[1] Pourtajabadi, R., Nayeri, M. (2019). 'A Novel Design of a Multi-layer 2:4 Decoder using Quantum- Dot Cellular Automata', Journal of Optoelectronical Nanostructures, 4(1), pp. 39-50
[2] Nayeri, M., keshavarzian, P., Nayeri, M. (2018). 'A Novel Design of Penternary Inverter Gate Based on Carbon Nano Tube', Journal of Optoelectronical Nanostructures, 3(1), pp. 15-26.
[3 Pourtajabadi, R., Nayeri, M. (2019). 'A Novel Design of a Multi-layer 2:4 Decoder using Quantum- Dot Cellular Automata', Journal of Optoelectronical Nanostructures, 4(1), pp. 39-50.
[4] Hojatifar, M., Sahebsara, P. (2016). 'Tight- binding study of electronic band structure of anisotropic honeycomb lattice', Journal of Optoelectronical Nanostructures, 1(3), pp. 17-26.
[5] Mousavi, S. (2017). 'First–Principle Calculation of the Electronic and Optical Properties of Nanolayered ZnO Polymorphs by PBE and mBJ Density Functionals', Journal of Optoelectronical Nanostructures, 2(4), pp. 1-18.
[6] Geim, A.K. and Novoselov, K.S., 2010. The rise of graphene. In Nanoscience and Technology. A Collection of Reviews from Nature Journals, pp. 11-19.
[7] Xie, C., Wang, Y., Zhang, Z.X., Wang, D. and Luo, L.B., 2018. Graphene/semiconductor hybrid heterostructures for optoelectronic device applications. Nano Today, 19, pp.41-83.
[8] Legesse, M., Rashkeev, S.N., Al-Dirini, F. and Alharbi, F.H., 2020. Tunable high work function contacts: Doped graphene. Applied Surface Science, 509, p.144893.
[9] Jayanetti, J.K.D.S. and Heald, S.M., 2006. Preparation of SnGe Alloy Coated ge Nanoparticles and SnSi Alloy Coated si Nanoparticles by Ball-Milling. In
Electronic and Optical Properties of SnGe and SnC Nanoribbons: A First-Principles Study * 85
Solid State Ionics. Advanced Materials for Emerging Technologies (pp. 870-877).
[10] Lin, S.S., 2012. Light-emitting two-dimensional ultrathin silicon carbide. The Journal of Physical Chemistry C, 116(6), pp.3951-3955.
[11] Enayati, M.H. and Mohamed, F.A., 2014. Application of mechanical alloying/milling for synthesis of nanocrystalline and amorphous materials. International Materials Reviews, 59(7), pp.394-416.
[12] Damizadeh, S., Nayeri, M., Fotooh, F.K. and Fotoohi, S., 2019. First principles study of electronic structure and optical properties of armchair SnSi nanoribbons. Materials Research Express, 6(9), p.095001.
[13] Xu, Z., Li, Y. and Liu, Z., 2016. Controlling electronic and optical properties of layered SiC and GeC sheets by strain engineering. Materials & Design, 108, pp.333-342.
[14] Majidi, S., Elahi, S.M., Esmailian, A. and Kanjouri, F., 2017. First principle study of electronic and optical properties of planar GeC, SnC and SiC nanosheets. Protection of Metals and Physical Chemistry of Surfaces, 53(5), pp.773-779.
[15] Fadaie, M., Shahtahmassebi, N., Roknabad, M.R. and Gulseren, O., 2017. Investigation of new two-dimensional materials derived from stanene. Computational Materials Science, 137, pp.208-214.
[16] Ding, Y. and Wang, Y., 2017. Lattice thermal conductivities and thermoelectric performances of binary tin-based sheets: A computational study. Applied Surface Science, 396, pp.1164-1169.
[17] Drissi, L.B., Ramadan, F.Z. and Kanga, N.B.J., 2018. Optoelectronic properties in 2D GeC and SiC hybrids: DFT and many body effect calculations. Materials Research Express, 5(1), p.015061.
[18] Luo, M., Yu, B. and Xu, Y.E., 2019. Tuning Electronic Properties of the SiC-GeC Bilayer by External Electric Field: A First-Principles Study. Micromachines, 10(5), p.309.
[19] ھahin, H., Cahangirov, S., Topsakal, M., Bekaroglu, E., Akturk, E., Senger, R.T. and Ciraci, S., 2009. Monolayer honeycomb structures of group-IV elements and III-V binary compounds: First-principles calculations. Physical Review B, 80(15), p.155453.
[20] Lü, T.Y., Liao, X.X., Wang, H.Q. and Zheng, J.C., 2012. Tuning the indirect–direct band gap transition of SiC, GeC and SnC monolayer in a graphene-like honeycomb structure by strain engineering: a quasiparticle GW study. Journal of Materials Chemistry, 22(19), pp.10062-10068.
86 * Journal of Optoelectronical Nanostructures Autumn 2020 / Vol. 5, No. 4
[21] Majidi, S., Achour, A., Rai, D.P., Nayebi, P., Solaymani, S., Nezafat, N.B. and Elahi, S.M., 2017. Effect of point defects on the electronic density states of SnC nanosheets: First-principles calculations. Results in physics, 7, pp.3209-3215.
[22] Jin, H., Dai, Y. and Huang, B.B., 2016. Design of advanced photocatalysis system by adatom decoration in 2D nanosheets of group-IV and III–V binary compounds. Scientific reports, 6, p.23104.
[23] Peng, X., Copple, A. and Wei, Q., 2014. Edge effects on the electronic properties of phosphorene nanoribbons. Journal of Applied Physics, 116(14), p.144301.
[24] Kresse, G., and Furthmuller, J., Vienna ab-initio simulation package (VASP): The guide. VASP Group, Institut fur Materialphysik, Universitat Wien, Sensengasse, 2002, 8.
[25] Engel, E., Hِck, A. and Varga, S., 2001. Relativistic extension of the Troullier-Martins scheme: Accurate pseudopotentials for transition-metal elements. Physical Review B, 63(12), p.125121.
[26] Perdew, J.P., Burke, K. and Ernzerhof, M., 1996. Generalized gradient approximation made simple. Physical review letters, 77(18), p.3865.
[27] Notash, S. and Fotoohi, S., 2019. Spin polarized electronic and optical properties of vacancy defects in armchair phosphorene nanoribbons. Materials Research Express, 6(11), p.116312.