Strain Solitons and Topological Defects in Bilayer Graphene

TL;DR

This study uses electron microscopy to characterize the nanoscale structure and dynamics of strain solitons and topological defects in bilayer graphene, revealing their potential impact on its electronic and mechanical properties.

Contribution

First direct nanoscale measurements of soliton boundaries and topological defects in bilayer graphene, including their widths, motion, and structure, advancing understanding of their role in material properties.

Findings

Solitons have widths of 6-11 nm with atomic registry shifts.

Soliton motion observed during heating above 1000°C.

Structures are abundant and influence electronic and mechanical behavior.

Abstract

Spontaneous symmetry-breaking, where the ground state of a system has lower symmetry than the underlying Hamiltonian, is ubiquitous in physics. It leads to multiply-degenerate ground states, each with a different "broken" symmetry labeled by an order parameter. The variation of this order parameter in space leads to soliton-like features at the boundaries of different broken-symmetry regions and also to topological point defects. Bilayer graphene is a fascinating realization of this physics, with an order parameter given by its interlayer stacking coordinate. Bilayer graphene has been a subject of intense study because in the presence of a perpendicular electric field, a band gap appears in its electronic spectrum [1-3] through a mechanism that is intimately tied to its broken symmetry. Theorists have further proposed that novel electronic states exist at the boundaries between broken-symmetry stacking domains [4-5]. However, very little is known about the structural properties of these boundaries. Here we use electron microscopy to measure with nanoscale and atomic resolution the widths, motion, and topological structure of soliton boundaries and topological defects in bilayer graphene. We find that each soliton consists of an atomic-scale registry shift between the two graphene layers occurring over 6-11 nm. We infer the minimal energy barrier to interlayer translation and observe soliton motion during in-situ heating above 1000 {\deg}C. The abundance of these structures across a variety samples, as well as their unusual properties, suggests that they will have substantial effects on the electronic and mechanical properties of bilayer graphene.