The capacitance and electromechanical coupling of lipid membranes close to transitions. The effect of electrostriction

TL;DR

This paper explores how lipid membrane capacitance and electromechanical properties are affected near phase transitions, highlighting electrostriction effects that influence charge uptake and membrane behavior under voltage and pressure changes.

Contribution

It introduces the concept of capacitive susceptibility with a maximum at the melting transition and analyzes electrostriction effects on membrane electromechanics.

Findings

Capacitance peaks at melting transition due to electrostriction.

Small voltage changes can cause large charge uptake.

Pressure influences membrane capacitance and electromechanical behavior.

Abstract

Biomembranes are thin capacitors with the unique feature of displaying phase transitions in a physiologically relevant regime. We investigate the voltage and lateral pressure dependence of their capacitance close to their chain melting transition. Since the gel and the fluid membrane have different area and thickness, the capacitance of the two membrane phases is different. In the presence of external fields, charges exert forces that can influence the state of the membrane, thereby influencing the transition temperature. This phenomenon is called electrostriction. We show that this effect allows us to introduce a capacitive susceptibility that assumes a maximum in the melting transition with an associated excess charge. As a consequence, there exist voltage regimes where a small change in voltage can lead to a large uptake of charge and a large capacitive current. Furthermore, we consider electromechanical behavior such as pressure-induced changes in capacitance, and the application of such concepts in biology.