Gao, Guanhui and Gao, Wei and Cannuccia, E. and Taha-Tijerina, Jaime and Balicas, Luis and Mathkar, Akshay and Narayanan, T. N. and Liu, Zhen and Gupta, Bipin K. and Peng, Juan (2012) Artificially Stacked Atomic Layers: Toward New van der Waals Solids. Nano Letters, 12 (7). pp. 3518-3525. ISSN 1530-6984

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Abstract

Strong in-plane bonding and weak van der Waals interplanar interactions characterize a large number of layered materials, as epitomized by graphite. The advent of graphene (G), individual layers from graphite, and atomic layers isolated from a few other van der Waals bonded layered compounds has enabled the ability to pick, place, and stack atomic layers of arbitrary compositions and build unique layered materials, which would be otherwise impossible to synthesize via other known techniques. Here we demonstrate this concept for solids consisting of randomly stacked layers of graphene and hexagonal boron nitride (h-BN). Dispersions of exfoliated h-BN layers and graphene have been prepared by liquid phase exfoliation methods and mixed, in various concentrations, to create artificially stacked h-BN/G solids. These van der Waals stacked hybrid solid materials show interesting electrical, mechanical, and optical properties distinctly different from their starting parent layers. From extensive first principle calculations we identify (i) a novel approach to control the dipole at the h-BN/G interface by properly sandwiching or sliding layers of h-BN and graphene, and (ii) a way to inject carriers in graphene upon UV excitations of the Frenkell-like excitons of the h-BN layer(s). Our combined approach could be used to create artificial materials, made predominantly from inter planar van der Waals stacking of robust bond saturated atomic layers of different solids with vastly different properties.

Item Type: Article
Additional Information: Copyright for this article belongs to M/s American Chemical Society.
Subjects: Chemistry
Materials Science
Applied Physics/Condensed Matter
Nanoscience/ Nanotechnology
Physical Chemistry/Chemical Physics
Divisions: UNSPECIFIED
Depositing User: Users 27 not found.
Date Deposited: 05 Feb 2020 11:48
Last Modified: 05 Feb 2020 11:48
URI: http://npl.csircentral.net/id/eprint/3688

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