Phasonic Diffusion and Self-confinement of Decagonal Quasicrystals in Hyperspace

Hielscher, Johannes; Martinsons, M.; Schmiedeberg, Michael; Kapfer, Sebastian C.

doi:10.1088/1742-6596/1458/1/012018

Cited by 2 publications

(3 citation statements)

References 13 publications

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“…While we can study the dynamics of local phasonic flips over long times in much smaller systems, we cannot explore the phasonic excitations that matter for the long-distance behavior of the correlation functions and that correspond to rearrangements correlated over long distances which are only accessible with large simulation boxes. Simulations where exclusively phasonic flips can occur indicate that phasonic flips are part of thermal equilibrium [59] and the structure can still be dislocation free or at least usually no isolated dislocations occur. Furthermore, the logarithmic decay of the correlations of phasonic displacements [42,43] prohibits a perfect long-range phasonic order.…”

Section: Dislocations and Phason Relaxationmentioning

confidence: 99%

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Event-chain Monte Carlo simulations of the liquid to solid transition of two-dimensional decagonal colloidal quasicrystals

Martinsons

Hielscher

Kapfer

et al. 2019

J. Phys.: Condens. Matter

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In event-chain Monte Carlo simulations we model colloidal particles in two dimensions that interact according to an isotropic short-ranged pair potential which supports the two typical length scales present in decagonal quasicrystals. We investigate the assembled structures as we vary the density and temperature. Our special interest is related to the transition from quasicrystal to liquid. We find a one-step first-order melting transition without a pentahedratic phase as predicted within the KTHNY melting theory for quasicrystals. However, we discover that the slow relaxation of phasonic flips, i.e. rearrangements of the particles due to additional degrees of freedom in quasicrystals, changes the positional correlation functions such that structures with long-range orientational correlations but exponentially decaying positional correlations are observed.

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Section: Dislocations and Phason Relaxationmentioning

confidence: 99%

“…over long distances which are only accessible with large simulation boxes. Simulations where exclusively phasonic flips can occur indicate that phasonic flips are part of thermal equilibrium [59] and the structure can still be dislocation free or at least usually no isolated dislocations occur.…”

Section: Dislocations and Phason Relaxationmentioning

confidence: 99%

Event-chain Monte Carlo simulations of the liquid to solid transition of two-dimensional decagonal colloidal quasicrystals

Martinsons

Hielscher

Kapfer

et al. 2019

J. Phys.: Condens. Matter

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“…One of the reasons why it is interesting to study quasicrystals, is the flexibility they offer due to the variety of symmetries that can be produced, which can be of great importance in the optoelectronics industry [45][46][47], making high symmetry quasicrystals attractive. Another reason why these systems are interesting is the existence of phasons [48][49][50][51][52], that is, thermal excitations that propagate in the lattice without energy cost generating phasonic flips [53], which contribute to the specific heat in a similar way in which the phonons do in the periodic crystals. Just as phonons have a set of d phononic modes, where d is the dimension of the system, phasons also have a set of r − d phasonic modes, where r is the rank of the quasicrystal, i.e., the number of wave vectors linearly independent necessary to generate the reciprocal lattice of the quasiperiodic structure [21,54,55].…”

Section: Introductionmentioning

confidence: 99%

Efficient algorithm for simulating particles in true quasiperiodic environments

Sosa¹,

Kraemer²

2022

J. Phys. A: Math. Theor.

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We introduce an algorithm based on generalized dual method (GDM) to efficiently study the dynamics of a particle in quasiperiodic environments without the need to use periodic approximations or to save the information of the vertices that make up the quasiperiodic lattice. We show that the computation time and the memory required to find the tile in which a particle is located as a function of the distance R to the center of symmetry remains constant in our algorithm, while using the GDM directly both quantities go like R 2. This allows us to perform realistic simulations with low consumption of computational resources. The algorithm can be used to study any quasiperiodic lattice that can be produced by the cut-and-project method. Using this algorithm, we have calculated the free path length distribution in quasiperiodic Lorentz gases reproducing previous results and for systems with high symmetries at the Boltzmann–Grad limit. We have found for the Boltzmann–Grad limit, that the distribution of free paths depends on the rank r of the quasiperiodic system and not on its symmetry. The distribution as a function of the free path length l appears to be a combination of exponential decay and a power-law behavior. The latter seems to become important only for probabilities less than ( 2 r − 2 r ( r + 1 ) ) − 1 , showing an exponential decaying free-path length distribution for r → ∞, similar to what is observed in disordered systems.

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Phasonic Diffusion and Self-confinement of Decagonal Quasicrystals in Hyperspace

Cited by 2 publications

References 13 publications

Event-chain Monte Carlo simulations of the liquid to solid transition of two-dimensional decagonal colloidal quasicrystals

Event-chain Monte Carlo simulations of the liquid to solid transition of two-dimensional decagonal colloidal quasicrystals

Efficient algorithm for simulating particles in true quasiperiodic environments

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