INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
|
|
|
|
|
First-principles of Tunable Band Gaps of van der Waals Heterostructures Under Electric Field: Monolayer SiC on Hydrogenated BN Nanosheets |
XIAO Meixia1, LENG Hao1, YAO Tingzhen1, WANG Lei1, HE Cheng2
|
1 School of Materials Science and Engineering, Xi'an Shiyou University, Xi'an 710065, China 2 State Key Laboratory for Mechanical Behavior of Materials, Xi'an Jiaotong University, Xi'an 710049, China |
|
|
Abstract As a typical representative of the third generation semiconductor materials, silicon carbide (SiC) is one of the most ideally wide band gap semiconductor materials, which has a wide application prospect in semiconductor lighting device and electronic equipment. In this work, we have systematically investigated structural and electronic properties of monolayer SiC on fully-hydrogenated BN nanosheets (SiC/HBNH) and studied the effects of electric field on the band gaps of SiC/HBNH heterobilayers using first-principles calculations based on the density functional theory with van der Waals corrections. The results show that the position of Si and C atoms relative to HBNH nanosheet can determine the structural stability and the interaction strength between SiC and HBNH nanosheets. Therefore, the stacking types can effectively regulate the energy gaps of SiC/HBNH heterobilayers. Moreover, the conduction band minimum and valence band maximum of the heterobilayers are determined by SiC and HBNH nanosheets, respectively, leading to the separation of electrons and holes. Applying an electric field, a linear distribution of band gaps is a function of the strength of electric field, accompanied with a transition from direct semiconductors to indirect semiconductors even to conductors, which are primarily induced the stronger interaction between SiC and HBNH nanosheets. The results demonstrate that the stacking arrangements and electric field can effectively tune the electronic properties of SiC/HBNH heterobilayers, and reduce the recombination probability of electrons and holes, which open a way for the diverse and tunable electronic properties of semiconductor heterostructures in novel electronic nanodevices.
|
Published: 25 April 2022
Online: 2022-04-27
|
|
Fund:Young Scientists Fund of the National Natural Science Foundation of China (51801155) and Materials Science and Engineering of Provincial Advantage Disciplines in Xi'an Shiyou University (ys37020203). |
|
|
1 Zhou J, Wang Q, Sun Q, et al. Nano Letters,2009,9,3867. 2 Ao Z M, Peeters F M. The Journal of Physical Chemistry C,2010,114,14503. 3 Nair R R, Ren W, Jalil R, et al. Small,2010,6,2877. 4 Zhu Y F, Dai Q Q, Zhao M, et al. Scientific Reports,2013,3,1524. 5 Gao W, Tkatchenko A. Physical Review Letters,2015,114,096101. 6 Ma Y D, Dai Y, Guo M, et al. Nanoscale,2011,3,2301. 7 Zheng H, Li X B, Chen N K, et al. Physical Review B,2015,92,115307. 8 Gao N, Zheng W T, Jiang Q. Physical Chemistry Chemical Physics,2012,14,257. 9 Xu B, Yin J, Xia Y D, et al. Applied Physics Letters,2010,96,143111. 10 Zhou J, Wang Q, Sun Q, et al. Physical Review B,2010,81,085442. 11 Xiao M X, Yao T Z, Ao Z M, et al. Physical Chemistry Chemical Phy-sics,2015,17,8692. 12 Tang Q, Li Y F, Zhou Z, et al. ACS Applied Materials & Interfaces,2010,2,2442. 13 Şahin H, Cahangirov S, Topsakal M, et al. Physical Review B,2009,80,155453. 14 Bekaroglu E, Topsakal M, Cahangirov S, et al. Physical Review B,2010,81,075433. 15 Lin S S. The Journal of Physical Chemistry C,2012,116,3951. 16 Zhang P, Hou X, He Y, et al. Chemical Physics Letters,2015,628,60. 17 Geim A K, Grigorieva I V. Nature,2013,499,419. 18 He C, Zhang X, Liu Z, et al. Acta Physica Sinica,2015,64(20),206102(in Chinese). 何超,张旭,刘智,等.物理学报,2015,64(20),206102. 19 Katsnelson M I, Novoselov K S, Geim A K. Nature Physics,2006,2,620. 20 Chen X F, Lian J S, Jiang Q. Physical Review B,2012,86,125437. 21 Wang T H, Zhu Y F, Jiang Q. The Journal of Physical Chemistry C,2013,117,12873. 22 Liu H, Gao J, Zhao J. The Journal of Physical Chemistry C,2013,117,10353. 23 Li S, Wu Y F, Liu W, et al. Chemical Physics Letters,2014,609,161. 24 Gao N, Li J C, Jiang Q. Physical Chemistry Chemical Physics,2014,16,11673. 25 Ding Y, Wang Y. Applied Physics Letters,2013,103,043114. 26 He C, Zhang W X, Li T, et al. Physical Chemistry Chemical Physics,2015,17,23207. 27 Delley B. Journal of Chemical Physics,1990,92,508. 28 Delley B. Journal of Chemical Physics,2000,113,7756. 29 Grimme S. Journal of Computational Chemistry,2006,27,1787. 30 Perdew J P, Burke K, Ernzerhof M. Physical Review Letters,1996,77,3865. 31 Koelling D D, Hartreermon B N. Journal of Physics C: Solid State Phy-sics,1977,10,3107. 32 Monkhorst H J, Pack J D. Physical Review B,1976,13,5188. 33 Xie X, Ao Z, Su D, et al. Advanced Functional Materials,2015,25,1393. 34 Chen Q L, Dai Z H, Liu Z Q, et al. Acta Physica Sinica,2016,65(13),136101(in Chinese). 陈庆玲,戴振宏,刘兆庆,等.物理学报,2016,65(13),136101. 35 Gao N, Lu G Y, Wen Z, et al. Journal of Materials Chemistry C,2017,5,627. 36 Shen T, Ren J C, Liu X, et al. Journal of the American Chemical Society,2019,141,3110. 37 He C, Han F S, Zhang J H, et al. Journal of Materials Chemistry C,2020,8,6923. 38 Rubio-Pereda P, Takeuchi N. Journal of Physical Chemistry C,2015,119,27995. 39 Su G, Yang S, Jiang Y, et al. Progress in Surface Science,2019,94,100561. 40 Gao W, Chen Y, Li B, et al. Nature Communications,2020,11,1196. 41 Jiang Z Y, Xu X H, Wu H S, et al. Acta Physica Sinica,2002,51(7),1586(in Chinese). 姜振益,许小红,武海顺,等.物理学报,2002,51(7),1586. 42 Kukushkin S, Osipov A, Bessolov V, et al. Reviews on Advanced Mate-rials Science,2008,17,1. 43 Rivera P, Seyler K L, Yu H, et al. Science,2016,351,688. 44 Wu Z, Neaton J B, Grossman J C. Nano Letters,2009,9,2418. 45 Wu W, Ao Z, Wang T, et al. Physical Chemistry Chemical Physics,2014,16,16588. 46 Wang Z, Zhang Y, Wei X, et al. Physical Chemistry Chemical Physics,2020,22(17),9647. 47 Xiao J, Long M, Li X, et al. Journal of Physics: Condensed Matter,2014,26,405302. |
|
|
|