单层Nb<sub>2</sub>SiTe<sub>4</sub>基化合物的带隙异常变化

王晓菲; 孟威威; 赵培丽; 贾双凤; 郑赫; 王建波

doi:10.7498/aps.72.20222058

摘要

传统硫族化合物中阳离子相同时, 随着阴离子原子序数的增加, 价带顶逐渐升高, 带隙呈减小趋势. 在A₂BX₄基(A = V, Nb, Ta; B = Si, Ge, Sn; X = S, Se, Te)化合物中, 观察到随着阴离子原子序数增加, 其带隙呈现反常增大的现象. 为了探究其带隙异常变化的原因, 基于第一性原理计算, 对A₂BX₄基化合物的电子结构展开系统地研究, 包括能带结构、带边相对位置、轨道间耦合作用以及能带宽度等影响. 研究发现, Nb₂SiX₄基化合物中Nb原子4d轨道能量明显高于阴离子p轨道, 其价带顶和导带底主要由Nb原子4d轨道相互作用组成, 其带宽主要影响带隙大小. Nb₂SiX₄基化合物的带隙大小通过Nb—Nb和Nb—X键共同作用于Nb原子4d轨道的宽度来控制. 当阴离子序数增加时, Nb—Nb键长增加, 其相互作用减弱, 由Nb原子4d轨道主导的能带变宽, 带隙减小; 另一方面, Nb—X键长增加又使Nb原子4d带宽变窄, 带隙增加, 并且Nb—X键长增长占主导, 所以带隙最终呈现异常增加的趋势.

关键词:

Abstract

Two-dimensional (2D) niobium silicon telluride (Nb₂SiTe₄) with good stability, a narrow band gap of 0.39 eV, high carrier mobility and superior photoresponsivity, is highly desired for applications in mid-infrared (MIR) detections, ambipolar transistors. Intensive investigations on its ferroelasticity, anisotropic carrier transport, anisotropic thermoelectric property, etc., have been reported recently. Motivated by the above prominent properties and promising applications, we systematically study the electronic properties of single-layer (SL) A₂BX₄ analogues (A = V, Nb, Ta; B = Si, Ge, Sn; X = S, Se, Te) and find a band-gap anomaly with respect to anion change, which differs from conventional 2D metal chalcogenide. In conventional binary chalcogenide, when cations are kept fixed, the bandgap tends to decrease as the atomic number of anions in the same group increases. However, in SL A₂BX₄, as atomic number of anions increases, its bandgaps tend to increase, with cations kept fixed. In order to find the underlying mechanism of such an abnormal bandgap, using first-principles calculations, we thoroughly investigate the electronic structures of Nb₂SiX₄ (X = S, Se, Te) surving as an example. It is found that the valance band maximum (VBM) and conduction band minimum (CBM) are mainly derived from the bonding and antibonding coupling between Nb 4d states. The bandwidth of Nb 4d states determines the relative value of the band gap in Nb₂SiX₄. We demonstrate that the band gap is largely influenced by the competition effect between Nb—Nb and Nb—X interactions in Nb₂SiX₄. As the anion atomic number increases, the Nb—Nb bond length increases, yielding an increased bandwidth of Nb 4d state and a smaller bandgap of Nb₂SiX₄. Meanwhile, as Nb—X bond length increases, the bandwidth of Nb 4d however decreases, yielding a larger bandgap. The interaction between Nb and X should be dominant and responsible for the overall bandgap increase of Nb₂SiX₄ compared with the Nb—Nb interaction.

Keywords:

作者及机构信息

1.
武汉大学物理科学与技术学院, 电子显微镜中心, 人工微结构教育部重点实验室, 高等研究院, 武汉　430072

2.
武汉大学苏州研究院, 苏州　215123

3.
武汉大学深圳研究院, 深圳　518057

4.
武汉大学科研公共服务条件平台, 武汉　430072

通信作者: 孟威威, meng@whu.edu.cn ; 郑赫, zhenghe@whu.edu.cn ; 王建波, wang@whu.edu.cn

基金项目: 国家自然科学基金(批准号: 52071237, 12074290, 51871169, 52101021, 12104345)、江苏省自然科学基金(批准号: BK20191187)、湖北省青年拔尖人才计划、深圳市科创委基础研究面上项目(批准号: JCYJ20190808150407522)和中国博士后科学基金(批准号: 2019M652685)资助的课题.

Authors and contacts

1.
Institute for Advanced Studies, MOE Key Laboratory of Artificial Micro- and Nano-structures, Center for Electron Microscopy, School of Physics and Technology, Wuhan University, Wuhan 430072, China

2.
Suzhou Institute of Wuhan University, Suzhou 215123, China

3.
Wuhan University Shenzhen Research Institute, Shenzhen 518057, China

4.
Core Facility of Wuhan University, Wuhan 430072, China

Corresponding author: Meng Wei-Wei, meng@whu.edu.cn ; Zheng He, zhenghe@whu.edu.cn ; Wang Jian-Bo, wang@whu.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 52071237, 12074290, 51871169, 52101021, 12104345), the Natural Science Foundation of Jiangsu Province, China (Grant No. BK20191187), the Young Top-notch Talent Cultivation Program of Hubei Province, China, the Science and Technology Program of Shenzhen, China (Grant No. JCYJ20190808150407522), and the China Postdoctoral Science Foundation (Grant No. 2019M652685).

文章全文 : translate this paragraph

参考文献

[1]	Guo Q, Pospischil A, Bhuiyan M, Jiang H, Tian H, Farmer D, Deng B, Li C, Han S J, Wang H, Xia Q, Ma T P, Mueller T, Xia F 2016 Nano. Lett. 16 4648 Google Scholar
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[19]	Carrier P, Wei S H 2005 J. Appl. Phys. 97 033707 Google Scholar
[20]	Wei S H, Zunger A 1997 Phys. Rev. B 55 13605 Google Scholar
[21]	Ye Z Y, Deng H X, Wu H Z, Li S S, Wei S H, Luo J W 2015 Npj Comput. Mater. 1 15001 Google Scholar
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[29]	Wang F, Xu Y, Mu L, Zhang J, Xia W, Xue J, Guo Y, Yang J, Yan H 2022 ACS Nano 16 8107 Google Scholar
[30]	Boucher F, Zhukov V, Evain M 1996 Inorg. Chem. 35 7649 Google Scholar
[31]	Hu J, Liu X, Yue C L, Liu J Y, Zhu H W, He J B, Wei J, Mao Z Q, Antipina L Y, Popov Z I, Sorokin P B, Liu T J, Adams P W, Radmanesh S M A, Spinu L, Ji H, Natelson D 2015 Nat. Phys. 11 471 Google Scholar
[32]	An L, Zhang H, Hu J, Zhu X, Gao W, Zhang J, Xi C, Ning W, Mao Z, Tian M 2018 Phys. Rev. B 97 235133 Google Scholar

施引文献

图 1 A₂BX₄基(A = V, Nb, Ta; B = Si, Ge, Sn; X = S, Se, Te)化合物带隙异常变化, 阴离子从上往下对应带隙从大到小

Fig. 1. Band gap anomaly in A₂BX₄ (A = V, Nb, Ta; B = Si, Ge, Sn; X = S, Se, Te) analogues, with anions from the top down corresponds to the band gap from large to small.

下载: 全尺寸图片幻灯片

图 2 晶体结构及其单层晶体结构俯视图　(a), (d) Nb₂SiTe₄; (b), (e) Nb₃SiTe₆; (c), (f) Nb₂CaO₄

Fig. 2. Crystal structures and top view of single-layer: (a), (d) Nb₂SiTe₄; (b), (e) Nb₃SiTe₆; (c), (f) Nb₂CaO₄.

下载: 全尺寸图片幻灯片

图 3 (a) Nb₂SiTe₄的轨道投影能带图; (b) Nb₂SiTe₄ VBM处的电荷密度图; (c) Nb₂SiTe₄ CBM处的电荷密度图

Fig. 3. (a) Orbit-resolved band structures of Nb₂SiTe₄; (b) partial charge density at VBM of Nb₂SiTe₄; (c) partial charge density at CBM of Nb₂SiTe₄.

下载: 全尺寸图片幻灯片

图 4 Nb₂SiTe₄中不同原子间哈密顿轨道布局　(a) Nb-Nb; (b) Nb-Si; (c) Nb-Te; (d) Si-Te; (e)图(b)中红色圆圈的放大部分(横坐标的正(负)表示原子轨道间为成(反)键态, 用图中红(绿)色区域表示)

Fig. 4. Crystal orbital Hamilton populations for different interatomic in Nb₂SiTe₄: (a) Nb-Nb; (b) Nb-Si; (c) Nb-Te; (d) Si-Te; (e) enlarged portion of the red circle in Fig. (b) (The positive (negative) of COHP represents bonding (antibonding) interaction between ions, as colored in red (green)).

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图 5 Nb₂SiX₄(X = S, Se, Te) 化合物的能带排列图

Fig. 5. Band alignment of Nb₂SiX₄ (X = S, Se, Te) compounds.

下载: 全尺寸图片幻灯片

图 6 HSE06计算的轨道投影能带结构　(a) Nb₂SiS₄; (b) Nb₂SiSe₄; (c) Nb₂SiTe₄(蓝色箭头表示占据态中最靠近VBM的两条Nb原子4d能带的近似带宽)

Fig. 6. Orbit resolved band structures calculated by HSE06: (a) Nb₂SiS₄; (b) Nb₂SiSe₄; (c) Nb₂SiTe₄ (Bandwidths of the two Nb 4d bands below the VBM are represented by blue arrows).

下载: 全尺寸图片幻灯片

图 7 PBE计算的轨道投影能带结构　(a) Nb₂SiTe₄-1; (b) Nb₂SiTe₄-2; (c) Nb₂SiTe₄; (d) Nb₂SiTe₄-3; (e) Nb₂SiTe₄-4

Fig. 7. PBE calculated orbit resolved band structures: (a) Nb₂SiTe₄-1; (b) Nb₂SiTe₄-2; (c) Nb₂SiTe₄; (d) Nb₂SiTe₄-3; (e) Nb₂SiTe₄-4.

下载: 全尺寸图片幻灯片

表 1 系列Nb₂SiTe₄构型的参数对比

Table 1. Comparisons of representative Nb₂SiTe₄-based compounds.

Nb—Nb键长/Å Nb—Te键长/Å Nb 4d带宽/Å 带隙E_g /eV

Nb₂SiTe₄-1 2.91 2.72 1.23 –0.01
Nb₂SiTe₄-2 2.91 2.76 1.14 0.21
Nb₂SiTe₄ 2.91 2.88 0.69 0.52
Nb₂SiTe₄-3 2.81 2.71 1.03 0.53
Nb₂SiTe₄-4 2.75 2.59 1.23 0.25

下载: 导出CSV

[1]	Guo Q, Pospischil A, Bhuiyan M, Jiang H, Tian H, Farmer D, Deng B, Li C, Han S J, Wang H, Xia Q, Ma T P, Mueller T, Xia F 2016 Nano. Lett. 16 4648 Google Scholar
[2]	Youngblood N, Chen C, Koester S J, Li M 2015 Nat. Photonics 9 247 Google Scholar
[3]	Yuan H, Liu X, Afshinmanesh F, Li W, Xu G, Sun J, Lian B, Curto A G, Ye G, Hikita Y, Shen Z, Zhang S, Chen X, Brongersma M, Hwang H Y, Cui Y 2015 Nat. Nanotechnol. 10 707 Google Scholar
[4]	Li L, Yu Y, Ye G J, Ge Q, Ou X, Wu H, Feng D, Chen X H, Zhang Y 2014 Nat. Nanotechnol. 9 372 Google Scholar
[5]	Han C, Hu Z, Gomes L C, Bao Y, Carvalho A, Tan S J R, Lei B, Xiang D, Wu J, Qi D, Wang L, Huo F, Huang W, Loh K P, Chen W 2017 Nano. Lett. 17 4122 Google Scholar
[6]	Tian H, Deng B, Chin M L, Yan X, Jiang H, Han S J, Sun V, Xia Q, Dubey M, Xia F, Wang H 2016 ACS Nano 10 10428 Google Scholar
[7]	Castellanos-Gomez A, Vicarelli L, Prada E, Island J O, Narasimha-Acharya K L, Blanter S I, Groenendijk D J, Buscema M, Steele G A, Alvarez J V, Zandbergen H W, Palacios J J, vander Zant H S J 2014 2D Mater. 1 025001 Google Scholar
[8]	Long M, Gao A, Wang P, Xia H, Ott C, Pan C, Fu Y, Liu E, Chen X, Lu W, Nilges T, Xu J, Wang X, Hu W, Miao F 2017 Sci. Adv. 3 e1700589 Google Scholar
[9]	Wood J D, Wells S A, Jariwala D, Chen K S, Cho E, Sangwan V K, Liu X, Lauhon L J, Marks T J, Hersam M C 2014 Nano. Lett. 14 6964 Google Scholar
[10]	Zhang T, Ma Y, Xu X, Lei C, Huang B, Dai Y 2020 J. Phys. Chem. Lett. 11 497 Google Scholar
[11]	Wang W, Dai S, Li X, Yang J, Srolovitz D J, Zheng Q 2015 Nat. Commun. 6 7853 Google Scholar
[12]	Zhao M, Xia W, Wang Y, Luo M, Tian Z, Guo Y, Hu W, Xue J 2019 ACS Nano 13 10705 Google Scholar
[13]	Fang W Y, Li P A, Yuan J H, Xue K H, Wang J F 2020 J. Electron. Mater. 49 959 Google Scholar
[14]	Ponce’S, Margine E R, Giustino F 2018 Phys. Rev. B 97 121201 Google Scholar
[15]	Xu B, Xiang H, Yin J, Xia Y, Liu Z 2018 Nanoscale 10 215 Google Scholar
[16]	Wu M, Zeng X 2016 Nano. Lett. 16 3236 Google Scholar
[17]	Wang H, Li X, Sun J, Liu Z, Yang J 2017 2D Mater. 4 045020 Google Scholar
[18]	罗雄, 孟威威, 陈国旭佳, 管晓溪, 贾双凤, 郑赫, 王建波 2020 物理学报 69 197102 Google Scholar Luo X, Meng W W, Chen G X J, Guan X X, Jia S F, Zheng H, Wang J B 2020 Acta Phys. Sin. 69 197102 Google Scholar
[19]	Carrier P, Wei S H 2005 J. Appl. Phys. 97 033707 Google Scholar
[20]	Wei S H, Zunger A 1997 Phys. Rev. B 55 13605 Google Scholar
[21]	Ye Z Y, Deng H X, Wu H Z, Li S S, Wei S H, Luo J W 2015 Npj Comput. Mater. 1 15001 Google Scholar
[22]	Perdew J P, Burke K, Ernzerhof M 1996 Phys. Rev. Lett. 77 3865 Google Scholar
[23]	Kresse G, Joubert D 1999 Phys. Rev. B 59 1758 Google Scholar
[24]	Monkhorst H J, Pack J D 1976 Phys. Rev. B 13 5188 Google Scholar
[25]	Heyd J, Scuseria G E, Ernzerhof M 2003 J. Chem. Phys. 118 8207 Google Scholar
[26]	Deringer V L, Tchougréeff A L, Dronskowski R 2011 J. Phys. Chem. A 115 5461 Google Scholar
[27]	Maintz S, Deringer V L, Tchougréeff A L, Dronskowski R 2016 J. Comput. Chem. 37 1030 Google Scholar
[28]	Wang V, Xu N, Liu J C, Tang G, Geng W T 2021 Comput. Phys. Commun. 267 108033 Google Scholar
[29]	Wang F, Xu Y, Mu L, Zhang J, Xia W, Xue J, Guo Y, Yang J, Yan H 2022 ACS Nano 16 8107 Google Scholar
[30]	Boucher F, Zhukov V, Evain M 1996 Inorg. Chem. 35 7649 Google Scholar
[31]	Hu J, Liu X, Yue C L, Liu J Y, Zhu H W, He J B, Wei J, Mao Z Q, Antipina L Y, Popov Z I, Sorokin P B, Liu T J, Adams P W, Radmanesh S M A, Spinu L, Ji H, Natelson D 2015 Nat. Phys. 11 471 Google Scholar
[32]	An L, Zhang H, Hu J, Zhu X, Gao W, Zhang J, Xi C, Ning W, Mao Z, Tian M 2018 Phys. Rev. B 97 235133 Google Scholar

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