Emergent tetratic order in crowded systems of rotationally asymmetric hard kite particles

Emergent tetratic order in crowded systems of rotationally asymmetric hard kite particles

Considering multi-body systems of monodisperse hard Brownian particles, it remains challenging to predict the forms of order that can emerge in their dense assembled structures. Surprisingly, here, using Monte Carlo simulations, we show that tetratic-ordered phases emerge in a dense two-dimensional...

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Bibliographic Details
Published in:Nature communications Vol. 11; no. 1; p. 2064
Main Authors: Hou, Zhanglin, Zong, Yiwu, Sun, Zhaoyan, Ye, Fangfu, Mason, Thomas G., Zhao, Kun
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 28-04-2020
Nature Publishing Group
Nature Portfolio
Subjects:
639/301/923/916
639/301/923/919
639/301/923/966
639/766/119
Asymmetry
Brownian motion
Computer simulation
Crystal structure
Humanities and Social Sciences
Kites
Monte Carlo simulation
Multibody systems
multidisciplinary
Particle shape
Science
Science (multidisciplinary)
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Summary:Considering multi-body systems of monodisperse hard Brownian particles, it remains challenging to predict the forms of order that can emerge in their dense assembled structures. Surprisingly, here, using Monte Carlo simulations, we show that tetratic-ordered phases emerge in a dense two-dimensional system of hard kites that are rotationally asymmetric and have opposite 72° and α ≈ 90° internal angles. We observe a new tetragonal rectangular crystal (TRX) phase possessing (quasi-)long-range fourfold molecular-orientational order. We propose a method based on local polymorphic configurations of neighboring particle pairs (LPC-NPPs) to understand this emergent tetratic order and show that LPC-NPPs can be useful for predicting orientational order in such systems. To examine the dependence of the tetratic order on α , we apply LPC-NPP analysis to other hard kites for 54° ≤ α ≤ 144°. Our work provides insight into the creation of novel ordered materials by rationally designing particle shape based on anticipated LPC-NPPs. For colloidal particles, it remains challenging to predict the forms of order that can emerge in their dense assembled structures. Here, the authors show, by Monte Carlo simulations, that tetratic-ordered phases emerge in a dense two-dimensional system of hard kites that are rotationally asymmetric.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-020-15723-w