參考文獻 |
[1] Biró, László P., and Philippe Lambin. "Grain boundaries in graphene grown by chemical vapor deposition." New Journal of Physics 15.3 (2013): 035024.
[2] Kim, Philip. "Across the border." Nature materials 9.10 (2010): 792-793.
[3] Yasaei, Poya, et al. "Chemical sensing with switchable transport channels in graphene grain boundaries." Nature communications 5.1 (2014): 4911.
[4] Liu, Jia-Ming, and I-Tan Lin. Graphene photonics. Cambridge University Press, 2018.
[5] Novoselov, Kostya S., et al. "Electric field effect in atomically thin carbon films." science 306.5696 (2004): 666-669.
[6] Novoselov, Kostya S., et al. "Two-dimensional atomic crystals." Proceedings of the National Academy of Sciences 102.30 (2005): 10451-10453.
[7] Geim, Andre K., and Konstantin S. Novoselov. "The rise of graphene." Nature materials 6.3 (2007): 183-191.
[8] Hass, J., W. A. De Heer, and E. H. Conrad. "The growth and morphology of epitaxial multilayer graphene." Journal of Physics: Condensed Matter 20.32 (2008): 323202.
[9] Mishra, Neeraj, et al. "Graphene growth on silicon carbide: A review." physica status solidi (a) 213.9 (2016): 2277-2289.
[10] Li, Dan, et al. "Processable aqueous dispersions of graphene nanosheets." Nature nanotechnology 3.2 (2008): 101-105.
[11] Li, Xuesong, et al. "Large-area synthesis of high-quality and uniform graphene films on copper foils." science 324.5932 (2009): 1312-1314.
[12] Bets, Ksenia V., Vasilii I. Artyukhov, and Boris I. Yakobson. "Kinetically determined shapes of grain boundaries in graphene." ACS nano 15.3 (2021): 4893-4900.
[13] Vicarelli, Leonardo, et al. "Controlling defects in graphene for optimizing the electrical properties of graphene nanodevices." ACS nano 9.4 (2015): 3428-3435.
[14] Read, William T., and W. J. P. R. Shockley. "Dislocation models of crystal grain boundaries." Physical review 78.3 (1950): 275.
[15] Liu, Yuanyue, and Boris I. Yakobson. "Cones, pringles, and grain boundary landscapes in graphene topology." Nano letters 10.6 (2010): 2178-2183.
[16] Huang, Pinshane Y., et al. "Grains and grain boundaries in single-layer graphene atomic patchwork quilts." Nature 469.7330 (2011): 389-392.
[17] Kim, Kwanpyo, et al. "Grain boundary mapping in polycrystalline graphene." ACS nano 5.3 (2011): 2142-2146.
[18] Gao, Li, Jeffrey R. Guest, and Nathan P. Guisinger. "Epitaxial graphene on Cu (111)." Nano letters 10.9 (2010): 3512-3516.
[19] Gargiulo, Fernando, and Oleg V. Yazyev. "Topological aspects of charge-carrier transmission across grain boundaries in graphene." Nano letters 14.1 (2014): 250-254.
[20] Vancsó, Péter, et al. "Effect of the disorder in graphene grain boundaries: A wave packet dynamics study." Applied Surface Science 291 (2014): 58-63.
[21] Van Tuan, Dinh, et al. "Scaling properties of charge transport in polycrystalline graphene." Nano letters 13.4 (2013): 1730-1735.
[22] Zhang, Hengji, et al. "Grain boundary effect on electrical transport properties of graphene." The Journal of Physical Chemistry C 118.5 (2014): 2338-2343.
[23] Koepke, Justin C., et al. "Atomic-scale evidence for potential barriers and strong carrier scattering at graphene grain boundaries: a scanning tunneling microscopy study." ACS nano 7.1 (2013): 75-86.
[24] Nemes-Incze, Péter, et al. "Electronic states of disordered grain boundaries in graphene prepared by chemical vapor deposition." Carbon 64 (2013): 178-186.
[25] Rutter, Gregory M., et al. "Scattering and interference in epitaxial graphene." Science 317.5835 (2007): 219-222.
[26] Jauregui, Luis A., et al. "Electronic properties of grains and grain boundaries in graphene grown by chemical vapor deposition." Solid State Communications 151.16 (2011): 1100-1104.
[27] Cummings, Aron W., et al. "Charge transport in polycrystalline graphene: challenges and opportunities." Advanced Materials 26.30 (2014): 5079-5094.
[28] Ma, Teng, et al. "Tailoring the thermal and electrical transport properties of graphene films by grain size engineering." Nature communications 8.1 (2017): 14486.
[29] Malard, Leandro M., et al. "Raman spectroscopy in graphene." Physics reports 473.5-6 (2009): 51-87.
[30] Ferrari, Andrea C., and Denis M. Basko. "Raman spectroscopy as a versatile tool for studying the properties of graphene." Nature nanotechnology 8.4 (2013): 235-246.
[31] Ni, Zhenhua, et al. "Raman spectroscopy and imaging of graphene." Nano Research 1 (2008): 273-291.
[32] Ferrari, Andrea C., et al. "Raman spectrum of graphene and graphene layers." Physical review letters 97.18 (2006): 187401.
[33] Lucchese, Márcia Maria, et al. "Quantifying ion-induced defects and Raman relaxation length in graphene." Carbon 48.5 (2010): 1592-1597.
[34] Cançado, L. G., et al. "General equation for the determination of the crystallite size L a of nanographite by Raman spectroscopy." Applied Physics Letters 88.16 (2006): 163106.
[35] Ago, Hiroki. "CVD growth of high-quality single-layer graphene." Frontiers of Graphene and Carbon Nanotubes: Devices and Applications (2015): 3-20.
[36] Reina, Alfonso, et al. "Large area, few-layer graphene films on arbitrary substrates by chemical vapor deposition." Nano letters 9.1 (2009): 30-35.
[37] Li, Xuesong, et al. "Large-area synthesis of high-quality and uniform graphene films on copper foils." science 324.5932 (2009): 1312-1314.
[38] Mattevi, Cecilia, Hokwon Kim, and Manish Chhowalla. "A review of chemical vapour deposition of graphene on copper." Journal of Materials Chemistry 21.10 (2011): 3324-3334.
[39] Gelb, Alan, and Mark J. Cardillo. "Classical trajectory study of the dissociation of hydrogen on copper single crystals: II. Cu (100) and Cu (110)." Surface Science 64.1 (1977): 197-208.
[40] Zhang, Y. I., Luyao Zhang, and Chongwu Zhou. "Review of chemical vapor deposition of graphene and related applications." Accounts of chemical research 46.10 (2013): 2329-2339.
[41] Zhou, Weilie, and Zhong Lin Wang, eds. Scanning microscopy for nanotechnology: techniques and applications. Springer science & business media, 2007.
[42] Levinson, Harry J. Principles of lithography. Vol. 146. SPIE press, 2005.
[43] Grant, David J., and Siva Sivoththaman. "Electron-beam lithography: From past to present." University of Waterloo, Canada (2003).
[44] Chung, Chen-Kuei. "Plasma etching." Encyclopedia of Microfluidics and Nanofluidics. New York: Springer Sci-ence+ Business Media (2014): 1-18.
[45] Awan, Tahir Iqbal, Almas Bashir, and Aqsa Tehseen. Chemistry of nanomaterials: fundamentals and applications. Elsevier, 2020.
[46] Werner, Florian. "Hall measurements on low-mobility thin films." Journal of Applied Physics 122.13 (2017): 135306.
[47] Rietveld, Gert, et al. "DC conductivity measurements in the Van Der Pauw geometry." IEEE transactions on instrumentation and measurement 52.2 (2003): 449-453.
[48] Instruments, Gamry. "Basics of electrochemical impedance spectroscopy." G. Instruments, Complex impedance in Corrosion (2007): 1-30.
[49] Fultz, Brent, and James M. Howe. Transmission electron microscopy and diffractometry of materials. Springer Science & Business Media, 2012.
[50] Kim, HoKwon, et al. "Activation energy paths for graphene nucleation and growth on Cu." ACS nano 6.4 (2012): 3614-3623.
[51] Červenka, J., and C. F. J. Flipse. "Structural and electronic properties of grain boundaries in graphite: planes of periodically distributed point defects." Physical Review B 79.19 (2009): 195429.
[52] Tsen, Adam W., et al. "Tailoring electrical transport across grain boundaries in polycrystalline graphene." Science 336.6085 (2012): 1143-1146.
[53] Tian, Jifa, et al. "Direct imaging of graphene edges: Atomic structure and electronic scattering." Nano letters 11.9 (2011): 3663-3668.
[54] Rasool, Haider I., et al. "Atomic-scale characterization of graphene grown on copper (100) single crystals." Journal of the American Chemical Society 133.32 (2011): 12536-12543.
[55] Yu, Qingkai, et al. "Control and characterization of individual grains and grain boundaries in graphene grown by chemical vapour deposition." Nature materials 10.6 (2011): 443-449.
[56] Childres, Isaac, et al. "Raman spectroscopy of graphene and related materials." New developments in photon and materials research 1 (2013): 1-20. |