Nucleation of a three-state spin model on complex networks

Detection of community structures in complex networks is a common challenge in the study of complex networks. Recently, various methods have been proposed to discover community structures at different scales. Here, the multiscale methods based on Potts spin model for community detection are described and compared in the analysis of community structures of several networks. We give a critical analysis of the multiscale methods, showing a kind of limitation that the methods may suffer from when the community size difference is very broad, the breakup of (large) communities will appear before the merger of (small) communities disappears. In particular, we give the explicit expressions for the critical points of the merger and breakup of communities and derive the sufficient conditions (in the form of upper limits) that indicate when the Potts model methods suffer from the limitation. We apply the theoretical results to model networks and show that the method using the configuration null model (i.e., a random graph model as comparison that has the same degree distribution as the network under study) may not recover the full structure of the model network, whereas the method using the Erdös-Rényi null model will do so.

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Optical Potts machine through networks of three-photon down-conversion oscillators

Nanophotonics ◽

10.1515/nanoph-2020-0256 ◽

2020 ◽

Vol 9 (13) ◽

pp. 4199-4205 ◽

Cited By ~ 2

Author(s):

Mostafa Honari-Latifpour ◽

Mohammad-Ali Miri

Keyword(s):

Nonlinear Process ◽

Spin Model ◽

Combinatorial Problems ◽

Optical Simulation ◽

Parametric Oscillators ◽

All Optical ◽

Potential Applications ◽

Lattice Spin Models ◽

State Spin ◽

Down Conversion

AbstractIn recent years, there has been a growing interest in optical simulation of lattice spin models for applications in unconventional computing. Here, we propose optical implementation of a three-state Potts spin model by using networks of coupled parametric oscillators with phase tristability. We first show that the cubic nonlinear process of spontaneous three-photon down-conversion is accompanied by a tristability in the phase of the subharmonic signal between three states with 2π/3 phase contrast. The phase of such a parametric oscillator behaves like a three-state spin system. Next, we show that a network of dissipatively coupled three-photon down-conversion oscillators emulates the three-state planar Potts model. We discuss potential applications of the proposed system for all-optical optimization of combinatorial problems such as graph 3-COL and MAX 3-CUT.

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Magnetic Properties of Quasi-One-Dimensional Crystals Formed by Graphene Nanoclusters and Embedded Atoms of the Transition Metals

Crystals ◽

10.3390/cryst9050251 ◽

2019 ◽

Vol 9 (5) ◽

pp. 251 ◽

Cited By ~ 2

Author(s):

Vladislav O. Cheranovskii ◽

Viktor V. Slavin ◽

Elena V. Ezerskaya ◽

Andrei L. Tchougréeff ◽

Richard Dronskowski

Keyword(s):

Transition Metals ◽

Quantum Monte Carlo ◽

Graphene Nanoribbons ◽

Spin Model ◽

Group Method ◽

Excitation Spectra ◽

Density Matrix Renormalization ◽

Coupling Parameters ◽

Frustrated Systems ◽

State Spin

Using the density-matrix renormalization group method and quantum Monte Carlo simulation, we studied numerically the energy spectrum and thermodynamics of the quantum Heisenberg spin model for narrow graphene nanoribbons and their derivatives with periodically embedded heteroatoms. For several nanoribbon structures we found macroscopic ground state spin, gapless lowest excitation spectra and intermediate magnetization plateaus at low temperatures. We also studied the lowest energy states of frustrated systems formed by triangular graphitic clusters connected by bridged ions of transition metals. On the base of many-body perturbation theory and the exact diagonalization method, we showed the possibility of spin switching for this model due to the change the corresponding coupling parameters.

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