Topological and geometric decomposition of nematic textures

TL;DR

This paper introduces a geometric method to classify complex defect structures in nematic liquid crystals by defining a defect rank, which correlates with intuitive point charges and considers energy constraints.

Contribution

It proposes a novel geometric approach to determine topological charges in nematic textures, addressing ambiguities in defect classification.

Findings

Defect rank correlates with intuitive point charge perception.

Geometric rules enable classification of complex defect structures.

Energy constraints influence the validity of the defect classification.

Abstract

Directional media, such as nematic liquid crystals and ferromagnets, are characterized by their topologically stabilized defects in directional order. In nematics, boundary conditions and surface-treated inclusions often create complex structures, which are difficult to classify. Topological charge of point defects in nematics has ambiguously defined sign and its additivity cannot be ensured when defects are observed separately. We demonstrate how the topological charge of complex defect structures can be determined by identifying and counting parts of the texture that satisfy simple geometric rules. We introduce a parameter called the defect rank and show that it corresponds to what is intuitively perceived as a point charge based on the properties of the director field. Finally, we discuss the role of free energy constraints in validity of the classification with the defect rank.