Lectures related to Heat capacity ratio

Heat Capacity and Degrees of Freedom in Thermodynamics

Covers heat capacity, degrees of freedom, and their implications in thermodynamics.

Explores energy equipartition in ideal gases, heat capacity, and thermodynamic transformations.

Explores ideal gas laws, entropy, internal energy, and specific heat capacities, emphasizing Mayer's relations and adiabatic reversible processes.

Specific Heat Capacity at Constant Volume

Explains the quantification of temperature changes and heat exchange in gases, focusing on specific heat capacity at constant volume.

Internal Energy and Specific Heat

Covers the calculation of internal energy and specific heat for gases, electrons, phonons, and photons.

Specific Heat at Constant Pressure

Explores specific heat at constant pressure, enthalpy, ideal gases, adiabatic exponent, and solid-specific heat.

Thermophysical Properties: Models and Applications

Explores classical and quantum models to understand heat capacity in solids and discusses the relation between heat capacities at constant volume and pressure.

States of Matter: Compressibility and Thermal Expansion

Explores compressibility, thermal expansion, and specific heat capacity of materials.

Thermodynamics: Internal Energy and Heat Capacity

Covers internal energy, heat capacity, and their roles in thermodynamics.

Thermo1: Evaluating Properties

Explores evaluating properties of substances, including liquids, solids, ideal gases, and real gases, emphasizing specific heat and enthalpy.

First Law of Thermodynamics: Energy Conservation

Explores the conservation of energy in thermodynamic systems through heat and work interactions, introducing internal energy, enthalpy, and heat capacity.

Vibrations in Solids: Harmonic Oscillators and Phonons

Explores vibrations in solids, including harmonic oscillators, phonons, and the Einstein model of heat capacity.

Thermophysical Properties: Expansion, Moduli, and Vacancies

Covers thermal expansion, Grüneisen parameter, and thermal vacancies in metals, exploring their interrelations and implications on material properties.

Thermodynamics and Energetics I

Explores fundamental thermodynamics concepts, laws, energy transfer, and system analysis.

Efficient Computation of Heat Capacity

Covers the efficient computation of heat capacity in metal organic frameworks using quantum classical methods and explores advanced PIMD techniques beyond benchmarks.

Anharmonic Effects in Solids

Explores anharmonic effects in solids, including thermal expansion, conductivity, and phonon scattering.

Specific Heat of Solids

Explores the specific heat of solids at high temperatures and its application to water through experimental evidence and calculations.

Thermodynamic Functions and Calorimetric Coefficients

Discusses thermodynamic functions, calorimetric coefficients, and their relationships in physical systems.

Specific Heat and Latent Heat in Matter States

Explores heat exchange, specific heat, and latent heat in different materials and phase transitions.

Flow PM Evaluation Table

Presents a table for evaluating the Prandtl-Meyer function based on Mach number.