On the Role of Nanometer Scale Structure on Interfacial Energy

Author(s)

Kuna, Jeffrey James; Voitchovsky, Kislon; Stellacci, Francesco; Singh, Chetana; Jiang, Hao; Mwenifumbo, Steve; Ghorai, Pradip K.; Stevens, Molly M.; Glotzer, Sharon C.; ... Show more Show less

Alternative title

The effect of nanometre-scale structure on interfacial energy

Abstract

Natural surfaces are often structured with nanometre-scale domains, yet a framework providing a quantitative understanding of how nanostructure affects interfacial energy, gammaSL, is lacking. Conventional continuum thermodynamics treats gammaSL solely as a function of average composition, ignoring structure. Here we show that, when a surface has domains commensurate in size with solvent molecules, gammaSL is determined not only by its average composition but also by a structural component that causes gammaSL to deviate from the continuum prediction by a substantial amount, as much as 20% in our system. By contrasting surfaces coated with either molecular (<2 nm) or larger scale domains (>5 nm), we find that while the latter surfaces have the expected linear dependence of gammaSL on surface composition, the former exhibit a markedly different non-monotonic trend. Molecular dynamics simulations show how the organization of the solvent molecules at the interface is controlled by the nanostructured surface, which in turn appreciably modifies gammaSL.

Date issued

2009-09

URI

http://hdl.handle.net/1721.1/58479

Department

Massachusetts Institute of Technology. Department of Materials Science and Engineering

Journal

Nature Materials

Publisher

Nature Publishing Group

Citation

Kuna, Jeffrey J. et al. “The effect of nanometre-scale structure on interfacial energy.” Nat Mater 8.10 (2009): 837-842.

Version: Author's final manuscript

ISSN

1476-1122

1476-4660