Stability of LS and LS2 crystal structures in binary mixtures of hard and charged spheres

Hynninen, Antti-Pekka; Filion, Laura; Dijkstra, Marjolein

doi:10.1063/1.3182724

Cited by 61 publications

(116 citation statements)

References 29 publications

(49 reference statements)

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“…Solvent evapora- 20 The same conclusion holds for a size ratio γ of 0.75. Using this combination of PbSe and CdSe NCs, we have also performed solvent evaporation experiments at temperatures below 70°C.…”

mentioning

confidence: 61%

“…e γ e 0.61, AlB 2 is stable; [17][18][19] for 0.54 e γ e 0.625, NaZn 13 is stable; 18,19 and for 0.76 e γ e 0.84 it was recently established that the Laves phases (MgZn 2 , MgCu 2 , MgNi 2 ) are stable, 20 although their maximum filling fraction is lower than that of the fcc lattice. Note that between 0.63 e γ e 0.75 there are no known stable binary hard-sphere crystal structures.…”

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confidence: 99%

“…[16][17][18][19][20][21] It has been shown that the crystallization of a binary mixture of micrometer-sized colloidal hard spheres is driven only by an increase in entropy. 16,19,21 In the case of monolayerstabilized NCs in a good organic solvent, the effective interaction consists to a first approximation of van der Waals attraction between the cores and steric repulsion between the stabilizing ligand molecules.…”

mentioning

confidence: 99%

“…The self-assembled crystal structures on the TEM grids are compared with the phase diagrams as determined from free energy calculations using the Frenkel-Ladd Einstein thermodynamic integration in computer simulations for binary mixtures of hard spheres. [17][18][19][20] Using this method, the freeenergy can be determined exactly and accounts for all entropic contributions. From the available theoretical predictions, the following conclusions can be drawn (Supporting Information, Section II): apart from the single-component fcc phases, for 0.414 e γ e 0.45, NaCl is stable; 17 for 0.45…”

mentioning

confidence: 99%

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Entropy-Driven Formation of Binary Semiconductor-Nanocrystal Superlattices

Evers

Nijs²,

Filion³

et al. 2010

Nano Lett.

159

192

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One of the main reasons for the current interest in colloidal nanocrystals is their propensity to form superlattices, systems in which (different) nanocrystals are in close contact in a well-ordered three-dimensional (3D) geometry resulting in novel material properties. However, the principles underlying the formation of binary nanocrystal superlattices are not well understood. Here, we present a study of the driving forces for the formation of binary nanocrystal superlattices by comparing the formed structures with full free energy calculations. The nature (metallic or semiconducting) and the size-ratio of the two nanocrystals are varied systematically. With semiconductor nanocrystals, self-organization at high temperature leads to superlattices (AlB 2 , NaZn 13 , MgZn 2 ) in accordance with the phase diagrams for binary hard-sphere mixtures; hence entropy increase is the dominant driving force. A slight change of the conditions results in structures that are energetically stabilized. This study provides rules for the rational design of 3D nanostructured binary semiconductors, materials with promises in thermoelectrics and photovoltaics and which cannot be reached by any other technology.KEYWORDS Nanocrystals, self-assembly, superlattices, hard spheres, thermodynamics. C olloidal, monolayer-stabilized nanocrystals (NC) can be synthesized with a nearly spherical shape and with a well-defined diameter that does not vary by more than 5% in the sample. Because of their monodisperse size and shape, such NCs show a strong propensity to assemble into NC superlattices.1 More than a decade ago, the formation of single-component superlattices that consist of CdSe semiconductor NCs was reported.1 This was followed by the demonstration of binary superlattices, consisting of NCs of different diameters and different nature, that is, semiconductor, metallic, or magnetic. [1][2][3][4][5][6][7][8][9][10][11][12][13] In such systems, novel collective properties can arise from the (quantum mechanical) interactions between the different components that are in close contact in a three-dimensional (3D) ordered geometry. Some striking examples have already been reported. 3,4,14,15 For instance, a binary superlattice of two types of insulator nanoparticles is found to become conductive due to interparticle charge transfer.3 Colloidal crystallization is the only method known to date to obtain nanostructured systems with order in three dimensions. However, for further progress in the field of designed nanostructured materials, improved control of nanocolloid crystallization is a key factor.Apart from the viewpoint of emerging nanomaterials, the formation of (binary) NC superlattices is of strong interest in colloidal science. Nanocrystals have a mass that is about a million times smaller than that of the colloidal particles commonly used in crystallization studies; hence, their thermal velocity is about a factor of thousand higher. This agrees with the fact that nanocolloid crystallization is a relatively fast process, still oc...

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mentioning

confidence: 61%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Entropy-Driven Formation of Binary Semiconductor-Nanocrystal Superlattices

Evers

Nijs²,

Filion³

et al. 2010

Nano Lett.

159

192

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“…This is particularly relevant, since densest-packed candidate crystal structure need not be thermodynamically stable at all pressures for which the system crystallizes. 28,51,66,67,95 It is important to realize that there are strong finite-size effects for the prediction of candidates at finite pressure. The pressure P at which we perform the FBMC simulations only sets a range from which we sample crystal structures.…”

Section: Close-packed Crystal Structures For Anisotropic Particlesmentioning

confidence: 99%

Crystal-structure prediction via the Floppy-Box Monte Carlo algorithm: Method and application to hard (non)convex particles

Graaf

Filion

Maréchal

et al. 2012

The Journal of Chemical Physics

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In this paper, we describe the way to set up the floppy-box Monte Carlo (FBMC) method [L. Filion, M. Marechal, B. van Oorschot, D. Pelt, F. Smallenburg, and M. Dijkstra, Phys. Rev. Lett. 103, 188302 (2009)] to predict crystal-structure candidates for colloidal particles. The algorithm is explained in detail to ensure that it can be straightforwardly implemented on the basis of this text. The handling of hard-particle interactions in the FBMC algorithm is given special attention, as (soft) short-range and semi-long-range interactions can be treated in an analogous way. We also discuss two types of algorithms for checking for overlaps between polyhedra, the method of separating axes and a triangular-tessellation based technique. These can be combined with the FBMC method to enable crystal-structure prediction for systems composed of highly shape-anisotropic particles. Moreover, we present the results for the dense crystal structures predicted using the FBMC method for 159 (non)convex faceted particles, on which the findings in [J. de Graaf, R. van Roij, and M. Dijkstra, Phys. Rev. Lett. 107, 155501 (2011)] were based. Finally, we comment on the process of crystalstructure prediction itself and the choices that can be made in these simulations.

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Entropy‐Driven Phase Transitions in Colloids: From spheres to anisotropic particles

Dijkstra¹

2014

Advances in Chemical Physics

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Stability of LS and LS2 crystal structures in binary mixtures of hard and charged spheres

Cited by 61 publications

References 29 publications

Entropy-Driven Formation of Binary Semiconductor-Nanocrystal Superlattices

Entropy-Driven Formation of Binary Semiconductor-Nanocrystal Superlattices

Crystal-structure prediction via the Floppy-Box Monte Carlo algorithm: Method and application to hard (non)convex particles

Entropy‐Driven Phase Transitions in Colloids: From spheres to anisotropic particles

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