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低维原子/分子晶体材料的可控生长、物性调控和原理性应用

黄立 李更 张余洋 鲍丽宏 郇庆 林晓 王业亮 郭海明 申承民 杜世萱 高鸿钧

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低维原子/分子晶体材料的可控生长、物性调控和原理性应用

黄立, 李更, 张余洋, 鲍丽宏, 郇庆, 林晓, 王业亮, 郭海明, 申承民, 杜世萱, 高鸿钧

Construction, physical properties and applications of low-dimensional atomic/molecular crystals

Huang Li, Li Geng, Zhang Yu-Yang, Bao Li-Hong, Huan Qing, Lin Xiao, Wang Ye-Liang, Guo Hai-Ming, Shen Cheng-Min, Du Shi-Xuan, Gao Hong-Jun
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  • 本文介绍了高鸿钧课题组在物理所20年来的部分代表性工作.研究的主要方向为低维纳米功能材料的分子束外延可控制备、生长机制、物性调控及其在未来信息技术中的原理性应用.从材料的可控制备入手,结合第一性原理的理论计算,阐明材料生长机制和结构与物性的关系,进而实现物性调控和原理性应用.主要内容有:1)纳米尺度海马分形结构的形成及其生长机制;2)STM分辨率的提高及最高分辨Si(111)-77原子图像的获得;3)固体表面上功能分子的吸附、组装及其机制;4)稳定、重复、可逆的纳米尺度电导转变与超高密度信息存储;5)固体表面上单分子自旋态的量子调控及其原理性应用;6)原子尺度上朗德g因子的空间分辨及其空间分布不均匀性的发现;7)晶圆尺寸、高质量、单晶石墨烯的制备及原位硅插层绝缘化;8)几种新型二维原子晶体材料的可控构筑及其物性调控;9)自然图案化的新型二维原子晶体材料及其功能化.这些工作为低维量子结构的构造、物性调控及其原理性应用奠定了基础.
    In this article, we review the representative work that has been done by Hong-Jun Gao's group in the past two decades in Institute of Physics, Chinese Academy of Sciences. The work focuses on the construction, properties and applications of low-dimensional atomic/molecular crystals, covering the following 3 aspects. 1) Construction and growth mechanisms of low-dimensional quantum structures. Firstly, we demonstrate the fabrication and growth mechanism of a seahorse shaped fractal pattern in C60-TCNQ multilayer thin films by using the ionized-cluster-beam method. Secondly, by modifying the tip of the scanning tunneling microscope (STM), we clearly resolve the six rest atoms and twelve adatoms on a Si(111)-77 unit cell, showing the highest-resolution STM images of the Si(111)-77 surface. According to this work, we investigate the adsorption and bonding of Ge atoms on Si(111)-77 at low coverages. The configurations and growth behaviors of iron phthalocyanine molecules on Au(111) surface from sub-monolayer to bilayer are also reviewed. Furthermore, we demonstrate that organic molecules bond preferentially to different facets of the Ag(775) substrate under different deposition sequences, molecular lengths, terrace widths, and step heights. This can contribute to the design of non-templated selective functionalization of nanocrystals. 2) Reversible conductance transition and spin on-off in low-dimensional quantum structures and applications in ultrahigh-density information storage. Firstly, we implement reversible, erasable, and rewritable nano-recordings on molecular thin films as a result of conductance transition. Then we demonstrate that the Kondo resonance of iron phthalocyanine molecules on an Au(111) substrate depends strongly on adsorption configuration, and the Kondo resonance of manganese phthalocyanine molecules can reversibly switch ON and OFF via attachment and detachment of single hydrogen atom to the molecule. Moreover, we achieve the site-dependent g factor of a single magnetic molecule with sub-molecular resolution, which shows an inhomogeneous distribution of the g factor within a single molecule. These results open up new routes to realizing ultrahigh-density information storage and controlling local spin properties within a single molecule. 3) Construction, physical properties and applications of graphene and other two-dimensional atomic crystals. We start with the fabrication of a wafer-size, high-quality (almost defect free), single-crystalline graphene on Ru(0001). Then we demonstrate the structure of novel two-dimensional (2D) atomic crystals of mono-element, such as silicene,germanene, hafnene, and antimonene. Last but not least, we present the formation of intrinsically patterned bi-elements 2D materials, PtSe2 and CuSe, which can serve as templates for selective self-assembly of molecules and nanoclusters, as well as dual functionalization for catalysis or other applications. The series of work done in Hong-Jun Gao's group has laid a solid foundation in the research field of low-dimensional quantum structures and their applications.
      通信作者: 高鸿钧, hjgao@iphy.ac.cn
    • 基金项目: 国家重点研发计划(批准号:2016YFA0202300)、国家重点基础研究发展计划(批准号:2013CBA01600)、国家自然科学基金(批准号:61390501,51572290,61725107,61622116,11604373)、中国科学院先导培育项目(B类)(批准号:XDPB0601,XDPB08-1)和中国科学院率先行动百人计划资助的课题.
      Corresponding author: Gao Hong-Jun, hjgao@iphy.ac.cn
    • Funds: Project supported by the National Key RD Program of China (Grant No. 2016YFA0202300), the National Basic Research Program of China (Grant No. 2013CBA01600), the National Natural Science Foundation of China (Grant Nos. 61390501, 51572290, 61725107, 61622116, 11604373), the Key Research Program (B) of the Chinese Academy of Sciences (Grant Nos. XDPB0601, XDPB08-1), and the CAS Pioneer Hundred Talents Program.
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  • 收稿日期:  2018-04-28
  • 修回日期:  2018-05-08
  • 刊出日期:  2019-06-20

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