Stress-controlled Poisson ratio of a crystalline membrane: Application to graphene

Abstract

We demonstrate that a key elastic parameter of a suspended crystalline membrane---the Poisson ratio (PR) ---is a non-trivial function of the applied stress σ and of the system size L, i.e., =L(σ). We consider a generic 2D membrane embedded into space of dimensionality 2+dc. (The physical situation corresponds to dc=1.) A particularly important application of our results is free-standing graphene. We find that at very low stress, where the membrane exhibits a linear response, the PR L(0) decreases with increasing L and saturates for L ∞ at a value which depends on the boundary conditions and is essentially different from the value =-1/3 previously predicted by the membrane theory within a self-consisted scaling analysis. By increasing σ, one drives a membrane into a non-linear regime characterized by a universal value of PR that depends solely on dc. This universal non-linear PR acquires its minimum value min=-1 in the limit dc ∞. With the further increase of σ, the PR changes sign and finally saturates at a positive non-universal value prescribed by the conventional elasticity theory. We also show that one should distinguish between the absolute and differential PR ( and diff, respectively). While coinciding in the limits of very low and very high stresses, they differ in general, ≠ diff. In particular, in the non-linear universal regime, diff takes a universal value which, similarly to absolute PR, is a function solely of dc but is different from the universal value of . In the limit dc ∞, the universal value of diff tends to -1/3, at variance with the limiting value -1 of . Finally, we briefly discuss generalization of these results to a disordered membrane.