Structure diagram of binary Lennard-Jones clusters

Mravlak, Marko; Kister, Thomas; Kraus, Tobias; Schilling, Tanja

doi:10.1063/1.4954938

Cited by 9 publications

(11 citation statements)

References 24 publications

(30 reference statements)

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“…LJ clusters made up of two different sized particles with the same interaction potential are known to configure in a core-shell structure, with larger particles on the surface and smaller particles in the core, in order to equalise surface and bulk interactions [65,64,66,67]. In contrast, LJ clusters containing two particle types of the same size but different attractions partition in the opposite core-shell structure, in which the more strongly attractive particles make up the core and the more weakly attractive particles compose the shell [63]. Heterogeneous PAH clusters show a structure similar to the latter case, suggesting that the strength of intermolecular interactions plays a more dominant role in determining cluster structure than the molecular size differences.…”

Section: Discussionmentioning

confidence: 99%

Partitioning of polycyclic aromatic hydrocarbons in heterogeneous clusters

Bowal

Martin

Kraft

2019

Carbon

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Section: Discussionmentioning

confidence: 99%

Partitioning of polycyclic aromatic hydrocarbons in heterogeneous clusters

Bowal

Martin

Kraft

2019

Carbon

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“…by DNA-based ligands [38] or the inclusion of magnetic sub-particles [39]. This would enable us to simulate the assembly of the patchy building blocks in the form of binary icosahedral clusters with symmetric or Janus arrangements of interacting sites on the surface of clusters, which have been predicted before [10].…”

Section: Discussionmentioning

confidence: 99%

“…This quasi-spherical arrangement is a particularly stable motif in the minimal energy Lennard-Jones diagrams for binary systems of particles in a wide range of different attraction ratios. The coordinates of sub-particles were obtained from a database of minimal energy Lennard-Jones clusters [10]. In our simulations we define an icosahedral molecule as a rigid arrangement of the 42 sub-particles from the outer shell of the energy-minimized Mackay icosahedron.…”

Section: Simulation Methodsmentioning

confidence: 99%

“…Confinement of spherical gold nanoparticles inside spherical surfaces of emulsion droplets leads to an assembly of nanocrystals with superlattices corresponding to Mackay icosahedra [8]. The structures of these clusters keep the polyhedral character also for binary mixtures of particles with different attractions [10] while differences in atmospheric pressure can determine the formation of either a complex binary crystal super-lattice, core-shell, or Janus clusters in dispersions of nanoparticle with binary size distributions [11]. Mackay icosahedra have also been ob- Figure 1.…”

Section: Introductionmentioning

confidence: 99%

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On the phase diagram of Mackay icosahedra

Mravlak

Schilling

2018

The Journal of Chemical Physics

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Using Monte Carlo and molecular dynamics simulations, we investigate the equilibrium phase behavior of a monodisperse system of Mackay icosahedra. We define the icosahedra as polyatomic molecules composed of a set of Lennard-Jones subparticles arranged on the surface of the Mackay icosahedron. The phase diagram contains a fluid phase, a crystalline phase and a rotator phase. We find that the attractive icosahedral molecules behave similar to hard geometric icosahedra for which the densest lattice packing and the rotator crystal phase have been identified before. We show that both phases form under attractive interactions as well. When heating the system from the dense crystal packing, there is first a transition to the rotator crystal and then another to a fluid phase.

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“…The two first species are reactive, and their interactions are tailored to obtain (1) alloy, (2) Janus and (3) core-shell NPs [See Table I]. In the two latter cases, the coefficients are chosen by following the work of Mravlak et al who computed the most stable structures of binary nanoclusters for a large number of combination of coefficients [79]. In the alloy case, the σ parameters are chosen to obtain the Kobb-Andersen system, which crystallizes in alloy BCC structures [80][81][82][83], while the energy parameters are set in a way to roughly match the melting and boiling temperatures obtained with the core-shell and Janus systems.…”

Section: Methodsmentioning

confidence: 99%

Alloy, Janus and core–shell nanoparticles: numerical modeling of their nucleation and growth in physical synthesis

Förster

Benoit

Lam

2019

Phys. Chem. Chem. Phys.

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While alloy, core-shell and Janus binary nanoclusters are found in more and more technological applications, their formation mechanisms are still poorly understood, especially during synthesis methods involving physical approaches. In this work, we employ a very simple model of such complex systems using Lennard-Jones interactions and inert gas quenching. After demonstrating the ability of the model to well reproduce the formation of alloy, core-shell or Janus nanoparticles, we studied their temporal evolution from the gas via droplets to nanocrystalline particles. In particular, we showed that the growth mechanisms exhibit qualitative differences between these three chemical orderings. Then, we determined how the quenching rate can be used to finely tune structural characteristics of the final nanoparticles, including size, shape and crystallinity.

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Structure diagram of binary Lennard-Jones clusters

Cited by 9 publications

References 24 publications

Partitioning of polycyclic aromatic hydrocarbons in heterogeneous clusters

Partitioning of polycyclic aromatic hydrocarbons in heterogeneous clusters

On the phase diagram of Mackay icosahedra

Alloy, Janus and core–shell nanoparticles: numerical modeling of their nucleation and growth in physical synthesis

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