Complex crystal structures formed by the self assembly of di-tethered nanospheres
Posted by iacovecr on Monday, October 31, 2011 in Recent Publications.
Citation:
Iacovella CR, Glotzer SC (2009) Complex crystal structures formed by the self assembly of di-tethered nanospheres, Nano Letters, 9, pp 1206–1211
DOI:10.1021/nl900051u
arXiv:0901.0957v1
Abstract:
We report the results from a computational study of the self-assembly of amphiphilic ditethered nanospheres using molecular simulation. As a function of the interaction strength and directionality of the tether−tether interactions, we predict the formation of four highly ordered phases not previously reported for nanoparticle systems. We find a double diamond structure comprised of a zinc blende (binary diamond) arrangement of spherical micelles with a complementary diamond network of nanoparticles (ZnS/D), a phase of alternating spherical micelles in a NaCl structure with a complementary simple cubic network of nanoparticles to form an overall crystal structure identical to that of AlCu2Mn (NaCl/SC), an alternating tetragonal ordered cylinder phase with a tetragonal mesh of nanoparticles described by the [8,8,4] Archimedean tiling (TC/T), and an alternating diamond phase in which both diamond networks are formed by the tethers (AD) within a nanoparticle matrix. We compare these structures with those observed in linear and star triblock copolymer systems.
Tags: Amphiphile, Diamond, Gyroid, Phase Separation, Self-assembly, Tethered Nanoparticle
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