Phase Behavior and Structure of a New Colloidal Model System of Bowl-Shaped Particles

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Simulation studies of self-assembly of end-tethered nanorods in solution and role of rod aspect ratio and tether length J. Chem. Phys. 125, 184903 (2006) We present a double-charge model for the interaction between parallel polarizable hard spherocylinders subject to an external electric field. Using Monte Carlo simulations and free-energy calculations, we predict the phase behaviour for this model as a function of the density and electric field strength, at a fixed length-to-diameter ratio L/D = 5. The resulting phase diagram contains, in addition to the well-known nematic, smectic A, ABC crystal, and columnar phases, a smectic C phase, and a low temperature crystal X phase. We also find a string fluid at low densities and field strengths, resembling results found for dipolar spheres.

“…(12). We note that the integration path was smooth and no hysteresis was observed along the integration path.…”

Section: Free Energy Of the Columnar Phasementioning

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Phase behaviour of polarizable colloidal hard rods in an external electric field: A simulation study

Troppenz

Filion

Roij

et al. 2014

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“…[1][2][3][4][5][6][7][8] Such samples were used to experimentally study self-assembly and mesophase behavior. [6][7][8][9][10][11] Concurrently, new simulation techniques were developed to explain the experimentally observed phenomenology and to tackle the complex numerical problems that such investigations bring about. 8,[12][13][14][15][16][17][18][19][20][21][22][23] Most of these simulation studies focussed on convex particles in two-and three-dimensional (2D and 3D) systems, see Refs.…”

Section: Introductionmentioning

confidence: 99%

Phase diagram of octapod-shaped nanocrystals in a quasi-two-dimensional planar geometry

Graaf

Qiao

et al. 2013

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Recently, we reported the formation of crystalline monolayers consisting of octapod-shaped nanocrystals (so-called octapods) that had arranged in a square-lattice geometry through drop deposition and fast evaporation on a substrate [W. Qi, J. de Graaf, F. Qiao, S. Marras, L. Manna, and M. Dijkstra, Nano Lett. 12, 5299 (2012)]. In this paper we give a more in-depth exposition on the Monte Carlo simulations in a quasi-two-dimensional (quasi-2D) geometry, by which we modelled the experimentally observed crystal structure formation. Using a simulation model for the octapods consisting of four hard interpenetrating spherocylinders, we considered the effect of the pod length-to-diameter ratio on the phase behavior and we constructed the full phase diagram. The methods we applied to establish the nature of the phase transitions between the various phases are discussed in detail. We also considered the possible existence of a Kosterlitz-Thouless-type phase transition between the isotropic liquid and hexagonal rotator phase for certain pod lengthto-diameter ratios. Our methods may prove instrumental in guiding future simulation studies of similar anisotropic nanoparticles in confined geometries and monolayers.

“…Only recently were the first attempts made to study systems that contain relatively complex curved particles. Nonconvex shapes with sharp edges and smooth surfaces, such as superdisks, 79 bowls, 80 and curved triangles, 71 have also come under investigation. For bowls 80 an overlap algorithm was devised unique to this shape.…”

Section: B Triangular-tessellation-based Overlap Algorithmsmentioning

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

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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.