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تسجيل مستخدم جديدThermodynamics from a scaling Hamiltonian
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There are problems with defining the thermodynamic limit of systems with long-range interactions; as a result, the thermodynamic behavior of these types of systems is anomalous. In the present work, we review some concepts from both extensive and nonextensive thermodynamic perspectives. We use a model, whose Hamiltonian takes into account spins ferromagnetically coupled in a chain via a power law that decays at large interparticle distance $r$ as $1/r^{alpha}$ for $alphageq0$. Here, we review old nonextensive scaling. In addition, we propose a new Hamiltonian scaled by $2frac{(N/2)^{1-alpha}-1}{1-alpha}$ that explicitly includes symmetry of the lattice and dependence on the size, $N$, of the system. The new approach enabled us to improve upon previous results. A numerical test is conducted through Monte Carlo simulations. In the model, periodic boundary conditions are adopted to eliminate surface effects.
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