Kode Mata KuliahAS2102 / 3 SKS
Penyelenggara103 - Astronomy / FMIPA
KategoriLecture
Bahasa IndonesiaEnglish
Nama Mata KuliahAstrofisika TermalAstrophysical Thermodynamics
Bahan Kajian
  1. Konsep temperatur, sistem termodinamika
  2. Kerja, panas, hukum termodinamika I
  3. Gas ideal, teori kinetik gas
  4. Hukum termodinamika II
  5. Proses reversibel/irreversibel, entropi
  6. Pendekan mikroskopik, pengantar ke mekanika statistik
  1. Temperature concept, thermodynamic systems
  2. Work, Heat, Law of Thermodynamics I
  3. Ideal Gas, kinetic theory of gas
  4. Law of Thermodynamics II
  5. reversible/irreversible processes, entropy
  6. microscopic, introduction to statistical mechanics
Capaian Pembelajaran Mata Kuliah (CPMK)
  1. Mampu mendeskripsikan kesetimbangan termal, hukum termodinamika ke-0, dan konsep temperatur. Mampu menjelaskan termometer gas, dan menghitung temperatur gas ideal dari suatu data eksperimen.
  2. Mampu menjelaskan kesetimbangan termodinamik, dan persamaan keadaan dari beberapa sistem. Mampu menunjukkan teorema kalkulus diferensial parsial yang sering digunakan dalam termodinamika.
  3. Mampu menjelaskan konsep kerja (work) dalam sistem-sistem termodinamik; mampu menghitung kerja sistem hidrostatik yang berubah keadaannya melalui proses kuasi-statik.
  4. Mampu menjelaskan kerja adiabatik dan keberadaan fungsi energi dalam. Mampu menjelaskan hukum termodinamika pertama, konsep panas (heat), dan berbagai mekanisme transfer panas.
  5. Mampu menjelaskan definisi suatu gas ideal dan menunjukkan hubungan yang berlaku antar koordinat termodinamik yang relevan dalam gas ideal. Mampu menjelaskan teori kinetik gas ideal.
  6. Mampu menjelaskan konversi dari kerja menjadi panas, dan sebaliknya; menunjukkan beberapa mesin panas; menjelaskan pernyataan hukum termodinamika kedua (kasus mesin panas dan referigerator); konsep reversibilitas dan irreversibilitas; menjelaskan pentingnya siklus Carnot dalam analisa termodinamik.
  7. Mampu menjelaskan koordinat termodinamik entropi dan kaitannya dengan proses reversibel/irreversibel; menjelaskan prinsip pertambahan entropi dan kaitannya dengan ketakteraturan.
  8. Mampu menunjukkan beberapa teorema dan metode matematik yang bermanfaat dalam studi termodinamika
  9. Mampu menjelaskan perbedaan pendekatan dalam termodinamika (klasik) dan mekanika statistik; mampu menunjukkan prinsip-prinsip dasar dalam mekanika statistik; menjelaskan bagaimana relasi-relasi dalam termodinamika (klasik) diekspresikan dalam mekanika statistik.
  1. Able to describe thermal equilibrium, the law of thermodynamics 0, and the concept of temperature, to explain a gas thermometer, and to calculate the ideal gas temperature from experimental data.
  2. Able to explain thermodynamic equilibrium, and state equations of several systems, and to demonstrate the partial differential calculus theorem commonly used in thermodynamics.
  3. Able to explain the concept of work in thermodynamic systems; able to calculate the work of hydrostatic systems that change their state through quasi-static processes.
  4. Able to explain the adiabatic work and the existence of internal energy functions, the first law of thermodynamics, the concept of heat, and the various heat transfer mechanisms.
  5. Able to explain the definition of an ideal gas and show the relevant relationships between the relevant thermodynamic coordinates in the ideal gas.
  6. Able to explain the conversion of work into heat, and vice versa; show some heat engines; explain the statement of the second law of thermodynamics (the case of thermal engines and refrigerators); the concepts of reversibility and irreversibility; explain the importance of Carnot's cycles in thermodynamic analysis.
  7. Able to explain the thermodynamic coordinates of the entropy and its relationship with the reversible/irreversible process; explain the principle of the addition of the entropium and its relation to the irregularity.
  8. Able to show some mathematical theorems and methods useful in the study of thermodynamics
  9. Able to explain the differences of approaches in thermodynamics (classical) and statistical mechanics; able to demonstrate the basic principles in statistical physics; explaining how relationships in thermodynamics (classic) are expressed in the mechanics of statistics.
Metode PembelajaranKombinasi antara ceramah, diskusi, dan tugas membacaCombination of lectures, discussions, and reading tasks
Modalitas PembelajaranBauran sinkron dan asinkronSynchron and asynchronous
Jenis NilaiABCDE
Metode PenilaianKuis, tugas, UTS, UASQuiz, task, mid-semester exam, final semester exam
Catatan Tambahan