AI Article Synopsis
- Recent research is questioning current microscopic theories of nematic elasticity, particularly for systems with bent molecules or semiflexible polymers that don't fit the rigid rod model.
- The authors suggest an updated version of Onsager-Straley's theory, incorporating a new approach to model how the orientation of particles changes with deformation.
- The study highlights how particle shape influences elastic constants in ways that existing theories overlook, offering insights for better models of semiflexible liquid crystal polymers.
Article Abstract
The existing microscopic theories for elasticity of nematics are challenged by recent findings on systems, whether bent molecules or semiflexible polymers, which do not comply with the model of rigid rodlike particles. Here, we propose an extension of Onsager-Straley second-virial theory, based on a model for the orientational distribution function that, through explicit account of the director profile along a particle, changes in the presence of deformations. The elastic constants reveal specific effects of particle morphology, which are not captured by the existing theories. This paves the way to microscopic modeling of the elastic properties of semiflexible liquid crystal polymers, which is a longstanding issue.
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| http://dx.doi.org/10.1103/PhysRevLett.125.267802 | DOI Listing |
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