Your search keyword '"Cassi D"' showing total 4 results

1. Fractal geometry of Ising magnetic patterns: signatures of criticality and diffusive dynamics.

Author

Agliari, E., Burioni, R., Cassi, D., and Vezzani, A.

Subjects

GEOMETRY, MAGNETISM, ISING model, THERMAL diffusivity, DYNAMICS

Abstract

We investigate the geometric properties displayed by the magnetic patterns developing on a two-dimensional Ising system, when a diffusive thermal dynamics is adopted. Such a dynamics is generated by a random walker which diffuses throughout the sites of the lattice, updating the relevant spins. Since the walker is biased towards borders between clusters, the border-sites are more likely to be updated with respect to a non-diffusive dynamics and therefore, we expect the spin configurations to be affected. In particular, by means of the box-counting technique, we measure the fractal dimension of magnetic patterns emerging on the lattice, as the temperature is varied. Interestingly, our results provide a geometric signature of the phase transition and they also highlight some non-trivial, quantitative differences between the behaviors pertaining to the diffusive and non-diffusive dynamics. [ABSTRACT FROM AUTHOR]

Published

2006

2. Random walks interacting with evolving energy landscapes.

Author

Agliari, E., Burioni, R., Cassi, D., and Vezzani, A.

Subjects

DIFFUSION, RANDOM walks, LATTICE theory, TEMPERATURE, PHASE transitions

Abstract

We introduce a diffusion model for energetically inhomogeneous systems. A random walker moves on a spin-S Ising configuration, which generates the energy landscape on the lattice through the nearest-neighbors interaction. The underlying energetic environment is also made dynamic by properly coupling the walker with the spin lattice. In fact, while the walker hops across nearest-neighbor sites, it can flip the pertaining spins, realizing a diffusive dynamics for the Ising system. As a result, the walk is biased towards high energy regions, namely the boundaries between clusters. Besides, the coupling introduced involves, with respect the ordinary diffusion laws, interesting corrections depending on either the temperature and the spin magnitude. In particular, they provide a further signature of the phase-transition occurring on the magnetic lattice. [ABSTRACT FROM AUTHOR]

Published

2005

3. Diffusive thermal dynamics for the spin-S Ising ferromagnet.

Author

Agliari, E., Burioni, R., Cassi, D., and Vezzani, A.

Subjects

LATTICE theory, DYNAMICS, FERROMAGNETIC materials, MONTE Carlo method, MATHEMATICAL models

Abstract

We introduce an alternative thermal diffusive dynamics for the spin-S Ising ferromagnet realized by means of a random walker. The latter hops across the sites of the lattice and flips the relevant spins according to a probability depending on both the local magnetic arrangement and the temperature. The random walker, intended to model a diffusing excitation, interacts with the lattice so that it is biased towards those sites where it can achieve an energy gain. In order to adapt our algorithm to systems made up of arbitrary spins, some non trivial generalizations are implied. In particular, we will apply the new dynamics to two-dimensional spin-1/2 and spin-1 systems analyzing their relaxation and critical behavior. Some interesting differences with respect to canonical results are found; moreover, by comparing the outcomes from the examined cases, we will point out their main features, possibly extending the results to spin-S systems. [ABSTRACT FROM AUTHOR]

Published

2005

4. The type-problem on the average for random walks on graphs.

Author

Burioni, R., Cassi, D., and Vezzani, A.

Abstract

When averages over all starting points are considered, the type problem for the recurrence or transience of a simple random walk on an inhomogeneous network in general differs from the usual “local" type problem. This difference leads to a new classification of inhomogeneous discrete structures in terms of recurrence and transience on the average, describing their large scale topology from a “statistical" point of view. In this paper we analyze this classification and the properties connected to it, showing how the average behavior affects the thermodynamic properties of statistical models on graphs. [ABSTRACT FROM AUTHOR]

Published

2000