Matthew C. F. Wander scite author profile

The interaction of interfacial water with graphitic carbon at the atomic scale is studied as a function of the hydrophobicity of epitaxial graphene. High resolution X-ray reflectivity shows that the graphene-water contact angle is controlled by the average graphene thickness, due to the fraction of the film surface expressed as the epitaxial buffer layer whose contact angle (contact angle θ c = 73°) is substantially smaller than that of multilayer graphene (θ c = 93°). Classical and ab initio molecular dynamics simulations show that the reduced contact angle of the buffer layer is due to both its epitaxy with the SiC substrate and the presence of interfacial defects. This insight clarifies the relationship between interfacial water structure and hydrophobicity, in general, and suggests new routes to control interface properties of epitaxial graphene.2

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Structure and Charge Hopping Dynamics in Green Rust

Wander

Rosso

Schoonen

2007

J. Phys. Chem. C

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Green rust is a family of mixed-valent iron phases formed by a number of abiotic and biotic processes under alkaline suboxic conditions. Because of its high Fe2+ content, green rust is a potentially important phase for pollution remediation by serving as a powerful electron donor for reductive transformation. However, mechanisms of oxidation of this material are poorly understood. An essential component of the green rust structure is a mixed-valent brucite-like Fe(OH)2 sheet comprised of a two-dimensional network of edge-sharing iron octahedra. Liquid nitrogen temperature Mössbauer spectra show that any Fe2+−Fe3+ valence interchange reaction must be slower than approximately 107 s-1. Using Fe(OH)2 as structural analogue for reduced green rust, we performed Hartree−Fock calculations on periodic slab models and cluster representations to determine the structure and hopping mobility of Fe3+ hole polarons in this material, providing a first principles assessment of the Fe2+−Fe3+ valence interchange reaction rate. The calculations show that, among three possible symmetry unique iron-to-iron hops within a sheet, a hop to next-nearest neighbors at an intermediate distance of 5.6 Å is the fastest. The predicted rate is on the order of 1010 s-1 (at 300 K) and 103 s-1 (at 70 K), consistent the Mössbauer-based constraint. All other possibilities, including hopping across interlayer spaces, are predicted to be slower than 107 s-1. Collectively, the findings suggest the possibility of hole self-diffusion along sheets as a mechanism for regeneration of lattice Fe2+ sites, consistent with previous experimental observations of edge-inward progressive oxidation of green rust.

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Matthew C. F. Wander

Understanding controls on interfacial wetting at epitaxial graphene: Experiment and theory

Structure and Charge Hopping Dynamics in Green Rust

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