|
| [70] | 34 Chen J M,Xi J Y,Wang D,Shuai Z G.J Phys Chem Lett,2013,4:1443~1448
|
| [71] | 35 Cao J,Tang C P,Xiong S J.Physica B,2012,407:4387~4390
|
| [72] | 36 Cui H J,Sheng X L,Yan Q B,Zheng Q R,Su G.Phys Chem Chem Phys,2013,15:8179~8185
|
| [73] | 37 Peng Q,Ji W,De S.Phys Chem Chem Phys,2012,14:13385~13391
|
| [74] | 38 Zhang Y Y,Pei Q X,Wang C M.Appl Phys Lett,2012,101:081909~8
|
| [75] | 63 Spitler E L,Johnson C A,Haley M M.Chem Rev,2006,106:5344~5386
|
| [76] | 64 GholamiM,Tykwinski R R.Chem Rev,2006,106:4997~5027
|
| [77] | 65 Tahara K,Fujita T,Sonoda M,Shiro M,Tobe Y.J Am Chem Soc,2008,130:14339~14345
|
| [78] | 66 Tobe Y,Fujii T,Matsumoto H,Tsumuraya K,Noguchi D,Nakagawa N,Sonoda M,Naemura K,Achiba Y,Wakabayashi T.J Am Chem Soc,2000,122:1762~1775
|
Full-Text
|
|
Contact Us
service@oalib.com QQ:3279437679 
WhatsApp +8615387084133
|
|
