Self-assembly of a colloidal interstitial solid with tunable sublattice doping

L. Filion; M. Hermes; R. Ni; E. C.M. Vermolen; A. Kuijk; C. G. Christova; J. C.P. Stiefelhagen; T. Vissers; A. Van Blaaderen; M. Dijkstra

doi:10.1103/PhysRevLett.107.168302

Self-assembly of a colloidal interstitial solid with tunable sublattice doping

L. Filion^*, M. Hermes, R. Ni, E. C.M. Vermolen, A. Kuijk, C. G. Christova, J. C.P. Stiefelhagen, T. Vissers, A. Van Blaaderen, M. Dijkstra

^*Corresponding author for this work

Utrecht University

Research output: Contribution to journal › Article › peer-review

35 Citations (Scopus)

Abstract

We determine the phase diagram of a binary mixture of small and large hard spheres with a size ratio of 0.3 using free-energy calculations in Monte Carlo simulations. We find a stable binary fluid phase, a pure face-centered-cubic (fcc) crystal phase of the small spheres, and binary crystal structures with LS and LS₆ stoichiometries. Surprisingly, we demonstrate theoretically and experimentally the stability of a novel interstitial solid solution in binary hard-sphere mixtures, which is constructed by filling the octahedral holes of an fcc crystal of large spheres with small spheres. We find that the fraction of octahedral holes filled with a small sphere can be completely tuned from 0 to 1. Additionally, we study the hopping of the small spheres between neighboring octahedral holes, and interestingly, we find that the diffusion increases upon increasing the density of small spheres.

Original language	English
Article number	168302
Journal	Physical Review Letters
Volume	107
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevLett.107.168302
Publication status	Published - Oct 11 2011
Externally published	Yes

ASJC Scopus Subject Areas

General Physics and Astronomy

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10.1103/PhysRevLett.107.168302

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title = "Self-assembly of a colloidal interstitial solid with tunable sublattice doping",

abstract = "We determine the phase diagram of a binary mixture of small and large hard spheres with a size ratio of 0.3 using free-energy calculations in Monte Carlo simulations. We find a stable binary fluid phase, a pure face-centered-cubic (fcc) crystal phase of the small spheres, and binary crystal structures with LS and LS6 stoichiometries. Surprisingly, we demonstrate theoretically and experimentally the stability of a novel interstitial solid solution in binary hard-sphere mixtures, which is constructed by filling the octahedral holes of an fcc crystal of large spheres with small spheres. We find that the fraction of octahedral holes filled with a small sphere can be completely tuned from 0 to 1. Additionally, we study the hopping of the small spheres between neighboring octahedral holes, and interestingly, we find that the diffusion increases upon increasing the density of small spheres.",

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AU - Filion, L.

AU - Hermes, M.

AU - Ni, R.

AU - Vermolen, E. C.M.

AU - Kuijk, A.

AU - Christova, C. G.

AU - Stiefelhagen, J. C.P.

AU - Vissers, T.

AU - Van Blaaderen, A.

AU - Dijkstra, M.

PY - 2011/10/11

Y1 - 2011/10/11

N2 - We determine the phase diagram of a binary mixture of small and large hard spheres with a size ratio of 0.3 using free-energy calculations in Monte Carlo simulations. We find a stable binary fluid phase, a pure face-centered-cubic (fcc) crystal phase of the small spheres, and binary crystal structures with LS and LS6 stoichiometries. Surprisingly, we demonstrate theoretically and experimentally the stability of a novel interstitial solid solution in binary hard-sphere mixtures, which is constructed by filling the octahedral holes of an fcc crystal of large spheres with small spheres. We find that the fraction of octahedral holes filled with a small sphere can be completely tuned from 0 to 1. Additionally, we study the hopping of the small spheres between neighboring octahedral holes, and interestingly, we find that the diffusion increases upon increasing the density of small spheres.

AB - We determine the phase diagram of a binary mixture of small and large hard spheres with a size ratio of 0.3 using free-energy calculations in Monte Carlo simulations. We find a stable binary fluid phase, a pure face-centered-cubic (fcc) crystal phase of the small spheres, and binary crystal structures with LS and LS6 stoichiometries. Surprisingly, we demonstrate theoretically and experimentally the stability of a novel interstitial solid solution in binary hard-sphere mixtures, which is constructed by filling the octahedral holes of an fcc crystal of large spheres with small spheres. We find that the fraction of octahedral holes filled with a small sphere can be completely tuned from 0 to 1. Additionally, we study the hopping of the small spheres between neighboring octahedral holes, and interestingly, we find that the diffusion increases upon increasing the density of small spheres.

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Self-assembly of a colloidal interstitial solid with tunable sublattice doping

Abstract

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