Pilihan pendaftaran
Tahun Akademik:
Gasal 2022/2023
Kelas-Offr:
AM-AM
Deskripsi:
Introduction to Statistical Physics: 1. The Scope of Statistical Physics, 2. Description of the Assemblies – Phase Space, 3. The Average Properties of an Assembly, 4. Clasical and Quantum Assemblies. Maxwell—Boltzmann Statistics: 1. Distribution Over Energies, 2. Weights of Configurations, 3. The Most Probable Configuration, 4. The Sharpness of the Configuration Maximum, 5. The Multiplier , 6. The Multiplier , 7. The Maxwell—Boltzmann Distribution. Applications of Maxwell—Boltzmann Statistics: 1. Average Properties of Systems, 2. The Clasical Perfect Gas, 3. Mean and Most Probable Velocities, 4. The Doppler Broadening of Spectral Lines, 5. Equipartition of Energy, 6. The Specific Heats of Gases, 7. The Einstein Diffusion Equation. Bose-Einstein Statistics: 1. The Bose-Einstein Distribution, 2. The Bose-Einstein Gas, 3. Black Body Radiation: the Photon Gas, 4. The Specific Heats of Solid: the Phonon Gas. Fermi—Dirac Statistic: 1. The Fermi-Dirac Statistic Distribution, 2. The Fermi-Dirac Gas, 3. The Electron Gas, 4. Pauli Paramagnetism, 5. Thermionic Emission. Temperature and Entropy: 1. The Statistical Concept of Temperature, 2. Entropy, 3. The Free Energy. The Thermodynamics Gases: 1. The weight Wmax for a classical perfect gas, 2. The Boltzmann Partition Function, 3. The evaluation of the Classical Partition Function, 4. Gibb’s Paradox, 5. The semi-classical perfect gas, 6. Component s of the Partition Function. Applications of Statistical Thermodynamics: 1. The paramagnetic gas, 2. The harmonic oscillator, 3. The diatomic molecule, 4. The two energy level system, 5. The disordered lattice. The Canonical Ensemble: 1. Ensembles, 2. The Constant Temperature Ensemble, 3. Thermodynamic Properties of the Partition Function.
Capaian Pembelajaran
Gasal 2022/2023
Kelas-Offr:
AM-AM
Deskripsi:
Introduction to Statistical Physics: 1. The Scope of Statistical Physics, 2. Description of the Assemblies – Phase Space, 3. The Average Properties of an Assembly, 4. Clasical and Quantum Assemblies. Maxwell—Boltzmann Statistics: 1. Distribution Over Energies, 2. Weights of Configurations, 3. The Most Probable Configuration, 4. The Sharpness of the Configuration Maximum, 5. The Multiplier , 6. The Multiplier , 7. The Maxwell—Boltzmann Distribution. Applications of Maxwell—Boltzmann Statistics: 1. Average Properties of Systems, 2. The Clasical Perfect Gas, 3. Mean and Most Probable Velocities, 4. The Doppler Broadening of Spectral Lines, 5. Equipartition of Energy, 6. The Specific Heats of Gases, 7. The Einstein Diffusion Equation. Bose-Einstein Statistics: 1. The Bose-Einstein Distribution, 2. The Bose-Einstein Gas, 3. Black Body Radiation: the Photon Gas, 4. The Specific Heats of Solid: the Phonon Gas. Fermi—Dirac Statistic: 1. The Fermi-Dirac Statistic Distribution, 2. The Fermi-Dirac Gas, 3. The Electron Gas, 4. Pauli Paramagnetism, 5. Thermionic Emission. Temperature and Entropy: 1. The Statistical Concept of Temperature, 2. Entropy, 3. The Free Energy. The Thermodynamics Gases: 1. The weight Wmax for a classical perfect gas, 2. The Boltzmann Partition Function, 3. The evaluation of the Classical Partition Function, 4. Gibb’s Paradox, 5. The semi-classical perfect gas, 6. Component s of the Partition Function. Applications of Statistical Thermodynamics: 1. The paramagnetic gas, 2. The harmonic oscillator, 3. The diatomic molecule, 4. The two energy level system, 5. The disordered lattice. The Canonical Ensemble: 1. Ensembles, 2. The Constant Temperature Ensemble, 3. Thermodynamic Properties of the Partition Function.
Capaian Pembelajaran
- Peserta menunjukkan penguasaan konsep dalam Introduction to Statistical Physics.
- Peserta menunjukkan penguasaan konsep Maxwell—Boltzmann Statistics, kemampuan menemukan dan menganalisis solusi bagi suatu system fisis standar, dan kemampuan mengambil keputusan secara tepat untuk menjawab permasalahan dari system fisis tersebut.
- Peserta menunjukkan penguasaan konsep Bose-Einstein Statistics, kemampuan menemukan dan menganalisis solusi bagi suatu system fisis standar, dan kemampuan mengambil keputusan secara tepat untuk menjawab permasalahan dari system fisis tersebut.
- Peserta menunjukkan penguasaan konsep Fermi—Dirac Statistic, kemampuan menemukan dan menganalisis solusi bagi suatu system fisis standar, dan kemampuan mengambil keputusan secara tepat untuk menjawab permasalahan dari system fisis tersebut.
- Peserta menunjukkan penguasaan konsep Temperature and Entropy, kemampuan menemukan dan menganalisis solusi bagi suatu system fisis standar, dan kemampuan mengambil keputusan secara tepat untuk menjawab permasalahan dari system fisis tersebut.
- Peserta menunjukkan penguasaan konsep The Thermodynamics Gases, kemampuan menemukan dan menganalisis solusi bagi suatu system fisis standar, dan kemampuan mengambil keputusan secara tepat untuk menjawab permasalahan dari system fisis tersebut.
- Peserta menunjukkan penguasaan konsep Statistical Thermodynamics, kemampuan menemukan dan menganalisis solusi bagi suatu system fisis standar, dan kemampuan mengambil keputusan secara tepat untuk menjawab permasalahan dari system fisis tersebut.
- J. Pointon, 1967, An Introduction to Statistical Physics for Students, Longman, London and New York
- Huang Kerson, Introduction to Statistical Physics
- Greiner W., Neise, Stocker, 1997, Thermodynamics and statistical mechanics
- William Geraint V. Rosser, An Introduction to Statistical Physics
- Landberg, Problem in Thermodynamics and Stastical Physics
- Pengajar: Hari Wisodo
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