一键导入
thermodynamics-statistical-mechanics
Use when computing partition functions, thermodynamic potentials, phase transitions, equations of state, or ensemble averages.
用 Codex 或 Claude 帮你安装 复制这段 Prompt,粘贴到 Codex、Claude 或其他助手里,让它检查 Skill 页面并帮你完成安装。
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Use when computing partition functions, thermodynamic potentials, phase transitions, equations of state, or ensemble averages.
用 Codex 或 Claude 帮你安装 复制这段 Prompt,粘贴到 Codex、Claude 或其他助手里,让它检查 Skill 页面并帮你完成安装。
基于 SOC 职业分类
MCTS-based autonomous physics problem solver with arXiv search, prior knowledge retrieval, and multi-agent reasoning. Use when you need to solve physics problems, search arXiv for relevant papers, or generate structured physics solutions with iterative refinement.
Use when solving problems involving Maxwell's equations, electrostatics, magnetostatics, electromagnetic waves, radiation, or relativistic electrodynamics.
Use when applying conservation of energy, momentum, angular momentum, charge, or other conserved quantities to constrain or solve a physical system.
Use when checking dimensional consistency, estimating physical scales, or deriving functional forms via the Buckingham Pi theorem.
Use when decomposing signals or fields into frequency/momentum components, applying Fourier transforms, or using spectral methods to solve differential equations.
Use when solving ordinary or partial differential equations numerically, including choosing integrators, discretization schemes, and stability analysis.
| name | thermodynamics_statistical_mechanics |
| description | Use when computing partition functions, thermodynamic potentials, phase transitions, equations of state, or ensemble averages. |
Apply this skill when the problem involves thermal equilibrium, partition functions, free energies, entropy, equations of state, phase transitions, or the statistical behavior of many-particle systems.
Compute thermodynamic quantities from microscopic models using ensemble theory, or apply thermodynamic identities and potentials to macroscopic systems.
microscopic_model: Hamiltonian or energy function of the systemensemble: Which ensemble to use (microcanonical, canonical, grand canonical)control_parameters: Temperature T, pressure P, chemical potential mu, external fieldsparticle_statistics: Classical, bosonic, or fermionicpartition_function: Z (or its logarithm) in the appropriate ensemblethermodynamic_potentials: F, G, Omega, S, U as functions of control parametersequations_of_state: Pressure, density, magnetization as functions of T, V, N, etc.phase_diagram: Location of phase boundaries and critical points (if applicable)Identify the ensemble.
Compute the partition function.
Derive thermodynamic quantities.
Analyze phase transitions (if applicable).
Numerical methods (if needed).