Transformable Super-Isostatic Crystals Self-Assembled from Segment Colloidal Rods
Abstract
Colloidal particles can spontaneously self-assemble into ordered structures, which not only can manipulate the propagation of light, but also vibration or phonons. Using Monte Carlo simulation, we study the self-assembly of perfectly aligned segment rod particles with lateral flat cutting. Under the help of surface attractions, we find that particles with different cutting degree can self-assemble into different crystal phases characterized by bond coordination z that varies from 3 to 6. Importantly, we identify a transformable super-isostatic structures with pgg symmetry and redundant bonds (z=5). We find that this structure can support either the soft bulk model or soft edge model depending on its Poisson's ratio which can be tuned from positive to negative by a uniform soft deformation. Importantly, the bulk soft modes are associated with states of self-stress along the direction of zero strain during the uniform soft deformation. This self-assembled transformable super-isostatic structure may act as mechanical metamaterials with potential application in micro-mechanical engineering.
Cite
@article{arxiv.2311.01160,
title = {Transformable Super-Isostatic Crystals Self-Assembled from Segment Colloidal Rods},
author = {Ji-Dong Hu and Ting Wang and Qun-Li Lei and Yu-qiang Ma},
journal= {arXiv preprint arXiv:2311.01160},
year = {2024}
}
Comments
12 pages,6 figures