Ligand-Induced Motion and Self-Assembly Pathways between Nanocubes

Junyu Zhang; Xue Zhang; Dapeng Yang; Peng Zhao

doi:10.1021/acs.jpclett.1c00254

Ligand-Induced Motion and Self-Assembly Pathways between Nanocubes

Junyu Zhang
, Xue Zhang
, Dapeng Yang
, Peng Zhao

Huaqiao University
Shenzhen Institute of Advanced Technology
Quanzhou Normal University

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Nanoparticle motion and self-assembly have been regarded as a promising pathway for forming ordered nanostructures. However, the detailed dynamics processes induced by ligand involvement remained poorly understood. Here, we used in situ liquid-cell electron microscopy technology to image the formation of face-to-face Pt cube ordered structures: pairs, linear chains, and squares. The van der Waals interaction between the two neighboring cubes was quantified in real time. Interestingly, the two different formation processes of the square phase were achieved via a rotational and translational method. It is found that the space between two neighboring cubes was the same as the ex-TEM results. The density functional theory calculation demonstrated that it was attributed to the DMF ligand interactions of the cubes that promoted their face-to-face attachment.

Original language	English
Pages (from-to)	2429-2436
Number of pages	8
Journal	Journal of Physical Chemistry Letters
Volume	12
Issue number	9
DOIs	https://doi.org/10.1021/acs.jpclett.1c00254
State	Published - 11 Mar 2021
Externally published	Yes

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title = "Ligand-Induced Motion and Self-Assembly Pathways between Nanocubes",

abstract = "Nanoparticle motion and self-assembly have been regarded as a promising pathway for forming ordered nanostructures. However, the detailed dynamics processes induced by ligand involvement remained poorly understood. Here, we used in situ liquid-cell electron microscopy technology to image the formation of face-to-face Pt cube ordered structures: pairs, linear chains, and squares. The van der Waals interaction between the two neighboring cubes was quantified in real time. Interestingly, the two different formation processes of the square phase were achieved via a rotational and translational method. It is found that the space between two neighboring cubes was the same as the ex-TEM results. The density functional theory calculation demonstrated that it was attributed to the DMF ligand interactions of the cubes that promoted their face-to-face attachment.",

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AU - Zhang, Junyu

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AU - Yang, Dapeng

AU - Zhao, Peng

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PY - 2021/3/11

Y1 - 2021/3/11

N2 - Nanoparticle motion and self-assembly have been regarded as a promising pathway for forming ordered nanostructures. However, the detailed dynamics processes induced by ligand involvement remained poorly understood. Here, we used in situ liquid-cell electron microscopy technology to image the formation of face-to-face Pt cube ordered structures: pairs, linear chains, and squares. The van der Waals interaction between the two neighboring cubes was quantified in real time. Interestingly, the two different formation processes of the square phase were achieved via a rotational and translational method. It is found that the space between two neighboring cubes was the same as the ex-TEM results. The density functional theory calculation demonstrated that it was attributed to the DMF ligand interactions of the cubes that promoted their face-to-face attachment.

AB - Nanoparticle motion and self-assembly have been regarded as a promising pathway for forming ordered nanostructures. However, the detailed dynamics processes induced by ligand involvement remained poorly understood. Here, we used in situ liquid-cell electron microscopy technology to image the formation of face-to-face Pt cube ordered structures: pairs, linear chains, and squares. The van der Waals interaction between the two neighboring cubes was quantified in real time. Interestingly, the two different formation processes of the square phase were achieved via a rotational and translational method. It is found that the space between two neighboring cubes was the same as the ex-TEM results. The density functional theory calculation demonstrated that it was attributed to the DMF ligand interactions of the cubes that promoted their face-to-face attachment.

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Ligand-Induced Motion and Self-Assembly Pathways between Nanocubes

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