“
“The understanding of the structural and thermal properties of membranes, low-dimensional flexible systems in a space of higher dimension, is pursued in many fields from string theory to chemistry and biology, The case of a two-dimensional (2D) membrane in three dimensions is the relevant one for dealing with real materials. unlike Traditionally, membranes are primarily discussed In the context of biological membranes and soft matter in general. The complexity of these systems hindered a realistic description of their Interatomic structures based on a truly microscopic approach. Therefore, theories of membranes were developed mostly within phenomenological models. From the point of view of statistical mechanics, membranes at finite temperature are systems governed by interacting long-range fluctuations.

Graphene, the first truly two-dimensional system consisting of just one layer of carbon atoms, provides a model system for the development of a microscopic description of membranes. In the same way that geneticists have used Drosophila as a gateway to probe more complex questions, theoretical chemists and physicists can use graphene as a simple model membrane to study both phenomenological theories and experiments. In this Account, we review key results in the microscopic theory of structural and thermal properties of graphene and compare them with the predictions of phenomenological theories. The two approaches are in good agreement for the various scaling properties of correlation functions of atomic displacements.

However, some other properties, such as the temperature dependence of the bending rigidity, cannot be understood based on phenomenological approaches. We also consider graphene at very high temperature and compare the results with existing models for two-dimensional melting. The melting of graphene presents a different scenario, and we describe that process as the decomposition of the graphene layer into entangled carbon chains.”
“Because of its atomic thickness, excellent properties, and widespread applications, graphene is regarded as one of the most promising candidate materials for nanoelectronics. The wider use of graphene will require processes Brefeldin_A that produce this material in a controllable manner. In this Account, we focus kinase inhibitor Wortmannin on our recent studies of the controllable chemical vapor deposition (CVD) growth of graphene, especially few-layer graphene (FIG), and the applications of this material in electronic devices.

CVD provides various means of control over the morphologies of the produced graph ene.