Franz Eder

TL;DR: An accurate measurement and a quantitative analysis of electron-beam-induced displacements of carbon atoms in single-layer graphene show that a static lattice approximation is not sufficient to describe knock-on damage in this material, while a very good agreement between calculated and experimental cross sections is obtained.

TL;DR: A direct, atomic-level structural analysis during a crystal-to-glass transformation, including all intermediate stages, is presented, utilizing the electron beam of a transmission electron microscope, which allows us to capture the atomic structure at each step.

TL;DR: This work shows that they can access the same point on both surfaces of a few-layer graphene membrane simultaneously, using a dual-probe scanning tunneling microscopy (STM) setup, and reveals different regimes of stability of few- layer graphene.

TL;DR: In this article, the authors present a computational study on the topology, energetics, and structural deformations for a large number of experimentally observed defect configurations in graphene and find that both the number of lost hexagonal carbon rings and introduced nonhexagonal rings increase linearly as a function of the vacancy order (number of missing atoms).