单层α-MoO3半导体薄膜的范德瓦耳斯外延制备

摘要/Abstract

摘要： α-MoO₃是一种典型的层状半导体过渡金属氧化物,其独特的电子结构和晶格结构使其近些年来被广泛研究。相比于体相α-MoO₃,α-MoO₃薄膜因二维几何限制而具有优异的光学、电学和力学性质。然而,单层无缺陷的α-MoO₃薄膜的外延生长迄今尚未实现。本研究在超高真空条件下使用分子束外延技术,首次在高定向热解石墨(HOPG)上范德瓦耳斯外延制备了单层无缺陷的半导体α-MoO₃薄膜,并通过氢气还原的方法产生线型缺陷,使用扫描隧道显微镜研究了完整单层薄膜及缺陷处的形貌结构和表观能隙。结果表明:通过精确控制衬底温度可以在HOPG衬底上制备出高质量单层α-MoO₃薄膜;薄膜厚度和单胞大小均符合单层α-MoO₃特征,扫描隧道谱显示其表观能隙为1.7 eV;所生长薄膜的高质量可以通过衬底HOPG的摩尔纹进一步证实。通过引入氢气可以在薄膜表面获得与摩尔纹方向垂直的明亮线缺陷,缺陷处的局域表观能隙为0.4 eV,即在一个整体为宽表观能隙的半导体材料中间实现了局部的具有窄表观能隙的通道。

关键词: α-MoO₃, 薄膜, 高定向热解石墨, 范德瓦耳斯外延, 半导体, 表观能隙

Abstract: α-MoO₃ is a typical layered semiconductor transition metal oxide, and its unique electronic structure and lattice structure have made it widely studied in recent years. Compared with bulk α-MoO₃, α-MoO₃ film has excellent optical, electrical and mechanical properties due to its two-dimensional geometric limitations. However, the epitaxial growth of single-layer defect-free α-MoO₃ film has not been realized so far. In this paper, molecular beam epitaxy was used in ultra-high vacuum, and a single-layer defect-free semiconductor α-MoO₃ film was prepared by van der Waals epitaxial on highly oriented pyrolytic graphite (HOPG) for the first time, and linear defects were generated by hydrogen reduction. The microstructure and apparent energy gap of the defect-free single-layer film and the defect were studied by scanning tunneling microscope (STM). The results show that, high-quality single-layer α-MoO₃ films can be prepared on HOPG substrates by accurately controlling the substrate temperature. The film thickness and cell size conform to the characteristics of single-layer α-MoO₃, and the apparent energy gap of 1.7 eV is determined by the scanning tunnel spectrum. The high quality of the grown film can be further confirmed by the moire pattern on the substrate HOPG. By introducing hydrogen, bright line defects perpendicular to the moire pattern can be obtained on the surface of the film, and the local apparent energy gap of the line defects is 0.4 eV, that is, a narrowband semiconductor channel is realized inside a broadband semiconductor.

Key words: α-MoO₃, thin film, HOPG, van der Waals extaxy, semiconductor, apparent energy gap

中图分类号:

O484.1

韩钰, 牛群, 周琴, 赵爱迪. 单层α-MoO₃半导体薄膜的范德瓦耳斯外延制备[J]. 人工晶体学报, 2023, 52(5): 886-893.

HAN Yu, NIU Qun, ZHOU Qin, ZHAO Aidi. Van der Waals Epitaxial Preparation of Single-Layer α-MoO₃ Semiconductor Thin Films[J]. JOURNAL OF SYNTHETIC CRYSTALS, 2023, 52(5): 886-893.

参考文献

[1] JASINSKI R. A summary of patents on organic electrolyte batteries[J]. Journal of Electroanalytical Chemistry and Interfacial Electrochemistry, 1970, 26(2/3): 189-194.
[2] ZHOU L, YANG L C, YUAN P, et al. α-MoO₃ nanobelts: a high performance cathode material for lithium ion batteries[J]. The Journal of Physical Chemistry C, 2010, 114(49): 21868-21872.
[3] HORNEBECQ V, MASTAI Y, ANTONIETTI M, et al. Redox behavior of nanostructured molybdenum oxide-mesoporous silica hybrid materials[J]. Chemistry of Materials, 2003, 15(19): 3586-3593.
[4] SAJI V S, LEE C W. Molybdenum, molybdenum oxides, and their electrochemistry[J]. ChemSusChem, 2012, 5(7): 1146-1161.
[5] JI F X, REN X P, ZHENG X Y, et al. 2D-MoO₃ nanosheets for superior gas sensors[J]. Nanoscale, 2016, 8(16): 8696-8703.
[6] CHITHAMBARARAJ A, SANJINI N S, BOSE A C, et al. Flower-like hierarchical h-MoO₃: new findings of efficient visible light driven nano photocatalyst for methylene blue degradation[J]. Catalysis Science & Technology, 2013, 3(5): 1405-1414.
[7] HUANG L Y, XU H, ZHANG R X, et al. Synthesis and characterization of g-C₃N₄/MoO₃ photocatalyst with improved visible-light photoactivity[J]. Applied Surface Science, 2013, 283: 25-32.
[8] MA W L, ALONSO-GONZÁLEZ P, LI S J, et al. In-plane anisotropic and ultra-low-loss polaritons in a natural van der Waals crystal[J]. Nature, 2018, 562(7728): 557-562.
[9] HU G W, OU Q D, SI G Y, et al. Topological polaritons and photonic magic angles in twisted α-MoO₃ bilayers[J]. Nature, 2020, 582(7811): 209-213.
[10] HU H, CHEN N, TENG H C, et al. Gate-tunable negative refraction of mid-infrared polaritons[J]. Science, 2023, 379(6632): 558-561.
[11] KOWALCZYK D A, ROGALA M, SZAŁOWSKI K, et al. Two-dimensional crystals as a buffer layer for high work function applications: the case of monolayer MoO₃[J]. ACS Applied Materials & Interfaces, 2022, 14(39): 44506-44515.
[12] ALAM M H, CHOWDHURY S, ROY A, et al. Wafer-scalable single-layer amorphous molybdenum trioxide[J]. ACS Nano, 2022, 16(3): 3756-3767.
[13] KIM H S, COOK J B, LIN H, et al. Oxygen vacancies enhance pseudocapacitive charge storage properties of MoO_3-x[J]. Nature Materials, 2017, 16(4): 454-460.
[14] GUO H C, GOONETILLEKE D, SHARMA N, et al. Two-phase electrochemical proton transport and storage in α-MoO₃ for proton batteries[J]. Cell Reports Physical Science, 2020, 1(10): 100225.
[15] DU Y G, LI G Q, PETERSON E W, et al. Iso-oriented monolayer α-MoO₃(010) films epitaxially grown on SrTiO₃(001)[J]. Nanoscale, 2016, 8(5): 3119-3124.
[16] GUIMOND S, GÖBKE D, STURM J M, et al. Well-ordered molybdenum oxide layers on Au(111): preparation and properties[J]. The Journal of Physical Chemistry C, 2013, 117(17): 8746-8757.
[17] DIXIT D, RAMACHANDRAN B, CHITRA M, et al. Photochromic response of the PLD-grown nanostructured MoO₃ thin films[J]. Applied Surface Science, 2021, 553: 149580.
[18] SHI M L, CHEN L, ZHANG T B, et al. Top-down integration of molybdenum disulfide transistors with wafer-scale uniformity and layer controllability[J]. Small, 2017, 13(35): 10.1002/smll.201603157.
[19] DISKUS M, NILSEN O, FJELLVÅG H. Growth of thin films of molybdenum oxide by atomic layer deposition[J]. Journal of Materials Chemistry, 2011, 21(3): 705-710.
[20] DISKUS M, NILSEN O, FJELLVÅG H, et al. Combination of characterization techniques for atomic layer deposition MoO₃coatings: from the amorphous to the orthorhombic α-MoO₃ crystalline phase[J]. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 2012, 30(1): 01A107.
[21] CAUDURO A L F, DOS REIS R, CHEN G, et al. Crystalline molybdenum oxide thin-films for application as interfacial layers in optoelectronic devices[J]. ACS Applied Materials & Interfaces, 2017, 9(8): 7717-7724.
[22] ARITA M, KAJI H, FUJII T, et al. Resistance switching properties of molybdenum oxide films[J]. Thin Solid Films, 2012, 520(14): 4762-4767.
[23] KIM J H, DASH J K, KWON J, et al. Van der Waals epitaxial growth of single crystal α-MoO₃ layers on layered materials growth templates[J]. 2D Materials, 2018, 6(1): 015016.
[24] KIM J H, HYUN C, KIM H, et al. Thickness-insensitive properties of α-MoO₃ nanosheets by weak interlayer coupling[J]. Nano Letters, 2019, 19(12): 8868-8876.
[25] BIENER M M, BIENER J, SCHALEK R, et al. Growth of nanocrystalline MoO₃ on Au(111) studied by in situ scanning tunneling microscopy[J]. The Journal of Chemical Physics, 2004, 121(23): 12010-12016.
[26] QUEK S Y, BIENER M M, BIENER J, et al. Tuning electronic properties of novel metal oxide nanocrystals using interface interactions: MoO₃ monolayers on Au(111)[J]. Surface Science, 2005, 577(2/3): L71-L77.
[27] DENG X Y, QUEK S Y, BIENER M M, et al. Selective thermal reduction of single-layer MoO₃ nanostructures on Au(111)[J]. Surface Science, 2008, 602(6): 1166-1174.
[28] WU Q H, ZHAO Y Q, HONG G, et al. Electronic structure of MoO_3-x/graphene interface[J]. Carbon, 2013, 65: 46-52.
[29] KOWALCZYK D A, ROGALA M, SZAŁOWSKI K, et al. Local electronic structure of stable monolayers of α-MoO_3-x grown on graphite substrate[J]. 2D Materials, 2021, 8(2): 025005.
[30] MEYER J, KIDAMBI P R, BAYER B C, et al. Metal oxide induced charge transfer doping and band alignment of graphene electrodes for efficient organic light emitting diodes[J]. Scientific Reports, 2014, 4(1): 1-7.
[31] DAS T, TOSONI S, PACCHIONI G. Structural and electronic properties of bulk and ultrathin layers of V₂O₅ and MoO₃[J]. Computational Materials Science, 2019, 163: 230-240.
[32] GUO Y, MA L, MAO K K, et al. Eighteen functional monolayer metal oxides: wide bandgap semiconductors with superior oxidation resistance and ultrahigh carrier mobility[J]. Nanoscale Horizons, 2019, 4(3): 592-600.

单层α-MoO₃半导体薄膜的范德瓦耳斯外延制备

Van der Waals Epitaxial Preparation of Single-Layer α-MoO₃ Semiconductor Thin Films

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	彭博, 李奇, 张舒淼, 樊叔维, 王若铮, 王宏兴. 金刚石肖特基二极管的研究进展[J]. 人工晶体学报, 2023, 52(5): 732-745.
[2]	武成, 朱昭捷, 李坚富, 涂朝阳, 吕佩文, 王燕. 反应磁控溅射制备h-BN薄膜及其日盲紫外探测器[J]. 人工晶体学报, 2023, 52(5): 798-804.
[3]	王高凯, 张兴旺. 六方氮化硼外延生长研究进展[J]. 人工晶体学报, 2023, 52(5): 825-841.
[4]	屈鹏霏, 金鹏, 周广迪, 王镇, 许敦洲, 吴巨, 郑红军, 王占国. 单晶金刚石异质外延用铱复合衬底研究现状[J]. 人工晶体学报, 2023, 52(5): 857-877.
[5]	白玲, 宁静, 张进成, 王东, 王博宇, 武海迪, 赵江林, 陶然, 李忠辉. 多晶金刚石衬底范德瓦耳斯外延GaN薄膜[J]. 人工晶体学报, 2023, 52(5): 901-908.
[6]	韩徐, 金艳营, 曾立, 岳宏卫, 蒋艳玲, 唐平英, 黄国华, 谢清连. Tl-1223高温超导薄膜在蓝宝石单晶基片上的生长和性能研究[J]. 人工晶体学报, 2023, 52(4): 629-635.
[7]	赵聪, 郭华飞, 邱建华, 丁建宁, 袁宁一. 基于氯化铯背接触处理优化硒化锑薄膜太阳电池性能[J]. 人工晶体学报, 2023, 52(4): 636-644.
[8]	任怡静, 马新国, 张锋, 陆晶晶, 张力, 王晗. BaTiO₃薄膜的制备及其在电光调制器的应用[J]. 人工晶体学报, 2023, 52(4): 688-700.
[9]	黎少君, 姚悦, 陈俊明. SnS₂气敏材料研究进展[J]. 人工晶体学报, 2023, 52(4): 701-709.
[10]	戚佳斌, 谢欣瑜, 李忠贤. 柔性无机铁电薄膜的制备及其在存储器领域应用研究进展[J]. 人工晶体学报, 2023, 52(3): 380-393.
[11]	余纳, 许从艳, 李秋莲, 陈玉飞, 赵永刚, 周志能, 杨鑫, 王书荣. 少量锗的加入对铜锌锡硒薄膜及其器件性能的影响[J]. 人工晶体学报, 2023, 52(3): 460-466.
[12]	王佳文, 黄勇, 郑超凡, 王语灏, 王威, 毛梦洁. 退火时间及后退火对Cu₂(Cd_xZn_1-x)SnS₄/CdS薄膜太阳电池性能影响的研究[J]. 人工晶体学报, 2023, 52(3): 476-484.
[13]	李振兴, 柏伟, 王琰璋, 刘江高, 张瑛侠, 折伟林. 大尺寸非规则碲锌镉晶片双面抛光技术[J]. 人工晶体学报, 2023, 52(2): 244-251.
[14]	张俊峰, 孙再征, 孔腾飞, 蔡根旺, 李亚平, 胡莎, 樊志琴. 射频磁控溅射法制备MoS₂薄膜的最佳工艺参数研究[J]. 人工晶体学报, 2023, 52(2): 271-280.
[15]	谭黎, 张俊, 张敏, 赵荣力, 邓朝勇, 崔瑞瑞. 高温扩散工艺制备带隙可调的β-(Al_xGa_1-x)₂O₃薄膜[J]. 人工晶体学报, 2023, 52(2): 281-288.