# Statistical mechanics of asymmetric tethered membranes: spiral and   crumpled phases

**Authors:** Tirthankar Banerjee, Niladri Sarkar, John Toner, Abhik Basu

arXiv: 1901.02848 · 2019-06-05

## TL;DR

This paper develops an elastic theory for asymmetric tethered membranes, revealing novel spiral and crumpled phases, with universal properties and potential experimental realizations.

## Contribution

It introduces a new theoretical framework for asymmetric membranes, predicting a double-spiral phase and a scale-dependent crumpling transition not seen in symmetric membranes.

## Key findings

- Discovery of a double-spiral phase with universal exponents
- Identification of a crumpling instability triggered by asymmetry
- Calculation of the maximum size before crumpling, L_c, as a function of parameters

## Abstract

We develop the elastic theory for inversion-asymmetric tethered membranes and use it to identify and study their possible phases. Asymmetry in a tethered membrane causes spontaneous curvature, which in general depends upon the local in-plane dilation of the tethered network. This in turn leads to long-ranged interactions between the local mean and Gaussian curvatures, which is not present in symmetric tethered membranes. This interplay between asymmetry and Gaussian curvature leads to a new {\em double-spiral} phase not found in symmetric tethered membranes. At temperature $T=0$, tethered membranes of arbitrarily large size are always rolled up tightly into a conjoined pair of Archimedes' spirals. At finite $T$ this spiral structure swells up significantly into algebraic spirals characterized by universal exponents which we calculate. These spirals have long range orientational order, and are the asymmetric analogs of statistically flat symmetric tethered membranes. We also find that sufficiently strong asymmetry can trigger a structural instability leading to crumpling of these membranes as well. This provides a new route to crumpling for asymmetric tethered membranes. We calculate the maximum linear extent $L_c$ beyond which the membrane crumples, and calculate the universal dependence of $L_c$ on the membrane parameters. By tuning the asymmetry parameter, $L_c$ can be continuously varied, implying a {\em scale-dependent} crumpling. Our theory can be tested on controlled experiments on lipids with artificial deposits of spectrin filaments, in-vitro experiments on %\sout{artificial deposition of spectrin filaments on} red blood cell membrane extracts, %\sout{after %depletion of adenosine-tri-phosphate molecules} and on graphene coated on one side.

## Full text

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## Figures

18 figures with captions in the complete paper: https://tomesphere.com/paper/1901.02848/full.md

## References

60 references — full list in the complete paper: https://tomesphere.com/paper/1901.02848/full.md

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Source: https://tomesphere.com/paper/1901.02848