Structure and Pattern Formation in Biological Liquid Crystals: Insights From Theory and Simulation of Self-Assembly and Self-Organization

Abstract: This review presents theory and simulation of liquid crystal phase ordering in biological fibrous materials, solutions, and composites in the presence of elastic fields, second phase inclusions, and transport phenomena, including complex shear-extensional flow and mass transfer. Liquid crystal self-assembly through phase ordering on elastic deformable membranes is first applied to characterize the mechanisms that control the structures in plant cell walls, highlighting how curvophobic and curvophilic effects i… Show more

“…Surface pattern formation and instabilities in equilibrium or near equilibrium self-assembly are richly enhanced when considering self-organization under dissipative dynamics [84][85][86][87][88] as shown below. In the kinematics and dynamics section of this review paper, we focus on kinematics and dynamics of timedependent curvature changes in surfaces and membranes.…”

“…(1) Identifying the director orientation of a liquid crystals with the unit normal to a membrane leads to the membranology 84,101,102 model explored mainly in equilibrium scenarios but here we show how the methodology is augmented to dissipative process;…”

Geometry-structure models for liquid crystal interfaces, drops and membranes: wrinkling, shape selection and dissipative shape evolution

“…Surface pattern formation and instabilities in equilibrium or near equilibrium self-assembly are richly enhanced when considering self-organization under dissipative dynamics [84][85][86][87][88] as shown below. In the kinematics and dynamics section of this review paper, we focus on kinematics and dynamics of timedependent curvature changes in surfaces and membranes.…”

“…(1) Identifying the director orientation of a liquid crystals with the unit normal to a membrane leads to the membranology 84,101,102 model explored mainly in equilibrium scenarios but here we show how the methodology is augmented to dissipative process;…”

Geometry-structure models for liquid crystal interfaces, drops and membranes: wrinkling, shape selection and dissipative shape evolution

Biological Liquid Crystals

Ultraviolet response data of liquid crystals for bioprocess monitoring: A methodical exploration