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Auteurs principaux: Kumar, Naveen, Chhimpa, Rahul, Yadav, Avinash Chand
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2605.25884
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author Kumar, Naveen
Chhimpa, Rahul
Yadav, Avinash Chand
author_facet Kumar, Naveen
Chhimpa, Rahul
Yadav, Avinash Chand
contents We consider the Olami-Feder-Christensen (OFC) model on a square two-dimensional lattice with open boundary conditions. The model exhibits self-organized criticality and explains the Gutenberg-Richter law observed for earthquakes. A parameter $α$ controls the level of local dissipation: $α< 0.25$ corresponds to locally dissipative and $α= 0.25$ marks locally conservative dynamics. The avalanche size distribution follows a decaying power-law, with a non-universal critical exponent. Here, we examine the probability distribution of the difference between avalanche size and area. This quantity remains unexplored despite being of significant interest in earthquakes. We find a power-law with a scaling exponent close to one in the conservative OFC model. The scaling feature vanishes even for the physically relevant case $α= 0.21$. To examine the robustness of such features, we also examine the same quantity in the BTW and Manna sandpile models on a square lattice. We find that the power-law behavior survives for these systems due to locally conservative dynamics. We further examine the local and total stress fluctuations in the OFC model for both locally conservative and dissipative dynamics. The finite-size scaling analysis of the power spectra for the stress fluctuations reveals qualitatively the same but quantitatively significantly different behavior. The dynamic exponent describing the divergence of the correlation time with system size changes from nearly ballistic in the conservative to diffusive behavior in the locally dissipative dynamics with $α= 0.21$. The local stress also exhibits a signature of nearly canonical $1/f$ noise in the intermediate regime, and $1/f^2$-type scaling dominates the high-frequency regime.
format Preprint
id arxiv_https___arxiv_org_abs_2605_25884
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Scaling features for the stress fluctuations in the OFC model
Kumar, Naveen
Chhimpa, Rahul
Yadav, Avinash Chand
Statistical Mechanics
We consider the Olami-Feder-Christensen (OFC) model on a square two-dimensional lattice with open boundary conditions. The model exhibits self-organized criticality and explains the Gutenberg-Richter law observed for earthquakes. A parameter $α$ controls the level of local dissipation: $α< 0.25$ corresponds to locally dissipative and $α= 0.25$ marks locally conservative dynamics. The avalanche size distribution follows a decaying power-law, with a non-universal critical exponent. Here, we examine the probability distribution of the difference between avalanche size and area. This quantity remains unexplored despite being of significant interest in earthquakes. We find a power-law with a scaling exponent close to one in the conservative OFC model. The scaling feature vanishes even for the physically relevant case $α= 0.21$. To examine the robustness of such features, we also examine the same quantity in the BTW and Manna sandpile models on a square lattice. We find that the power-law behavior survives for these systems due to locally conservative dynamics. We further examine the local and total stress fluctuations in the OFC model for both locally conservative and dissipative dynamics. The finite-size scaling analysis of the power spectra for the stress fluctuations reveals qualitatively the same but quantitatively significantly different behavior. The dynamic exponent describing the divergence of the correlation time with system size changes from nearly ballistic in the conservative to diffusive behavior in the locally dissipative dynamics with $α= 0.21$. The local stress also exhibits a signature of nearly canonical $1/f$ noise in the intermediate regime, and $1/f^2$-type scaling dominates the high-frequency regime.
title Scaling features for the stress fluctuations in the OFC model
topic Statistical Mechanics
url https://arxiv.org/abs/2605.25884