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Based on the improvement of transmission electron microscope (TEM), nano fabrication, and film deposition, and with the development of the in-situ liquid TEM and nano characterization platform, various relevant nano researches have been carried in different fields. In this article, the principle, basic design requirements, development and typical preparation technologies of the liquid cell are briefly introduced. Subsequently, the state-of-the-art applications of liquid cell transmission electron microscope in the nucleation and growth of nanoparticles are reviewed. Finally, the opportunities and challenges faced by the frontier development of this technology are also discussed. This article provides constructive discussion about and support for advanced nano characterization technology and precise manipulation of atomic structures.
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Keywords:
- in situ liquid transmission electron microscope /
- nano characterization /
- in situ liquid cell
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图 1 三类液体环境TEM实现方式示意图 (a)基于差分泵真空系统TEM结构示意图[3]; (b), (c) 基于离子液体构建的液体环境TEM实验装置示意图[4]; (d) 基于液体腔构建的液体环境TEM实验装置示意图; (e), (f)基于微纳加工制备的氮化硅窗口液体腔结构示意图[6,7]; (g), (h)基于石墨烯窗口的液体腔结构示意图[8,9]
Figure 1. Schematic diagrams of three typical methods to observe liquid sample by TEM: (a) Environment TEM based on differential pump system[3]; (b), (c) observation of the ionic liquid sample by TEM[4]; (d) schematic diagram of closed liquid cell for TEM observation; (e), (f) schematic diagrams of the liquid cell with the silicon nitride window[6,7]; (g), (h) schematic diagrams of the liquid cell with the graphene window[8,9].
图 4 典型的TEM 原位液体腔制作工艺步骤示意图 (a) 液体腔的基本结构图, 为方便结构解析, (b), (c) 沿黑色虚线剖面结构; (b) 典型的制作工艺步骤, 通过不同工艺分别制作上下两部分结构, 最后组装成(c)结构; (c) 液体腔的基本结构图剖面图
Figure 4. Typical TEM liquid cell manufacturing process: (a) The structure diagram of the liquid cell, where description (b) and (c) are cross-sectional diagram drawn along the black dash; (b) typical manufacturing process steps, the upper and lower parts are made by different processes structure, finally assembled into (c) the structure of the liquid cell with the cross-sectional view.
图 6 典型的石墨烯液体腔制作工艺步骤示意图 (a) 两个石墨烯沉积的TEM网格相互叠加; (b) 滴加溶液并吸去多余的溶液; (c) 少量残留的液体压入微米或纳米级的囊中; (d) 移除上层TEM网格
Figure 6. Typical manufacturing process of the graphene liquid cell: (a) Two graphene deposited TEM grids are superimposed; (b) extra solution is removed by suction after dropping; (c) solution is entrapped between two graphene membranes after drying; (d) top TEM grid is removed.
图 8 金纳米颗粒的成核过程的TEM时序图像[82] (a)−(d)金纳米颗粒在溶液中的形核过程; (e)−(n) 选自(a)中黑框区域的成核情况, 圆圈标定的粒子在成核过程中溶解
Figure 8. TEM time series images of the nucleation process of gold nanoparticles[82]: (a)−(d) Nucleation process of gold nanoparticles in solution; (e)−(n) nucleation situation of the black frame area in (a) is selected, where particles demarcated by the circle are dissolved during the nucleation process.
图 9 金和银在溶液中成核的三步途径[85] (a)金纳米粒子成核的三个阶段演化图像; (b)成核步骤示意图; (c)银纳米粒子成核的三个阶段演化图像
Figure 9. The three-step pathway of gold and silver nucleation in solution[85]: (a) Three-stage evolution image of gold nanoparticle nucleation; (b) schematic diagram of nucleation step; (c) three-stage evolution image of silver nanoparticle nucleation.
图 10 原位液体电镜下纳米晶的生长过程 (a) Pt 纳米粒子生长的TEM时序图像, 左侧为纳米粒子通过单体生长的过程, 右侧为纳米粒子聚合生长过程[7]; (b) Pt纳米粒子特定晶相的聚合生长过程的TEM时序图像[8]
Figure 10. Growth process of nanocrystals observed by in-situ liquid electron microscope: (a) TEM time series images of Pt nanoparticle growth, the left side is the process of nanoparticle growth through monomer, and the right side is the process of nanoparticle aggregation growth[7]; (b) TEM time series images of the polymerization growth process of the specific crystal phase of Pt nanoparticles[8]
图 12 Pt二十面体上Au的生长[93] (a) TEM时序图像显示了Au在Pt二十面体纳米颗粒上的生长过程, 箭头代表Au的生长变化位置; (b) Pt纳米晶体上Au的成核和生长的定量分析, 方程是考虑了反应和扩散的增长率
Figure 12. Au growth on a Pt icosahedron[93]: (a) TEM sequence image shows the growth process of Au on Pt icosahedral nanoparticles, and the arrow represents the growth and change position of Au; (b) quantitative analysis of Au nucleation and growth on Pt nanocrystals, the equation is to consider the growth rate of reaction and diffusion.
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[2] Xu T, Sun L 2016 Superlattice Microstruct. 99 24
[3] Hansen T W, Wagner J B, Dunin-Borkowski R E 2010 Mater. Sci. Technol. 26 1338
[4] Huang J Y, Zhong L, Wang C M, Sullivan J P, Xu W, Zhang L Q, Mao S X, Hudak N S, Liu X H, Subramanian A, Fan H, Qi L, Kushima A, Li J 2010 Science 330 1515Google Scholar
[5] Miyata T, Mizoguchi T 2017 Ultramicroscopy 178 81
[6] Tromp R M, Hull R, Vereecken P M, Williamson M J, Ross F M 2003 Nat. Mater. 2 532
[7] Zheng H, Smith R K, Jun Y, Kisielowski C, Dahmen U, Alivisatos A P 2009 Science 324 1306Google Scholar
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[9] Rasool H, Dunn G, Fathalizadeh A, Zettl A 2016 Phys. Status Solidi B 253 2351Google Scholar
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[12] Evans J E, Jungjohann K L, Browning N D, Arslan I 2011 Nano Lett. 11 2809
[13] Park J, Zheng H, Lee W C, Geissler P L, Rabani E, Alivisatos A P 2012 ACS Nano 6 2078
[14] Li D, Nielsen M H, Jonathan R I L, Frandsen C, Banfield J F, James J D Y 2012 Science 336 1014Google Scholar
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[18] Liu J, Wang Z, Sheng A, Liu F, Qin F, Wang Z L 2016 Environ. Sci. Technol. 50 5606Google Scholar
[19] Tan S F, Chee S W, Lin G, Bosman M, Lin M, Mirsaidov U, Nijhuis C A 2016 J. Am. Chem. Soc. 138 5190Google Scholar
[20] Dong M, Wang W, Wei W, Hu X, Qin M, Zhang Q, Sun L, Xu F 2019 J. Phys. Chem. C 123 21257Google Scholar
[21] Zheng H, Claridge S A, Minor A M, Alivisatos A P, Dahmen U 2009 Nano Lett. 9 2460Google Scholar
[22] Grogan J M, Rotkina L, Bau H H 2011 Phys. Rev. E: Stat., Nonlin., Soft Matter Phys. 83 61405Google Scholar
[23] Chee S W, Baraissov Z, Loh N D, Matsudaira P T, Mirsaidov U 2016 J. Phys. Chem. C 120 20462Google Scholar
[24] Chee S W, Anand U, Bisht G, Tan S F, Mirsaidov U 2019 Nano Lett. 19 2871Google Scholar
[25] Radisic A, Vereecken P M, Hannon J B, Searson P C, Ross F M 2006 Nano Lett. 6 238Google Scholar
[26] Radisic A, Vereecken P M, Searson P C, Ross F M 2006 Surf. Sci. 600 1817Google Scholar
[27] Tan S F, Lin G, Bosman M, Mirsaidov U, Nijhuis C A 2016 ACS Nano 10 7689Google Scholar
[28] Lutz L, Dachraoui W, Demortière A, Johnson L R, Bruce P G, Grimaud A, Tarascon J 2018 Nano Lett. 18 1280Google Scholar
[29] Nagashima S, Ikai T, Sasaki Y, Kawasaki T, Hatanaka T, Kato H, Kishita K 2019 Nano Lett. 19 7000Google Scholar
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Hu Q, Jin C H 2019 Acta Phys.-Chim. Sin. 35 101Google Scholar
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