An improved PULSE generative model samples and evaluates the partition function to reproduce thermodynamic averages on the 2D Ising model more efficiently than standard Monte Carlo.
Thermodynamic properties of chemically disordered compounds via AI-driven estimation of partition function with the PULSE method
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abstract
In this article, we present an improved version of the PULSE method (Partition function Unsupervised Learning Sampling and Evaluation) for estimating the thermodynamic properties of chemically disordered compounds. The aim is to reduce the computational cost of Monte Carlo approaches for this type of material and to demonstrate that this generative tool can estimate thermodynamic properties by sampling and estimating the partition function of the system. To validate this innovative approach, we use the 2D Ising model as a benchmark. We demonstrate that our method accurately reproduces average properties with high precision and efficiency compared to traditional Monte Carlo sampling methods. Our results highlight the efficiency and adaptability of the PULSE method, making it a valuable tool for studying materials for which conventional methods are too inefficient to compute properties affected by chemical disorder at low cost.
fields
cond-mat.stat-mech 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Thermodynamic properties of chemically disordered compounds via AI-driven estimation of partition function with the PULSE method
An improved PULSE generative model samples and evaluates the partition function to reproduce thermodynamic averages on the 2D Ising model more efficiently than standard Monte Carlo.