摘要
Monolayer organic field-effect transistors(OFETs) are attracting worldwide interest in device physics and novel applications due to their ultrathin active layer for two-dimensional charge transport. The monolayer films are generally prepared by thermal evaporation, the Langmuir technique or self-assembly process, etc., but their electrical performance is relatively lower than corresponding thick films. From 2011, the performance of monolayer OFETs has been boosted by using the monolayer molecular crystals(MMCs) as active channels, which opened up a new era for monolayer OFETs. In this review, recent progress of monolayer OFETs, including the preparation of monolayer films, their OFET performance and applications are summarized.Finally, perspectives of monolayer OFETs in the near future are also discussed.
Monolayer organic field-effect transistors(OFETs) are attracting worldwide interest in device physics and novel applications due to their ultrathin active layer for two-dimensional charge transport. The monolayer films are generally prepared by thermal evaporation, the Langmuir technique or self-assembly process, etc., but their electrical performance is relatively lower than corresponding thick films. From 2011, the performance of monolayer OFETs has been boosted by using the monolayer molecular crystals(MMCs) as active channels, which opened up a new era for monolayer OFETs. In this review, recent progress of monolayer OFETs, including the preparation of monolayer films, their OFET performance and applications are summarized.Finally, perspectives of monolayer OFETs in the near future are also discussed.
引文
1 Tok JBH,Bao Z.Sci China Chem,2012,55:718-725
2 Shen H,Di CA,Zhu D.Sci China Chem,2017,60:437-449
3 Oh JY,Rondeau-GagnéS,Chiu YC,Chortos A,Lissel F,Wang GJN,Schroeder BC,Kurosawa T,Lopez J,Katsumata T,Xu J,Zhu C,Gu X,Bae WG,Kim Y,Jin L,Chung JW,Tok JBH,Bao Z.Nature,2016,539:411-415
4 Huang F,Cao Y.Sci China Chem,2017,60:431-432
5 Hu W,Bai F,Gong X,Zhan X,Fu H,Bjornholm T.Organic Optoelectronics.Weinheim:Wiley-VCH Verlag GmbH&Co.KGaA,2013.1-507
6 Wang C,Dong H,Jiang L,Hu W.Chem Soc Rev,2018,47:422-500
7 Klauk H.Organic Electronics:Materials,Manufacturing and Applications.Weinheim:Wiley-VCH Verlag GmbH&Co.KGaA,2007.1-428
8 Gao X,Zhao Z.Sci China Chem,2015,58:947-968
9 Wang C,Dong H,Hu W,Liu Y,Zhu D.Chem Rev,2012,112:2208-2267
10 Liu J,Dong H,Wang Z,Ji D,Cheng C,Geng H,Zhang H,Zhen Y,Jiang L,Fu H,Bo Z,Chen W,Shuai Z,Hu W.Chem Commun,2015,51:11777-11779
11 Liu J,Zhang H,Dong H,Meng L,Jiang L,Jiang L,Wang Y,Yu J,Sun Y,Hu W,Heeger AJ.Nat Commun,2015,6:10032
12 Minemawari H,Yamada T,Matsui H,Tsutsumi J’,Haas S,Chiba R,Kumai R,Hasegawa T.Nature,2011,475:364-367
13 Lee BH,Hsu BBY,Patel SN,Labram J,Luo C,Bazan GC,Heeger AJ.Nano Lett,2016,16:314-319
14 Li Q,Wu J,Wu R,Liu Y,Chen H,Huang F,Li H.Sci China Chem,2017,60:490-496
15 Zhou K,Chen H,Dong H,Fang Q,Hu W.Sci China Chem,2017,60:510-515
16 Jiang L,Dong H,Meng Q,Li H,He M,Wei Z,He Y,Hu W.Adv Mater,2011,23:2059-2063
17 Li H,Li Y,Li H,Brédas JL.Adv Funct Mater,2017,27:1605715
18 Wang Q,Qian J,Li Y,Zhang Y,He D,Jiang S,Wang Y,Wang X,Pan L,Wang J,Wang X,Hu Z,Nan H,Ni Z,Zheng Y,Shi Y.Adv Funct Mater,2016,26:3191-3198
19 Wang Q,Jiang S,Qian J,Song L,Zhang L,Zhang Y,Zhang Y,Wang Y,Wang X,Shi Y,Zheng Y,Li Y.Sci Rep,2017,7:7830
20 Peng B,Huang S,Zhou Z,Chan PKL.Adv Funct Mater,2017,27:1700999
21 Yamamura A,Watanabe S,Uno M,Mitani M,Mitsui C,Tsurumi J,Isahaya N,Kanaoka Y,Okamoto T,Takeya J.Sci Adv,2018,4:eaao5758
22 Shi Y,Jiang L,Liu J,Tu Z,Hu Y,Wu Q,Yi Y,Gann E,McNeill CR,Li H,Hu W,Zhu D,Sirringhaus H.Nat Commun,2018,9:2933
23 He D,Zhang Y,Wu Q,Xu R,Nan H,Liu J,Yao J,Wang Z,Yuan S,Li Y,Shi Y,Wang J,Ni Z,He L,Miao F,Song F,Xu H,Watanabe K,Taniguchi T,Xu JB,Wang X.Nat Commun,2014,5:5162
24 He D,Qiao J,Zhang L,Wang J,Lan T,Qian J,Li Y,Shi Y,Chai Y,Lan W,Ono LK,Qi Y,Xu JB,Ji W,Wang X.Sci Adv,2017,3:e1701186
25 Zhang Y,Qiao J,Gao S,Hu F,He D,Wu B,Yang Z,Xu B,Li Y,Shi Y,Ji W,Wang P,Wang X,Xiao M,Xu H,Xu JB,Wang X.Phys Rev Lett,2016,116:016602
26 Hu Y,Li G,Chen Z.IEEE Electron Device Lett,2018,39:276-279
27 Paloheimo J,Stubb H,Yli-Lahti P,Dyreklev P,Ingan?s O.Thin Solid Films,1992,210-211:283-286
28 Wei Z,Xu W,Hu W,Zhu D.Langmuir,2009,25:3349-3351
29 Wei Z,Cao Y,Ma W,Wang C,Xu W,Guo X,Hu W,Zhu D.Appl Phys Lett,2009,95:033304
30 Cao Y,Wei Z,Liu S,Gan L,Guo X,Xu W,Steigerwald ML,Liu Z,Zhu D.Angew Chem Int Ed,2010,49:6319-6323
31 Fabiano S,Musumeci C,Chen Z,Scandurra A,Wang H,Loo YL,Facchetti A,Pignataro B.Adv Mater,2012,24:951-956
32 Sizov AS,Agina EV,Gholamrezaie F,Bruevich VV,Borshchev OV,Paraschuk DY,de Leeuw DM,Ponomarenko SA.Appl Phys Lett,2013,103:043310
33 Sizov AS,Anisimov DS,Agina EV,Borshchev OV,Bakirov AV,Shcherbina MA,Grigorian S,Bruevich VV,Chvalun SN,Paraschuk DY,Ponomarenko SA.Langmuir,2014,30:15327-15334
34 D’Innocenzo V,Luzio A,Abdalla H,Fabiano S,Loi MA,Natali D,Petrozza A,Kemerink M,Caironi M.J Mater Chem C,2016,4:11135-11142
35 Borshchev OV,Sizov AS,Agina EV,Bessonov AA,Ponomarenko SA.Chem Commun,2017,53:885-888
36 Agina EV,Mannanov AA,Sizov AS,Vechter O,Borshchev OV,Bakirov AV,Shcherbina MA,Chvalun SN,Konstantinov VG,Bruevich VV,Kozlov OV,Pshenichnikov MS,Paraschuk DY,Ponomarenko SA.ACS Appl Mater Interfaces,2017,9:18078-18086
37 Trul AA,Sizov AS,Chekusova VP,Borshchev OV,Agina EV,Shcherbina MA,Bakirov AV,Chvalun SN,Ponomarenko SA.JMater Chem C,2018,6:9649-9659
38 Dinelli F,Murgia M,Levy P,Cavallini M,Biscarini F,de Leeuw DM.Phys Rev Lett,2004,92:116802
39 Jung S,Yao Z.Appl Phys Lett,2005,86:083505
40 Ruiz R,Papadimitratos A,Mayer AC,Malliaras GG.Adv Mater,2005,17:1795-1798
41 Park BN,Seo S,Evans PG.J Phys D-Appl Phys,2007,40:3506-3511
42 Huang J,Sun J,Katz HE.Adv Mater,2008,20:2567-2572
43 Asadi K,Wu Y,Gholamrezaie F,Rudolf P,Blom PWM.Adv Mater,2009,21:4109-4114
44 Liu SW,Lee CC,Tai HL,Wen JM,Lee JH,Chen CT.ACS Appl Mater Interfaces,2010,2:2282-2288
45 Mannebach EM,Spalenka JW,Johnson PS,Cai Z,Himpsel FJ,Evans PG.Adv Funct Mater,2013,23:554-564
46 Wang J,Jiang C.Org Electron,2015,16:164-170
47 Mottaghi M,Lang P,Rodriguez F,Rumyantseva A,Yassar A,Horowitz G,Lenfant S,Tondelier D,Vuillaume D.Adv Funct Mater,2007,17:597-604
48 Smits ECP,Mathijssen SGJ,van Hal PA,Setayesh S,Geuns TCT,Mutsaers KAHA,Cantatore E,Wondergem HJ,Werzer O,Resel R,Kemerink M,Kirchmeyer S,Muzafarov AM,Ponomarenko SA,de Boer B,Blom PWM,de Leeuw DM.Nature,2008,455:956-959
49 Hutchins DO,Acton O,Weidner T,Cernetic N,Baio JE,Ting G,Castner DG,Ma H,Jen AKY.Org Electron,2012,13:464-468
50 Ma H,Acton O,Hutchins DO,Cernetic N,Jen AKY.Phys Chem Chem Phys,2012,14:14110-14126
51 Ringk A,Li X,Gholamrezaie F,Smits ECP,Neuhold A,Moser A,Van der Marel C,Gelinck GH,Resel R,de Leeuw DM,Strohriegl P.Adv Funct Mater,2013,23:2016-2023
52 J?ger CM,Schmaltz T,Novak M,Khassanov A,Vorobiev A,Hennemann M,Krause A,Dietrich H,Zahn D,Hirsch A,Halik M,Clark T.J Am Chem Soc,2013,135:4893-4900
53 Ringk A,Christian Roelofs WS,Smits ECP,van der Marel C,Salzmann I,Neuhold A,Gelinck GH,Resel R,de Leeuw DM,Strohriegl P.Org Electron,2013,14:1297-1304
54 Schmaltz T,Amin AY,Khassanov A,Meyer-Friedrichsen T,Steinrück HG,Magerl A,Segura JJ,Voitchovsky K,Stellacci F,Halik M.Adv Mater,2013,25:4511-4514
55 Sandberg HGO,Frey GL,Shkunov MN,Sirringhaus H,Friend RH,Nielsen MM,Kumpf C.Langmuir,2002,18:10176-10182
56 Shan L,Liu D,Li H,Xu X,Shan B,Xu JB,Miao Q.Adv Mater,2015,27:3418-3423
57 Defaux M,Gholamrezaie F,Wang J,Kreyes A,Ziener U,Anokhin DV,Ivanov DA,Moser A,Neuhold A,Salzmann I,Resel R,de Leeuw DM,Meskers SCJ,Moeller M,Mourran A.Adv Mater,2012,24:973-978
58 Chen H,Dong S,Bai M,Cheng N,Wang H,Li M,Du H,Hu S,Yang Y,Yang T,Zhang F,Gu L,Meng S,Hou S,Guo X.Adv Mater,2015,27:2113-2120
59 Meng Q,Zhang F,Zang Y,Huang D,Zou Y,Liu J,Zhao G,Wang Z,Ji D,Di C,Hu W,Zhu D.J Mater Chem C,2014,2:1264-1269
60 Arai S,Inoue S,Hamai T,Kumai R,Hasegawa T.Adv Mater,2018,30:1707256
61 Jeong H,Kim D,Xiang D,Lee T.ACS Nano,2017,11:6511-6548
62 Zhang X,Li T.Chin Chem Lett,2017,28:2058-2064
63 Paloheimo J,Kuivalainen P,Stubb H,Vuorimaa E,Yli-Lahti P.Appl Phys Lett,1990,56:1157-1159
64 Xu G,Bao Z,Groves JT.Langmuir,2000,16:1834-1841
65 Scott JC,Samuel JDJ,Hou JH,Rettner CT,Miller RD.Nano Lett,2006,6:2916-2919
66 Fabiano S,Yoshida H,Chen Z,Facchetti A,Loi MA.ACS Appl Mater Interfaces,2013,5:4417-4422
67 Lo CK,Wang CY,Oosterhout SD,Zheng Z,Yi X,Fuentes-Hernandez C,So F,Coropceanu V,Brédas JL,Toney MF,Kippelen B,Reynolds JR.ACS Appl Mater Interfaces,2018,10:11995-12004
68 Agina EV,Usov IA,Borshchev OV,Wang J,Mourran A,Shcherbina MA,Bakirov AV,Grigorian S,M?ller M,Chvalun SN,Ponomarenko SA.Langmuir,2012,28:16186-16195
69 Shao W,Dong H,Jiang L,Hu W.Chem Sci,2011,2:590-600
70 Liu D,Xu X,Su Y,He Z,Xu J,Miao Q.Angew Chem Int Ed,2013,52:6222-6227
71 Liu D,He Z,Su Y,Diao Y,Mannsfeld SCB,Bao Z,Xu J,Miao Q.Adv Mater,2014,26:7190-7196
72 Jung MC,Leyden MR,Nikiforov GO,Lee MV,Lee HK,Shin TJ,Takimiya K,Qi Y.ACS Appl Mater Interfaces,2015,7:1833-1840
73 Wang Q,Jiang S,Qiu L,Qian J,Ono LK,Leyden MR,Wang X,Shi Y,Zheng Y,Qi Y,Li Y.ACS Appl Mater Interfaces,2018,10:22513-22519
74 Heringdorf FJ,Reuter MC,Tromp RM.Nature,2001,412:517-520
75 Fritz SE,Martin SM,Frisbie CD,Ward MD,Toney MF.J Am Chem Soc,2004,126:4084-4085
76 Gao J,Xu JB,Zhu M,Ke N,Ma D.J Phys D-Appl Phys,2007,40:5666-5669
77 Mirza M,Wang J,Li D,Arabi SA,Jiang C.ACS Appl Mater Interfaces,2014,6:5679-5684
78 Mirza M,Wang J,Wang L,He J,Jiang C.Org Electron,2015,24:96-100
79 Park B.Thin Solid Films,2017,627:53-58
80 Whitesides GM,Grzybowski B.Science,2002,295:2418-2421
81 Mas-Torrent M,Rovira C.Chem Rev,2011,111:4833-4856
82 DiBenedetto SA,Facchetti A,Ratner MA,Marks TJ.Adv Mater,2009,21:1407-1433
83 Calhoun MF,Sanchez J,Olaya D,Gershenson ME,Podzorov V.Nat Mater,2007,7:84-89
84 Tulevski GS,Miao Q,Fukuto M,Abram R,Ocko B,Pindak R,Steigerwald ML,Kagan CR,Nuckolls C.J Am Chem Soc,2004,126:15048-15050
85 Guo X,Myers M,Xiao S,Lefenfeld M,Steiner R,Tulevski GS,Tang J,Baumert J,Leibfarth F,Yardley JT,Steigerwald ML,Kim P,Nuckolls C.Proc Natl Acad Sci USA,2006,103:11452-11456
86 Mathijssen SGJ,Smits ECP,van Hal PA,Wondergem HJ,Ponomarenko SA,Moser A,Resel R,Bobbert PA,Kemerink M,Janssen RAJ,de Leeuw DM.Nat Nanotech,2009,4:674-680
87 Novak M,Ebel A,Meyer-Friedrichsen T,Jedaa A,Vieweg BF,Yang G,Voitchovsky K,Stellacci F,Spiecker E,Hirsch A,Halik M.Nano Lett,2011,11:156-159
88 Rumpel A,Novak M,Walter J,Braunschweig B,Halik M,Peukert W.Langmuir,2011,27:15016-15023
89 Zhang F,Di C,Berdunov N,Hu Y,Hu Y,Gao X,Meng Q,Sirringhaus H,Zhu D.Adv Mater,2013,25:1401-1407
90 Li L,Gao P,Schuermann KC,Ostendorp S,Wang W,Du C,Lei Y,Fuchs H,De Cola L,Müllen K,Chi L.J Am Chem Soc,2010,132:8807-8809
91 Wu K,Li H,Li L,Zhang S,Chen X,Xu Z,Zhang X,Hu W,Chi L,Gao X,Meng Y.Langmuir,2016,32:6246-6254
92 Li L,Gao P,Wang W,Müllen K,Fuchs H,Chi L.Angew Chem Int Ed,2013,52:12530-12535
93 Wang Z,Niu X,Zhou X,Song R,Wang Z,Huang L,Chi L.Org Electron,2018,58:38-45
94 Shin J,Hong TR,Lee TW,Kim A,Kim YH,Cho MJ,Choi DH.Adv Mater,2014,26:6031-6035
95 Giri G,DeLongchamp DM,Reinspach J,Fischer DA,Richter LJ,Xu J,Benight S,Ayzner A,He M,Fang L,Xue G,Toney MF,Bao Z.Chem Mater,2015,27:2350-2359
96 Huang S,Peng B,Chan PKL.Adv Electron Mater,2017,3:1700268
97 Xu C,He P,Liu J,Cui A,Dong H,Zhen Y,Chen W,Hu W.Angew Chem Int Ed,2016,55:9519-9523
98 Liu X,Luo X,Nan H,Guo H,Wang P,Zhang L,Zhou M,Yang Z,Shi Y,Hu W,Ni Z,Qiu T,Yu Z,Xu JB,Wang X.Adv Mater,2016,28:5200-5205
99 Xu R,He D,Zhang Y,Wu B,Liu F,Meng L,Liu JF,Wu Q,Shi Y,Wang J,Nie JC,Wang X,He L.Phys Rev B,2014,90:224106
100 Wu B,Zhao Y,Nan H,Yang Z,Zhang Y,Zhao H,He D,Jiang Z,Liu X,Li Y,Shi Y,Ni Z,Wang J,Xu JB,Wang X.Nano Lett,2016,16:3754-3759
101 Zhang Y,Luo Z,Hu F,Nan H,Wang X,Ni Z,Xu J,Shi Y,Wang X.Nano Res,2017,10:1336-1344
102 Wan W,Sun J,Su J,Hovm?ller S,Zou X.J Appl Crystlogr,2013,46:1863-1873