Akademik Dersler - İçerik

apply the three laws of thermodynamcis to closed systems.
Applies the basic integration and differentiation rules to thermodynamic problems.
Calculates the work done by the sytem or the work done on the system.
Calculates the heat absorbed by the sytem or the the heat withfrawn from the system.
Analyses the three laws of thermodynamics.
Designs reversible processes.
Calculates changes in enthalpy, entropy and Gibbs free energy as a function of temperature and pressure.
Generates energy functions (internal energy, enthalpy, Helmholtz free energy and Gibbs free energy) as a function of any two independent variables (temperature, pressure, volume and entropy).
Applies the auxilliary functions (coeffcient relations, Maxwell relations, Gibbs-Helmholtz equation) to thermodynamic problems.
analyse equilibrium conditions between solid-liquid, gas-liquid and gas-solid phases in one-component systems.
Calculates equilibrium conditions between solid-liquid phases via the Clapeyron equation.
Calculates equilibrium conditions between gas-condensed phases via the Clausius- Clapeyron equation.
Draws one-component phase diagrams.
apply Raoult's and Henry's laws, and regular solution rules to open systems.
Applies basic integral and differential rules to solution thermodynamics problems.
Applies partial differential rules to solution thermodynamics problems.
Expresses formation of a solution from its pure components.
Calculates changes in volume, enthalpy,entropy and Gibbs free energy of formation of Raoltian solutions.
Applies Henry's law to dilute solutions.
Analyses regular solution behaviourbyintroducing excess properties.
analyse the relationship between Gibbs free energy, thermodynamic activity and phase diagrams.
Derives equations expressing equilibirium conditions in solutions.
Derives criteria for phase stability in regular solutions.
For a given standard state, drives equations expressing change in Gibbs free energy of mixing of liquid and solid solutions as a function of composition, and plots diagram showing these variations.
For a given standard state, drives equations expressing change inactivity of components as a function of composition, and plots diagram showing these variations.
For a given temperature and binary phase diagram, schematically makes a plot showing variation of both Gibbs free energy of mixing and activity as a function of composition.
Derives, in systems showing Raoultian behaviour, simple binary phase diagrams from given thermodynamic data.