English

应用科学学报 >

2016 , Vol. 34 >Issue 2: 163 - 170

DOI: https://doi.org/10.3969/j.issn.0255-8297.2016.02.006

电子技术

弯曲应力对二维石墨烯导电性能的影响

展开
  • 南京邮电大学电子科学与工程学院, 南京 210003

收稿日期: 2015-08-13

  修回日期: 2015-11-10

  网络出版日期: 2016-03-30

基金资助

国家自然科学基金(No.11304159);教育部博士点基金(No.20133223120006);江苏省自然科学基金(No.BK20151508)资助

收起

Effect of Bending Stress on the Conductive Properties of Two-Dimensional Graphene

Expand
  • College of Electronic Science and Engineering, Nanjing University of Posts and Telecommunications, Nanjing 210003, China

Received date: 2015-08-13

  Revised date: 2015-11-10

  Online published: 2016-03-30

Fold

摘要

采用化学气相沉积法生长高质量二维石墨烯,制备出石墨烯/PDMS(聚二甲基硅氧烷)和石墨烯/PET(聚对苯二甲酸乙二醇酯)柔性透明导电薄膜,用以研究不同材料及不同厚度衬底时二维石墨烯的导电性能与弯曲曲率的关系.结果表明,柔性衬底的弹性模量及厚度对二维石墨烯的导电性能影响均不大,当衬底厚度相同时,随着弯曲曲率的增加,石墨烯阻值均增加,但电阻的相对变化率较小,表明二维石墨烯导电膜可作为柔性导体应用于可弯曲触摸屏、机器人皮肤、可穿戴设备.

关键词: 石墨烯; 化学气相沉积法; 柔性透明导电薄膜; 导电性能

本文引用格式

傅凯, 徐荣青, 谌静 . 弯曲应力对二维石墨烯导电性能的影响[J]. 应用科学学报, 2016 , 34(2) : 163 -170 . DOI: 10.3969/j.issn.0255-8297.2016.02.006

Abstract

Chemical vapor deposition (CVD) was used to grow high-quality two-dimensional graphene, and graphene/PDMS and graphene/PET flexible transparent conductive film were prepared. These were used to study the relationship between conductivity and curvature of two-dimensional graphene in the context of different materials and different thickness of the substrate. The results show that elastic modulus and thickness of the flexible substrate have little effect on conductivity of the two-dimensional graphene. When thickness of the substrate is the same, graphene resistance increases with the increase of the bending curvature. However, the rate of relative change of graphene resistance is small, indicating that two dimensional graphene conductive films can be used as flexible conductors for bendable touching screen, robot skin, and wearable device.

Key words: graphene; chemical vapor deposition; flexible transparent conductive film; conductivity

参考文献

[1] Nagatomo T, Maruta Y, Omoto O. Electrical and optical properties of vacuum-evaporated indium-tin oxide films with high electron mobility[J]. Thin Solid Films, 1990, 192(1):17-25.

[2] Weijtens C H L, van Loon P A C. Influence of annealing on the optical properties of indium tin oxide[J]. Thin Solid Films, 1991, 196(1):1-10.

[3] Lee C, Ahn J, Lee K B, Kim, D, Kim, J. Graphene-based flexible NO2 chemical sensors[J]. Thin Solid Films, 2012, 520(16):5459-5462.

[4] Gleskova H, Cheng I C, Wagner S, Sturm J C, Suo Z. Mechanics of thin-film transistors and solar cells on flexible substrates[J]. Solar Energy, 2006, 80(6):687-693.

[5] Ju S, Facchetti A, Xuan Y, Liu J, Ishikawa F, Y E P, Janes D B. Fabrication of fully transparent nanowire transistors for transparent and flexible electronics[J]. Nature Nanotechnology, 2007, 2(6):378-384.

[6] Sekitani T, Nakajima H, Maeda H, Fukushima T, Aida T, Hata K, Someya T. Stretchable active-matrix organic light-emitting diode display using printable elastic conductors[J]. Nature Materials, 2009, 8(6):494-499.

[7] Khrapach I,Withers F, Bointon T H, Polyushkin D K, BarnesWL, Russo S, Craciun M F. Novel highly conductive and transparent graphene-based conductors[J]. Advanced Materials, 2012, 24(21):2844-2849.

[8] Rogala M, Wlasny I, Dabrowski P, Kowalczyk P J, Busiakiewicz A, Kozlowski W, Krajewska A. Graphene oxide overprints for flexible and transparent electronics[J]. Applied Physics Letters, 2015, 106(4):041901.

[9] Novoselov K S, Geim A K, Morozov S V, Jiang D, Zhang Y, Dubonos S A, Firsov A A. Electric field effect in atomically thin carbon films[J]. Science, 2004, 306(5696):666-669.

[10] Chae S J, Günes F, Kim K K, Kim E S, Han G H, Kim S M, Yang C W. Synthesis of largearea graphene layers on Nickel film by chemical vapor deposition:wrinkle formation[C]//SPIE NanoScience+ Engineering. International Society for Optics and Photonics, 2009:73990W-73990W-11.

[11] Neto A H C, Guinea F, Peres N M R, Novoselov K S, Geim A K. The electronic properties of graphene[J]. Reviews of Modern Physics, 2009, 81(1):109.

[12] Lee Y H, Lee J H. Scalable growth of free-standing graphene wafers with copper (Cu) catalyst on SiO2/Si substrate:thermal conductivity of the wafers[J]. Applied Physics Letters, 2010, 96(8):083101.

[13] Xu K, Wang K, Zhao W, Bao W, Liu E, Ren Y, Zhou W. The positive piezoconductive effect in graphene[J]. Nature Communications, 2015, 6.

[14] 韦勇,童国平. 拉伸作用对单层石墨片电子能隙的影响[J]. 物理学报,2009(3):1931-1935. Wei Y, Tong G P. Effect of the tensile force on the electronic energy gap of graphene sheet[J]. Acta Physica Sinica, 2009(3):1931-1935. (in Chinese)

[15] Gui G, Li J, Zhong J X. Band structure engineering of graphene by strain:first-principles calculations[J]. Physical Review B, 2008, 78(7):075435.

[16] Chen Y Z, Medina H, Tsai H W, Wang Y C, Yen Y T, Manikandan A, Chueh Y L. Low temperature growth of graphene on glass by carbon-enclosed chemical vapor deposition process and its application as transparent electrode[J]. Chemistry of Materials, 2015, 27(5):1646-1655.

[17] Ferrari A C, Meyer J C, Scardaci V, Casiraghi C, Lazzeri M, Mauri F, Geim A K. Raman spectrum of graphene and graphene layers[J]. Physical Review Letters, 2006, 97(18):187401.

[18] Fu X W, Liao Z M, Zhou J X, Zhou Y B,Wu H C, Zhang R, Yu D. Strain dependent resistance in chemical vapor deposition grown graphene[J]. Applied Physics Letters, 2011, 99(21):213107.

[19] Kim K S, Zhao Y, Jang H, Lee S Y, Kim J M, Kim K S, Hong B H. Large-scale pattern growth of graphene films for stretchable transparent electrodes[J]. Nature, 2009, 457(7230):706-710.

[20] Bae S H, Lee Y, Sharma B K, Lee H J, Kim J H, Ahn J H. Graphene-based transparent strain sensor[J]. Carbon, 2013, 51:236-242.

[21] Zhao J, He C, Yang R, Shi Z, Cheng M, Yang W, Zhang G. Ultra-sensitive strain sensors based on piezoresistive nanographene films[J]. Applied Physics Letters, 2012, 101(6):063112.
Options
文章导航

/