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25 - Predictions of Single-Layer Honeycomb Structures from First Principles

from Part III

Published online by Cambridge University Press:  22 June 2017

Phaedon Avouris
Affiliation:
IBM T. J. Watson Research Center, New York
Tony F. Heinz
Affiliation:
Stanford University, California
Tony Low
Affiliation:
University of Minnesota
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2D Materials
Properties and Devices
, pp. 472 - 484
Publisher: Cambridge University Press
Print publication year: 2017

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References

25.7 References

Kresse, G, Furthmüller, J. Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set. Computational Materials Science. 1996 July, 6(1): 1550.Google Scholar
Heyd, J, Scuseria, GE, Ernzerhof, M. Erratum: “Hybrid functionals based on a screened Coulomb potential” [J. Chem. Phys. 118, 8207 (2003)]. The Journal of Chemical Physics. 2006 June 7, 124(21): 219906.Google Scholar
Shishkin, M, Kresse, G. Self-consistent GW calculations for semiconductors and insulators. Physical Review B. 2007 June 4, 75(23): 235102.Google Scholar
Takeda, K, Shiraishi, K. Theoretical possibility of stage corrugation in Si and Ge analogs of graphite. Physical Review B. 1994 November 15, 50(20): 14916–22.Google Scholar
Durgun, E, Tongay, S, Ciraci, S. Silicon and III–V compound nanotubes: Structural and electronic properties. Physical Review B. 2005 August 12, 72(7): 075420.Google Scholar
Cahangirov, S, Topsakal, M, Aktürk, E, Şahin, H, Ciraci, S. Two- and one-dimensional honeycomb structures of silicon and germanium. Physical Review Letters. 2009 June 12, 102(23): 236804.Google Scholar
Cahangirov, S, Topsakal, M, Ciraci, S. Armchair nanoribbons of silicon and germanium honeycomb structures. Physical Review B. 2010 May 25, 81(19): 195120.Google Scholar
Ezawa, M. A topological insulator and helical zero mode in silicene under an inhomogeneous electric field. New Journal of Physics. 2012 March 1, 14(3): 033003.Google Scholar
Vogt, P, De Padova, P, Quaresima, C, Avila, J, Frantzeskakis, E, Asensio, MC, et al. Silicene: Compelling experimental evidence for graphenelike two-dimensional silicon. Physical Review Letters. 2012 April 12, 108(15): 155501.Google Scholar
Cahangirov, S, Audiffred, M, Tang, P, Iacomino, A, Duan, W, Merino, G, et al. Electronic structure of silicene on Ag(111): Strong hybridization effects. Physical Review B. 2013 July 18, 88(3): 035432.Google Scholar
Feng, B, Ding, Z, Meng, S, Yao, Y, He, X, Cheng, P, et al. Evidence of silicene in honeycomb structures of silicon on Ag(111). Nanoletters. 2012 June 4, 12: 3507–11.CrossRefGoogle ScholarPubMed
Chen, L, Liu, C-C, Feng, B, He, X, Cheng, P, Ding, Z, et al. Evidence for Dirac fermions in a honeycomb lattice based on silicon. Physical Review Letters. 2012 August 3, 109(5): 056804.Google Scholar
Cahangirov, S, Özçelik, VO, Xian, L, Avila, J, Cho, S, Asensio, MC, et al. Atomic structure of the 3 × 3 phase of silicene on Ag(111). Physical Review B. 2014 July 28. 90(3): 035448.Google Scholar
Kaltsas, D, Tsetseris, L. Stability and electronic properties of ultrathin films of silicon and germanium. Physical Chemistry Chemical Physics. 2013, 15(24): 9710–15.Google Scholar
Özçelik, VO, Ciraci, S. Local reconstructions of silicene induced by adatoms. The Journal of Physical Chemistry C. 2013 December 2, 117: 26305–15.Google Scholar
Vogt, P, Capiod, P, Berthe, M, Resta, A, De Padova, P, Bruhn, T, et al. Synthesis and electrical conductivity of multilayer silicene. Applied Physics Letters. 2014 January 13, 104(2): 021602.Google Scholar
Cahangirov, S, Özçelik, VO, Rubio, A, Ciraci, S. Silicite: The layered allotrope of silicon. Physical Review B. 2014 August 22, 90(8): 085426.CrossRefGoogle Scholar
De Padova, P, Ottaviani, C, Quaresima, C, Olivieri, B. 24 h stability of thick multilayer silicene in air. 2D Materials. 2014, 1: 021003.Google Scholar
Tao, L, Cinquanta, E, Chiappe, D, Grazianetti, C, Fanciulli, M, Dubey, M, et al. Silicene field-effect transistors operating at room temperature. Nature Nanotechnology. 2015 March 1;10(3):227–31.Google Scholar
Dávila, ME, Xian, L, Cahangirov, S, Rubio, A, Le Lay, G. Germanene: A novel two-dimensional germanium allotrope akin to graphene and silicene. New Journal of Physics. 2014 September 1, 16(9): 095002.Google Scholar
Özçelik, VO, Kecik, D, Durgun, E, Ciraci, S. Adsorption of group IV elements on graphene, silicene, germanene, and stanene: Dumbbell formation. The Journal of Physical Chemistry C. 2014 December 19. 119: 845–53.Google Scholar
Derivaz, M, Dentel, D, Stephan, R, Hanf, M-C, Mehdaoui, A, Sonnet, P, et al. Continuous germanene layer on Al(111). Nanoletters. 2015 March 30, 15: 2510–16.Google Scholar
Zhu, F-F, Chen, W-J, Xu, Y, Gao, C-L, Guan, D-D, Liu, C-H, et al. Epitaxial growth of two-dimensional stanene. Nature Materials. 2015 October 1, 14(10): 1020–5.Google Scholar
Bekaroglu, E, Topsakal, M, Cahangirov, S, Ciraci, S. First-principles study of defects and adatoms in silicon carbide honeycomb structures. Physical Review B. 2010 February 24, 81(7): 075433.Google Scholar
Shaikhutdinov, S, Freund, HJ. Ultrathin silica films on metals: The long and winding road to understanding the atomic structure. Advanced Materials. 2013 January 4, 25(1): 4967.Google Scholar
Özçelik, VO, Cahangirov, S, Ciraci, S. Stable single-layer honeycomblike structure of silica. Physical Review Letters. 2014 June 20, 112(24): 246803.Google Scholar
Şahin, H, Cahangirov, S, Topsakal, M, Bekaroglu, E, Aktürk, E, Senger, RT, et al. Monolayer honeycomb structures of group-IV elements and III–V binary compounds: First-principles calculations. Physical Review B. 2009 October 28, 80(15): 155453.Google Scholar
Yang, B, Boscoboinik, JA, Yu, X, Shaikhutdinov, S, Freund, HJ. Patterned defect structures predicted for graphene are observed on single-layer silica films. Nanoletters. 2013 August 14, 13: 4422–7.Google Scholar
Özçelik, VO, Durgun, E, Ciraci, S. Modulation of electronic properties in laterally and commensurately repeating graphene and boron nitride composite nanostructures. The Journal of Physical Chemistry C. 2015 June 2, 119: 13248–56.Google Scholar
Tusche, C, Meyerheim, HL, Kirschner, J. Observation of depolarized ZnO(0001) monolayers: Formation of unreconstructed planar sheets. Physical Review Letters. 2007 July 13, 99(2): 026102.Google Scholar
Topsakal, M, Cahangirov, S, Bekaroglu, E, Ciraci, S. First-principles study of zinc oxide honeycomb structures. Physical Review B. 2009 December 11, 80(23): 235119.Google Scholar
Özçelik, VO, Ciraci, S. Size dependence in the stabilities and electronic properties of α-graphyne and its boron nitride analogue. The Journal of Physical Chemistry C. 2013 January 23, 117: 2175–82.Google Scholar
Li, L, Yu, Y, Ye, GJ, Ge, Q, Ou, X, Wu, H, et al. Black phosphorus field-effect transistors. Nature Nanotechnology. 2014 May 1, 9(5): 372–7.Google Scholar
Zhu, Z, Tománek, D. Semiconducting layered blue phosphorus: A computational study. Physical Review Letters. 2014 May 1, 112(17): 176802.Google Scholar
Aktürk, , Özçelik, VO, Ciraci, S. Single-layer crystalline phases of antimony: Antimonenes. Physical Review B. 2015 June 25, 91(23): 235446.Google Scholar
Özçelik, VO, Aktürk, , Durgun, E, Ciraci, S. Prediction of a two-dimensional crystalline structure of nitrogen atoms. Physical Review B. 2015 September 15, 92(12): 125420.Google Scholar
Ataca, C, Şahin, H, Ciraci, S. Stable, single-layer MX2 transition-metal oxides and dichalcogenides in a honeycomb-like structure. The Journal of Physical Chemistry C. 2012 April 16, 116: 8983–99.Google Scholar
Mak, KF, Lee, C, Hone, J, Shan, J, Heinz, TF. Atomically thin MoS2: A new direct-gap semiconductor. Physical Review Letters. 2010 September 24, 105(13): 136805.Google Scholar
Wang, Z, Zhao, K, Li, H, Liu, Z, Shi, Z, Lu, J, et al. Ultra-narrow WS2 nanoribbons encapsulated in carbon nanotubes. Journal of Materials Chemistry. 2011, 21(1): 171–80.Google Scholar
Coleman, JN, Lotya, M, O’Neill, A, Bergin, SD, King, PJ, Khan, U, et al. Two-dimensional nanosheets produced by liquid exfoliation of layered materials. Science. 2011 February, 331(6017): 568–71.Google Scholar
Radisavljevic, B, Radenovic, A, Brivio, J, Giacometti, V, Kis, A. Single-layer MoS2 transistors. Nature Nanotechnology. 2011 March 1, 6(3): 147–50.Google Scholar

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