- Absorption refrigerators
- Adiabatic compression in a diesel engine
- Air conditioner in real life
- Air conditioners
- Albite, jadeite and quartz phase diagram
- Aluminum silicate - stability of three crystal structures
- Aluminum silicate phase diagram
- Atmospheric convection
- Avogadro's number from thermal conductivity in an ideal gas
- Barometric equation: the exponential atmosphere
- Binomial coefficients and probability
- Black hole entropy
- Bulk modulus and the speed of sound
- Calcite and aragonite
- Calcium carbonate phase diagram
- Carnot cycle
- Carnot engine - a realistic version
- Chemical potential of a mixture of ideal gases
- Chemical potential of an ideal gas
- Chemical potential; application to the Einstein solid
- Clausius-Clapeyron relation; changing the freezing point of water
- Cloud formation
- Compression work
- Diamond-graphite phase boundary
- Diesel engines
- Diffusion equation
- Diffusion in an ideal gas; Fick's law
- Diffusion: a couple of examples
- Effusion: gas leaking through a small hole
- Einstein solid
- Einstein solid - numerical solution
- Einstein solid: analytic solution for heat capacity
- Einstein solids: multiplicity of large systems
- Energy of a system with quadratic degrees of freedom
- Enthalpy
- Enthalpy in chemical reactions
- Enthalpy in the Hampson-Linde cycle
- Enthalpy: a few examples
- Entropy
- Entropy and heat
- Entropy changes in macroscopic systems
- Entropy from erasing computer memory
- Entropy of a star
- Entropy of adiabatic compression
- Entropy of aluminum at low temperatures
- Entropy of an ideal gas; Sackur-Tetrode equation
- Entropy of diamond and graphite
- Entropy of distinguishable molecules
- Entropy of mixing
- Entropy of mixing in a small system
- Entropy of solar irradiance of the Earth
- Entropy of water and steam
- Entropy: a few examples
- Equipartition theorem: qualitative treatment
- Extensive and intensive quantities
- Geothermal energy loss due to heat conduction
- Gibbs and Helmholtz free energies; thermodynamic potentials
- Gibbs energy in batteries
- Gibbs free energy and chemical potential
- Gibbs free energy in chemical reactions
- Gibbs free energy of a mixture of two ideal gases
- Grand free energy
- Graphite and diamond
- Heat capacities at constant volume and pressure
- Heat capacities in terms of entropy
- Heat capacities using Maxwell relations
- Heat capacity and specific heat capacity
- Heat capacity of a single water molecule
- Heat capacity of pasta
- Heat engines
- Heat equation
- Heat pumps
- Heat, work and temperature
- Heating a frying pan's handle
- Helmholtz and Gibbs energies are minimum at equilibrium
- Helmholtz energy as a function of volume
- Helmholtz energy of a hydrogen atom
- Helmholtz free energy of a van der Waals fluid
- Hydrogen fuel cell at higher temperatures
- Ice-water heat engine
- Ideal gas law
- Ideal gas: relation of average speed of molecules to temperature
- Interacting Einstein solids
- Interacting Einstein solids: a few examples
- Interacting Einstein solids: rectangular peak in multiplicity graph
- Interacting Einstein solids: sharpness of the multiplicity function
- Internal combustion engine; the Otto cycle
- Isothermal and adiabatic compression of an ideal gas
- Isothermal and isentropic compressibilities
- Isothermal versus adiabatic expansion of an ideal gas bubble
- Laser cooling
- Latent heat
- Liquefying gases: the Hampson-Linde cycle
- Logarithms: a few properties
- Magnetic cooling
- Magnetic systems in thermodynamics
- Maxwell relations from thermodynamic identities
- Measuring heat capacity at constant volume
- Methane fuel cell
- Mixed systems: effect of interaction energy and the solubility gap
- Multiplicity of a 2-dim ideal gas
- Multiplicity of interacting ideal gases
- Muscle as a fuel cell
- Negative heat capacity in gravitational systems; estimating the Sun's temperature
- Ocean water as a heat engine
- Paramagnets & coin flips: peak and width of multiplicity function
- Phases of helium-3
- Phases of water - plots of Gibbs energy
- Power plants as heat engines
- Predicting heat capacity
- Pressure in terms of entropy; the thermodynamic identity
- PV diagrams: a diatomic ideal gas undergoes a rectangular cycle
- PV diagrams: a monatomic ideal gas follows a triangular cycle
- R values for still and convective air
- Random walks and diffusion
- Refrigerators
- Refrigerators in the real world
- Relative humidity and dew point
- Relative humidity: seeing your breath
- Rubber bands and entropy
- Steam engines in the real world
- Steam engines; the Rankine cycle
- Stirling engine
- Stirling's approximation for large factorials
- Super-efficient heat engines and refrigerators
- Surface tension and cloud formation
- Temperature defined from entropy
- Temperature of a black hole
- Temperature of an Einstein solid
- Thermal conductivity of an ideal gas
- Thermal conductivity of helium
- Thermal conductivity; R values
- Thermal equilibrium for entropy plots
- Thermal expansion of liquids and solids
- Thermodynamic identity for Gibbs & Helmholtz free energies
- Thermodynamic properties of a 2-dim ideal gas
- Thermodynamics of hiking
- Third law of thermodynamics; residual entropy
- Throttling: enthalpy versus entropy
- Two-state paramagnet as an Einstein solid
- Two-state paramagnet: an experiment with DPPH
- Two-state paramagnet: analytic solution
- Two-state paramagnet: entropy as a function of temperature
- Two-state paramagnet: numerical solution
- Two-state paramagnet: the Purcell & Pound experiment with lithium
- Van der Waals equation of state
- Van der Waals equation of state: Maxwell construction
- Van der Waals fluid at the critical point
- Vapour pressure
- Vapour pressure equation
- Virial expansion for a gas
- Viscosity of an ideal gas
- Wet adiabatic lapse rate
- Zeroth law of thermodynamics