BSC Physics Notes

Define thermal radiation Notes Define thermal radiation Notes:-Thermodynamics Relationships: Thermodynamic variables: extensive and intensive, Maxwell’s general relationships, application to Joule-Thomson cooling and adiabatic cooling in a general system,Vander Waal’s gas, Clausius-Clapeyron heat equation. Thermodynamic potentials and equilibrium of thermodynamical systems, relation with thermodynamical variables. Cooling due to adiabatic demagnetization. Production and measurement of very low […]

vapourization temperature T Physcis Notes vapourization temperature T Physcis Notes:-The Laws of Thermodynamics: The Zeroth law, various indicator diagrams, work done by and on the system, first law of thermodynamics. internal energy as a state function and other applications. Reversible and irreversible changes. Carnot cycle and its efficiency, Carnot theorem and the second law of

Deduce Clausius Clapeyron Notes Deduce Clausius Clapeyron Notes:- The Laws of Thermodynamics: The Zeroth law, various indicator diagrams, work done by and on the system, first law of thermodynamics. internal energy as a state function and other applications. Reversible and irreversible changes. Carnot cycle and its efficiency, Carnot theorem and the second law of thermodynamics.

BSC Physics Define Entropy Notes BSC Physics Define Entropy Notes:- The Laws of Thermodynamics: The Zeroth law, various indicator diagrams, work is done by and on the system, first law of thermodynamics. internal energy as a state function and other applications. Reversible and irreversible changes. Carnot cycle and its efficiency, Carnot theorem, and the second

State Prove Carnot’s Theorem Notes State Prove Carnot’s Theorem Notes:-Thermodynamics Relationships: Thermodynamic variables: extensive and intensive, Maxwell’s general relationships, application to Joule-Thomson cooling and adiabatic cooling in a general system,vander Waal’s gas, Clausius-Clapeyron heat equation. Thermodynamic potentials and equilibrium of thermodynamical systems, relation with thermodynamical variables. Cooling due to adiabatic demagnetization. Production and measurement of

Describe Working Carnot’s Reversible heat Engine Describe Working Carnot’s Reversible heat Engine:-Thermodynamics Relationships: Thermodynamic variables: extensive and intensive, Maxwell’s general relationships, application to Joule-Thomson cooling and adiabatic cooling in a general system,vander Waal’s gas, Clausius-Clapeyron heat equation. Thermodynamic potentials and equilibrium of thermodynamical systems, relation with thermodynamical variables. Cooling due to adiabatic demagnetization. Production and

Thermodynamic Proof Mayer’s Relation Thermodynamic Proof Mayer’s Relation:-Thermodynamics Relationships: Thermodynamic variables: extensive and intensive, Maxwell’s general relationships, application to Joule-Thomson cooling and adiabatic cooling in a general system,vander Waal’s gas, Clausius-Clapeyron heat equation. Thermodynamic potentials and equilibrium of thermodynamical systems, relation with thermodynamical variables. Cooling due to adiabatic demagnetization. Production and measurement of very low

BSc Notes Physical Significance BSc Notes Physical Significance:-The Laws of Thermodynamics: The Zeroth law, various indicator diagrams, work done by and on the system, first law of thermodynamics. internal energy as a state function and other applications. Reversible and irreversible changes. Carnot cycle and its efficiency, Carnot theorem and the second law of thermodynamics. Different

What are the Transport Phenomena Gases What are the Transport Phenomena Gases:-The Laws of Thermodynamics: The Zeroth law, various indicator diagrams, work done by and on the system, first law of thermodynamics. internal energy as a state function and other applications. Reversible and irreversible changes. Carnot cycle and its efficiency, Carnot theorem and the second

Square Root of Absolute Temperature Square Root of Absolute Temperature:- Liquefaction of Gases: Boyle temperature and inversion temperature. Principle of regenerative cooling and of cascade cooling, liquefaction of hydrogen and helium. Refrigeration cycles, meaning of efficiency. Transport phenomena in Gases: Molecular collision, mean free path and collision cross-sections. Estimates of molecular diameter and mean free