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Complete analytical index all topics covered in the course

Activated complex - Slide 19.08 - Video timestamp
Activated complex - Slide 20.02 - Video timestamp
Activated complex - Slide 20.08 - Video timestamp
Active matter - Slide 25.18 - Video timestamp
Activities and activity coefficients - Slide 16.12 - Video timestamp
Adiabatic availability definition - Slide 02.23 - Video timestamp
Adiabatic availability graphical representation - Slide 03.21 - Video timestamp
Adiabatic availability graphical representation - Slide 04.03 - Video timestamp
Adiabatic availability of mixing ideal gases - Slide 12.14 - Video timestamp
Adiabatic availability of mixing ideal gases - Slide 12.15 - Video timestamp
Adiabatic availability of mixing ideal gases - Slide 13.08 - Video timestamp
Adiabatic availability of mixing ideal gases - Slide 15.04 - Video timestamp
Adiabatic flame temperature in a closed combustion chamber - Slide 18.25 - Video timestamp
Adiabatic flame temperature in a closed combustion chamber - Slide 18.27 - Video timestamp
Adiabatic flame temperature in a closed combustion chamber - Slide 19.20 - Video timestamp
Adiabatic flame temperature in an open burner - Slide 18.22 - Video timestamp
Adiabatic process definition - Slide 05.04 - Video timestamp
Adiabatic process versus weight process - Slide 05.04 - Video timestamp
Advanced Thermodynamics, 2.43 Course introduction - Slide 01.01 - Video timestamp
Advanced Thermodynamics, 2.43 Course objectives, Part 1 - Slide 01.05 - Video timestamp
Advanced Thermodynamics, 2.43 Course objectives, Part 2 - Slide 01.06 - Video timestamp
Advanced Thermodynamics, 2.43 Course objectives, Part 3 - Slide 01.07 - Video timestamp
Advanced Thermodynamics, 2.43 Grading policy - Slide 01.08 - Video timestamp
Affinity and degree of disequilibrium - Slide 20.13 - Video timestamp
Affinity and direction of reaction - Slide 20.14 - Video timestamp
Affinity and reaction rates - Slide 21.03 - Video timestamp
Affinity and reaction rates - Slide 21.05 - Video timestamp
Affinity De Donder - Slide 19.11 - Video timestamp
Affinity entropic versus energetic - Slide 20.04 - Video timestamp
Affinity of a reaction - Slide 19.12 - Video timestamp
Allocation methods in heat and power cogeneration - Slide 10.25 - Video timestamp
Allocation methods in heat and power cogeneration - Slide 11.16 - Video timestamp
Allocation methods in hybrid solar-fossil power production - Slide 10.38 - Video timestamp
Allocation methods in hybrid solar-fossil power production - Slide 11.23 - Video timestamp
Amagat law of additive volumes - Slide 12.12 - Video timestamp
Anand, Lallit - Slide 22.04 - Video timestamp
Anisotropic Fourier conduction - Slide 21.17 - Video timestamp
Anisotropic Fourier conduction - Slide 21.19 - Video timestamp
Antanovskii, Leonid K. - Slide 25.24 - Video timestamp
Arrhenius law and activation barrier - Slide 20.10 - Video timestamp
Availability function and related stability conditions - Slide 06.22 - Video timestamp
Availability function general concept - Slide 06.20 - Video timestamp
Availability function graphical representation - Slide 06.21 - Video timestamp
Availability function graphical representation - Slide 07.13 - Video timestamp
Availability function w.r.to a fixed V and n reservoir - Slide 06.19 - Video timestamp
Availability function w.r.to a fixed V and n reservoir - Slide 07.12 - Video timestamp
Availability function w.r.to a fixed V and variable n_i reservoir - Slide 07.19 - Video timestamp
Availability function w.r.to a variable V and n reservoir - Slide 07.21 - Video timestamp
Availability function w.r.to a variable V and fixed n reservoir - Slide 07.17 - Video timestamp
Available energy and its related availability function - Slide 06.20 - Video timestamp
Available energy and its related availability function - Slide 07.12 - Video timestamp
Available energy graphical representation - Slide 03.25 - Video timestamp
Available energy graphical representation - Slide 04.05 - Video timestamp
Available energy graphical representation - Slide 06.21 - Video timestamp
Available energy graphical representation - Slide 07.13 - Video timestamp
Available energy w.r.to a fixed V and n reservoir - Slide 02.33 - Video timestamp
Available energy w.r.to a fixed V and n reservoir - Slide 06.20 - Video timestamp
Available energy w.r.to a fixed V and n reservoir - Slide 07.12 - Video timestamp
Available energy w.r.to a fixed V and variable n_i reservoir - Slide 07.19 - Video timestamp
Available energy w.r.to a variable V and n reservoir - Slide 07.21 - Video timestamp
Available energy w.r.to a variable V and fixed n reservoir - Slide 06.19 - Video timestamp
Available energy w.r.to a variable V and fixed n reservoir - Slide 07.17 - Video timestamp
Average kinetic energy versus temperature - Slide 03.18 - Video timestamp
Avogadro's number - Slide 13.11 - Video timestamp
Azeotrope - Slide 16.15 - Video timestamp
Balance equations for a continuum of a generic extensive property - Slide 22.06 - Video timestamp
Balance equations for a continuum of a generic extensive property - Slide 22.09 - Video timestamp
Balance equations for a continuum of the main extensive properties - Slide 23.04 - Video timestamp
Balance equations for a continuum one-dimensional heat and mass transfer - Slide 22.05 - Video timestamp
Balance equations for a continuum Reynolds theorem - Slide 22.09 - Video timestamp
Balancing the stoichiometric coefficients - Slide 18.09 - Video timestamp
Baricentric velocity - Slide 22.08 - Video timestamp
Baricentric velocity - Slide 22.11 - Video timestamp
Bedeaux, Dick - Slide 22.12 - Video timestamp
Bedeaux, Dick - Slide 23.15 - Video timestamp
Bedeaux, Dick - Slide 25.22 - Video timestamp
Bejan, Adrian - Slide 23.27 - Video timestamp
Bejan, Adrian - Slide 23.35 - Video timestamp
Binodal miscibility curve - Slide 17.07 - Video timestamp
Blue energy, osmotic power - Slide 14.11 - Video timestamp
Boiling point elevation - Slide 16.06 - Video timestamp
Boltzmann constant - Slide 13.11 - Video timestamp
Boltzmann constant - Slide 13.13 - Video timestamp
Boltzmann, Ludwig - Slide 01.03 - Video timestamp
Brownian motion - Slide 25.12 - Video timestamp
Bubble chamber - Slide 15.20 - Video timestamp
Bubble line - Slide 16.04 - Video timestamp
Bubble line - Slide 16.15 - Video timestamp
Bubble line - Slide 17.03 - Video timestamp
Bulk viscosity - Slide 23.14 - Video timestamp
Bulk-flow and local equilibrium - Slide 23.03 - Video timestamp
Bulk-flow and local equilibrium - Slide 23.06 - Video timestamp
Bulk-flow and partial energy - Slide 24.04 - Video timestamp
Bulk-flow interaction - Slide 08.17 - Video timestamp
Bulk-flow state - Slide 08.17 - Video timestamp
Cahn-Hilliard square-gradient model - Slide 25.24 - Video timestamp
Callen, Herbert B. - Slide 02.42 - Video timestamp
Canonical distribution of probabilities - Slide 13.13 - Video timestamp
Canonical distribution of probabilities - Slide 13.14 - Video timestamp
Caratheodory, Constantin - Slide 01.03 - Video timestamp
Carnot coefficient - Slide 05.06 - Video timestamp
Carnot coefficient - Slide 05.13 - Video timestamp
Carnot, Nicolas Leonard Sadi, 200th anniversary of the birth of Thermodynamics - Slide 01.02 - Video timestamp
Carnot, Nicolas Leonard Sadi, 200th anniversary of the birth of Thermodynamics - Slide 01.03 - Video timestamp
Carnot, Nicolas Leonard Sadi, 200th anniversary of the birth of Thermodynamics - Slide 25.26 - Video timestamp
Cattaneo-Vernotte heat conduction equation - Slide 21.20 - Video timestamp
Centrifuges for uranium enrichment - Slide 15.12 - Video timestamp
Characteristic SES functions - Slide 06.13 - Video timestamp
Characteristic SES functions - Slide 06.17 - Video timestamp
Characteristic SES functions - Slide 07.03 - Video timestamp
Charge densities in terms of mole and mass fractions and molar and mass densities - Slide 22.11 - Video timestamp
Charge density - Slide 23.08 - Video timestamp
Charge flux definition in �Heat&diffusion� interactions - Slide 22.24 - Video timestamp
Charge flux definition in �Heat&diffusion� interactions - Slide 24.03 - Video timestamp
Chemical equilibrium complete - Slide 19.23 - Video timestamp
Chemical equilibrium Gordon-McBride NASA computer code - Slide 19.23 - Video timestamp
Chemical equilibrium necessary condition - Slide 19.16 - Video timestamp
Chemical equilibrium necessary condition - Slide 19.22 - Video timestamp
Chemical equilibrium pH and pOH of pure water - Slide 20.06 - Video timestamp
Chemical equilibrium stable equilibrium states - Slide 19.11 - Video timestamp
Chemical kinetics - Slide 19.08 - Video timestamp
Chemical kinetics - Slide 20.07 - Video timestamp
Chemical kinetics vs heat conduction - Slide 22.03 - Video timestamp
Chemical potential and multicomponent equilibria - Slide 11.29 - Video timestamp
Chemical potential as functions of T and p - Slide 05.25 - Video timestamp
Chemical potential definition - Slide 02.42 - Video timestamp
Chemical potential definition - Slide 03.14 - Video timestamp
Chemical potential equality at mutual equilibrium - Slide 03.15 - Video timestamp
Chemical potential for ideal gas mixtures - Slide 12.11 - Video timestamp
Chemical potential for ideal solutions - Slide 14.04 - Video timestamp
Chemical potential ideal and excess - Slide 16.09 - Video timestamp
Chemical potential van'f Hoff relation - Slide 14.05 - Video timestamp
Chemical reaction direction of spontaneous process - Slide 18.12 - Video timestamp
Chemical reaction exergy - Slide 18.16 - Video timestamp
Chemical reaction maximum work obtainable - Slide 18.16 - Video timestamp
Chemical reaction minimum work required - Slide 18.16 - Video timestamp
Clausius inequalities and irreversibilities - Slide 05.11 - Video timestamp
Clausius inequalities generalized proof - Slide 22.22 - Video timestamp
Clausius inequalities graphical proof - Slide 05.02 - Video timestamp
Clausius inequalities proof - Slide 04.23 - Video timestamp
Clausius inequalities proof - Slide 05.02 - Video timestamp
Clausius inequalities proof - Slide 22.20 - Video timestamp
Clausius, Rudolf - Slide 01.03 - Video timestamp
Clausius-Clapeyron relation - Slide 09.24 - Video timestamp
Clausius-Clapeyron relation - Slide 16.06 - Video timestamp
Climate4you.com website - Slide 15.10 - Video timestamp
Cloud chamber - Slide 15.20 - Video timestamp
CO2 concentration at sea level - Slide 15.09 - Video timestamp
CO2 concentration with elevation - Slide 15.09 - Video timestamp
CO2 removal from atospheric air, minimum work required - Slide 14.14 - Video timestamp
CO2 stored in bottom layers of oceans - Slide 15.10 - Video timestamp
Cogeneration - Slide 08.35 - Video timestamp
Cogeneration - Slide 10.25 - Video timestamp
Cogeneration - Slide 11.09 - Video timestamp
Cogeneration - Slide 11.10 - Video timestamp
Cogeneration - Slide 11.10 - Video timestamp
Coherent light - Slide 20.21 - Video timestamp
Coleman-Noll procedure - Slide 22.04 - Video timestamp
Collisions in reacting systems - Slide 19.07 - Video timestamp
Collisions in reacting systems - Slide 20.09 - Video timestamp
Combined heat and power (CHP) - Slide 10.25 - Video timestamp
Combined heat and power (CHP) - Slide 11.10 - Video timestamp
Compatible compositions, meaning - Slide 19.04 - Video timestamp
Compatible values of amounts of constituents - Slide 19.04 - Video timestamp
Complete chemical equilibrium - Slide 19.23 - Video timestamp
Compressibility factor - Slide 15.17 - Video timestamp
Constructal law of design and evolution in Nature - Slide 23.35 - Video timestamp
Continuum approximation - Slide 22.14 - Video timestamp
Continuum approximation - Slide 25.17 - Video timestamp
Convective fluxes - Slide 22.08 - Video timestamp
Convective fluxes - Slide 22.10 - Video timestamp
Convective fluxes - Slide 23.02 - Video timestamp
Cornish engine - Slide 10.19 - Video timestamp
Covalent bond strength versus Van der Waals forces - Slide 17.17 - Video timestamp
Covalent bond strength versus Van der Waals forces - Slide 18.07 - Video timestamp
Cross effects between vectorial forces and fluxes - Slide 25.05 - Video timestamp
Cross effects summary and Curie principle - Slide 23.15 - Video timestamp
Cross effects summary and Curie principle - Slide 24.02 - Video timestamp
Cross effects summary and Curie principle - Slide 25.02 - Video timestamp
Cross effects thermo-diffusive - Slide 25.10 - Video timestamp
Cross effects thermo-electric - Slide 24.07 - Video timestamp
Cross effects thermo-electric - Slide 25.06 - Video timestamp
Cross effects thermo-osmosis - Slide 25.08 - Video timestamp
Cross effects thermophoresis - Slide 25.13 - Video timestamp
Curie symmetry principle - Slide 23.15 - Video timestamp
Curie, Pierre - Slide 23.15 - Video timestamp
Curie, Pierre - Slide 24.02 - Video timestamp
Current density and diffusive flux of charge - Slide 23.08 - Video timestamp
Cyclic relation - Slide 07.09 - Video timestamp
Dalton law of additive partial pressures - Slide 12.10 - Video timestamp
Darcy law of permeability - Slide 25.09 - Video timestamp
De Donder affinity, see also Affinity - Slide 19.11 - Video timestamp
De Groot, Sybren Ruurds - Slide 01.03 - Video timestamp
De Groot, Sybren Ruurds - Slide 22.23 - Video timestamp
Degree of disequilibrium in chemical kinetics - Slide 20.13 - Video timestamp
Degree of disequilibrium in chemical kinetics - Slide 20.18 - Video timestamp
Degree of disequilibrium in entropy production density - Slide 23.07 - Video timestamp
Degree of disequilibrium in local near equilibrium - Slide 24.06 - Video timestamp
Degree of disequilibrium in steepest entropy ascent - Slide 23.31 - Video timestamp
Desalination of seawater - Slide 14.10 - Video timestamp
Detailed balance principle - Slide 20.13 - Video timestamp
Dew line - Slide 16.04 - Video timestamp
Dew line - Slide 16.15 - Video timestamp
Dew line - Slide 17.03 - Video timestamp
Dewar, Roderick - Slide 23.27 - Video timestamp
Diffuse interface modeling of spinodal decomposition - Slide 15.21 - Video timestamp
Diffuse-interface model - Slide 23.15 - Video timestamp
Diffuse-interface model - Slide 25.24 - Video timestamp
Diffusion Darcy's law - Slide 25.09 - Video timestamp
Diffusion Fick's law - Slide 23.15 - Video timestamp
Diffusion Fick's law - Slide 24.02 - Video timestamp
Diffusion Fick's law - Slide 25.12 - Video timestamp
Diffusion Maxwell-Stefan law - Slide 25.12 - Video timestamp
Diffusion self-diffusion - Slide 25.12 - Video timestamp
Diffusion thermophoresis - Slide 25.14 - Video timestamp
Diffusive fluxes - Slide 22.08 - Video timestamp
Diffusive fluxes - Slide 22.10 - Video timestamp
Diffusive fluxes - Slide 23.02 - Video timestamp
Diffusive fluxes - Slide 24.04 - Video timestamp
Diffusive fluxes - Slide 25.04 - Video timestamp
Directional pressured for a single particle in a box - Slide 13.16 - Video timestamp
Dissipation function - Slide 23.07 - Video timestamp
Dissipation metric in nonequilibrium dynamics - Slide 23.19 - Video timestamp
Distillation - Slide 16.05 - Video timestamp
District heating in Brescia - Slide 08.35 - Video timestamp
Divers' decompression sickness (the bends) - Slide 17.05 - Video timestamp
Dufour effect - Slide 23.15 - Video timestamp
Dufour effect - Slide 24.02 - Video timestamp
Dufour effect - Slide 25.15 - Video timestamp
Duhem, Pierre - Slide 01.03 - Video timestamp
Duhem-Margules relation - Slide 11.37 - Video timestamp
Duhem-Margules relation - Slide 16.09 - Video timestamp
Efficiency in the production of heating - Slide 10.13 - Video timestamp
Efficiency in the production of heating - Slide 10.25 - Video timestamp
Efficiency in the production of heating - Slide 11.08 - Video timestamp
Efficiency in the production of heating - Slide 11.15 - Video timestamp
Efficiency in the production of heating - Slide 11.17 - Video timestamp
Einstein, Albert - Slide 01.03 - Video timestamp
Electrochemical potential - Slide 14.17 - Video timestamp
Electrochemical potential - Slide 15.13 - Video timestamp
Electrochemical systems - Slide 25.21 - Video timestamp
Electromagnetic radiation carries energy and entropy - Slide 24.05 - Video timestamp
Energy performance a residential building - Slide 10.25 - Video timestamp
Energy vs entropy diagram adiabatic availability - Slide 03.21 - Video timestamp
Energy vs entropy diagram adiabatic availability - Slide 04.03 - Video timestamp
Energy vs entropy diagram adiabatic flame temperature - Slide 18.27 - Video timestamp
Energy vs entropy diagram available energy - Slide 03.25 - Video timestamp
Energy vs entropy diagram available energy - Slide 04.05 - Video timestamp
Energy vs entropy diagram definition - Slide 03.16 - Video timestamp
Energy vs entropy diagram definition - Slide 04.02 - Video timestamp
Energy vs entropy diagram energy, entropy, and exergy of combustion - Slide 18.27 - Video timestamp
Energy vs entropy diagram enthalpy and entropy of reaction - Slide 18.06 - Video timestamp
Energy vs entropy diagram for a seven level quantum system - Slide 13.14 - Video timestamp
Energy vs entropy diagram graphical proof of Clausius inequalities - Slide 04.28 - Video timestamp
Energy vs entropy diagram graphical proof of Clausius inequalities - Slide 04.29 - Video timestamp
Energy vs entropy diagram graphical proof of Clausius inequalities - Slide 05.02 - Video timestamp
Energy vs entropy diagram negative temperatures - Slide 03.19 - Video timestamp
Energy vs entropy diagram negative temperatures - Slide 13.14 - Video timestamp
Energy vs entropy diagram states of a thermal reservoir - Slide 03.23 - Video timestamp
Energy vs entropy diagram states of a thermal reservoir - Slide 04.04 - Video timestamp
Energy additivity - Slide 01.19 - Video timestamp
Energy and the first law of Thermodynamics - Slide 01.18 - Video timestamp
Energy and the first law of Thermodynamics - Slide 02.11 - Video timestamp
Energy balance equation - Slide 01.21 - Video timestamp
Energy balance equation - Slide 02.12 - Video timestamp
Energy balance equation - Slide 03.03 - Video timestamp
Energy balance equation - Slide 08.26 - Video timestamp
Energy balance equation - Slide 17.13 - Video timestamp
Energy balance equation - Slide 18.03 - Video timestamp
Energy conservation - Slide 01.19 - Video timestamp
Energy definition - Slide 01.18 - Video timestamp
Energy definition - Slide 02.11 - Video timestamp
Energy definition - Slide 03.02 - Video timestamp
Energy exchangeability via interactions - Slide 01.20 - Video timestamp
Energy flux carried by electromagnetic radiation - Slide 24.05 - Video timestamp
Energy notation for exchanges between systems - Slide 01.21 - Video timestamp
Energy-entropy-volume diagram for water - Slide 09.27 - Video timestamp
Enthalpy definition - Slide 05.21 - Video timestamp
Enthalpy definition - Slide 06.14 - Video timestamp
Enthalpy in bulk-flow interaction - Slide 08.21 - Video timestamp
Enthalpy of isothermobaric mixing - Slide 06.14 - Video timestamp
Enthalpy of isothermobaric mixing - Slide 16.09 - Video timestamp
Enthapy of formation vs bond energy - Slide 17.16 - Video timestamp
Enthapy of formation vs bond energy - Slide 18.06 - Video timestamp
Enthapy of formation vs bond energy - Slide 19.11 - Video timestamp
Entropy balance in fluid mechanics - Slide 23.04 - Video timestamp
Entropy production density force-flux shorthand notation - Slide 23.11 - Video timestamp
Entropy production density general expression for a continuum - Slide 23.06 - Video timestamp
Entropy production density general expression in terms of heat flux - Slide 23.07 - Video timestamp
Entropy production density general expression in terms of heat flux and current density - Slide 23.08 - Video timestamp
Entropy production density in steady-state heat transfer - Slide 21.15 - Video timestamp
Entropy production density in steepest entropy ascent - Slide 23.31 - Video timestamp
Entropy production density in terms of relative diffusive fluxes and forces - Slide 24.06 - Video timestamp
Entropy production density in terms of relative diffusive fluxes and forces - Slide 25.04 - Video timestamp
Entropy additivity - Slide 02.35 - Video timestamp
Entropy balance equation - Slide 02.38 - Video timestamp
Entropy balance equation - Slide 03.09 - Video timestamp
Entropy balance equation - Slide 08.26 - Video timestamp
Entropy balance equation - Slide 17.13 - Video timestamp
Entropy definition - Slide 02.32 - Video timestamp
Entropy definition - Slide 03.06 - Video timestamp
Entropy engineering meaning - Slide 02.34 - Video timestamp
Entropy engineering meaning - Slide 03.07 - Video timestamp
Entropy exchangeability via interactions - Slide 02.37 - Video timestamp
Entropy flux carried by electromagnetic radiation - Slide 24.05 - Video timestamp
Entropy generated in mixing ideal gases - Slide 12.13 - Video timestamp
Entropy generated in mixing ideal gases - Slide 13.07 - Video timestamp
Entropy generated in mixing ideal gases - Slide 15.03 - Video timestamp
Entropy in terms of probabilities - Slide 13.12 - Video timestamp
Entropy in terms of quantum probabilities - Slide 13.13 - Video timestamp
Entropy in terms of quantum probabilities - Slide 13.14 - Video timestamp
Entropy of isothermobaric mixing - Slide 12.05 - Video timestamp
Entropy of isothermobaric mixing - Slide 16.09 - Video timestamp
Entropy of radiation - Slide 10.43 - Video timestamp
Entropy of radiation - Slide 24.05 - Video timestamp
Entropy of solar radiation - Slide 24.05 - Video timestamp
Entropy of spontaneus mixing of ideal gases - Slide 12.13 - Video timestamp
Entropy of spontaneus mixing of ideal gases - Slide 13.07 - Video timestamp
Entropy of spontaneus mixing of ideal gases - Slide 13.11 - Video timestamp
Entropy principle of non-decrease in a weight process - Slide 02.35 - Video timestamp
Equation of state - Slide 05.23 - Video timestamp
Equilibrium constant dependence on temperature - Slide 19.17 - Video timestamp
Equilibrium constant for pure water - Slide 20.06 - Video timestamp
Equilibrium constant from properties of formation - Slide 19.18 - Video timestamp
Equilibrium constant in non-equilibrium law of mass action - Slide 20.05 - Video timestamp
Equilibrium constant in terms of activities - Slide 19.16 - Video timestamp
Equilibrium constant in terms of concentrations - Slide 19.14 - Video timestamp
Equilibrium constant in terms of mole fractions - Slide 19.14 - Video timestamp
Equipartition theorem - Slide 13.16 - Video timestamp
Equivalence ratio - Slide 18.18 - Video timestamp
Euler free energy and minimum work of partitioning a small system - Slide 09.10 - Video timestamp
Euler free energy and mixture properties - Slide 11.37 - Video timestamp
Euler free energy and properties of small systems - Slide 09.09 - Video timestamp
Euler free energy definition - Slide 06.14 - Video timestamp
Euler free energy equal to zero in the simple-system (large n limit) model - Slide 11.34 - Video timestamp
Euler free energy how to measure it for small systems - Slide 09.09 - Video timestamp
Euler free energy how to measure it for small systems - Slide 09.10 - Video timestamp
Euler free energy importance for small systems - Slide 11.31 - Video timestamp
Euler free energy physical interpretation - Slide 09.11 - Video timestamp
Euler free energy vanishes in the large n limit - Slide 11.32 - Video timestamp
Euler free entropy definition - Slide 06.17 - Video timestamp
Euler relation for a pure substance - Slide 11.34 - Video timestamp
Euler relation general - Slide 11.32 - Video timestamp
Euler relation in terms of molar and mass specific properties - Slide 22.16 - Video timestamp
Euler relation in terms of volume specific properties - Slide 22.17 - Video timestamp
Euler relation proof - Slide 08.15 - Video timestamp
Euler relation proof - Slide 09.07 - Video timestamp
Excess air - Slide 18.18 - Video timestamp
Excess chemical potential - Slide 16.09 - Video timestamp
Excess entropy of isothermobaric mixing - Slide 16.09 - Video timestamp
Exergy and direction of chemical reaction - Slide 18.12 - Video timestamp
Exergy and direction of chemical reaction - Slide 18.15 - Video timestamp
Exergy and direction of chemical reaction - Slide 18.16 - Video timestamp
Exergy and second-law efficiency - Slide 08.35 - Video timestamp
Exergy and second-law efficiency - Slide 09.32 - Video timestamp
Exergy balance equation - Slide 08.28 - Video timestamp
Exergy balance equation - Slide 10.09 - Video timestamp
Exergy dissipation in a continuum - Slide 23.10 - Video timestamp
Exergy dissipation in steady-state heat transfer - Slide 21.15 - Video timestamp
Exergy general concept - Slide 08.27 - Video timestamp
Exergy general concept - Slide 08.28 - Video timestamp
Exergy general concept - Slide 08.32 - Video timestamp
Exergy in chemical reactors - Slide 18.16 - Video timestamp
Exergy in chemical reactors - Slide 18.27 - Video timestamp
Exergy in heating and cooling of bulk flows - Slide 10.05 - Video timestamp
Exergy in heating and cooling of bulk flows - Slide 10.08 - Video timestamp
Exergy in heating and cooling of bulk flows - Slide 11.03 - Video timestamp
Exergy minimum for low temperature heating - Slide 10.13 - Video timestamp
Exergy minimum for low temperature heating - Slide 11.04 - Video timestamp
Exergy of a fossil fuel - Slide 10.14 - Video timestamp
Exergy of a fossil fuel - Slide 18.27 - Video timestamp
Exergy of a hydraulic jump - Slide 10.07 - Video timestamp
Exergy of hydrocarbons - Slide 18.22 - Video timestamp
Exergy of solar radiation - Slide 10.43 - Video timestamp
Exergy transfer in a bulk-flow interaction - Slide 09.33 - Video timestamp
Exergy transfer in a bulk-flow interaction - Slide 10.03 - Video timestamp
Exergy transfer in a heat interaction - Slide 08.33 - Video timestamp
Exergy various forms - Slide 10.01 - Video timestamp
Extensive property - Slide 09.13 - Video timestamp
Extensive property - Slide 22.12 - Video timestamp
Fermi, Enrico - Slide 01.03 - Video timestamp
Feynman, Richard P. - Slide 01.20 - Video timestamp
Fick interdiffusion coefficient - Slide 25.12 - Video timestamp
Fick interdiffusion coefficient - Slide 25.14 - Video timestamp
Fick law of molecular diffusion - Slide 23.14 - Video timestamp
Fick law of molecular diffusion - Slide 23.15 - Video timestamp
Fick law of molecular diffusion - Slide 24.02 - Video timestamp
Fick law of molecular diffusion - Slide 25.15 - Video timestamp
First law of Thermodynamics and the definition of energy - Slide 01.18 - Video timestamp
First law of Thermodynamics and the law of time evolution - Slide 01.13 - Video timestamp
First law of Thermodynamics general statement - Slide 01.16 - Video timestamp
First law of Thermodynamics main consequences - Slide 01.18 - Video timestamp
First-law efficiency for a heat engine - Slide 05.13 - Video timestamp
First-law efficiency for a heat pump - Slide 05.15 - Video timestamp
First-law efficiency for a refrigerator - Slide 05.14 - Video timestamp
First-law efficiency general definition - Slide 08.30 - Video timestamp
Flame-based fuel-to-power conversion technologies - Slide 10.21 - Video timestamp
Flame-based fuel-to-power conversion technologies - Slide 11.07 - Video timestamp
Fleck, George - Slide 23.27 - Video timestamp
Fluctuation relation in chemical kinetics - Slide 20.14 - Video timestamp
Fluxes convective - Slide 22.08 - Video timestamp
Fluxes convective - Slide 22.10 - Video timestamp
Fluxes convective - Slide 23.02 - Video timestamp
Fluxes diffusive - Slide 22.08 - Video timestamp
Fluxes diffusive - Slide 22.10 - Video timestamp
Fluxes diffusive - Slide 23.02 - Video timestamp
Fluxes Lagrangian - Slide 22.08 - Video timestamp
Fluxes Lagrangian - Slide 22.10 - Video timestamp
Fluxes Lagrangian - Slide 23.02 - Video timestamp
Force-flux relations cross coupling effects - Slide 23.15 - Video timestamp
Force-flux relations cross coupling effects - Slide 24.02 - Video timestamp
Force-flux relations direct linear laws - Slide 23.14 - Video timestamp
Force-flux relations from steepest entropy ascent - Slide 23.26 - Video timestamp
Force-flux relations general - Slide 23.13 - Video timestamp
Force-flux relations general - Slide 24.06 - Video timestamp
Forward and backward half-reactions - Slide 19.09 - Video timestamp
Forward and backward half-reactions - Slide 20.11 - Video timestamp
Fourier law of thermal conduction - Slide 21.17 - Video timestamp
Fourier law of thermal conduction - Slide 23.14 - Video timestamp
Fourier law of thermal conduction - Slide 23.15 - Video timestamp
Fourier law of thermal conduction - Slide 24.02 - Video timestamp
Fourier law of thermal conduction - Slide 25.15 - Video timestamp
Fourth law of Thermodynamics captures forty years of nonequilbrium theories - Slide 23.25 - Video timestamp
Fourth law of Thermodynamics existence of the nonequilibrium metric $\underline{\underline{G}}$ - Slide 23.25 - Video timestamp
Fourth law of Thermodynamics steepest-entropy-ascent time evolution towards stable equilibrium - Slide 13.15 - Video timestamp
Freezing point depression - Slide 16.06 - Video timestamp
Fuel-cell-based fuel-to-power conversion technologies - Slide 10.23 - Video timestamp
Fuel-cell-based fuel-to-power conversion technologies - Slide 11.06 - Video timestamp
Fuel-to-power technologies flame based - Slide 10.20 - Video timestamp
Fuel-to-power technologies flame based - Slide 11.05 - Video timestamp
Fuel-to-power technologies fuel-cell based - Slide 10.23 - Video timestamp
Fuel-to-power technologies fuel-cell based - Slide 11.06 - Video timestamp
Fuel-to-power technologies three centuries of improvements in second-law efficiency - Slide 10.17 - Video timestamp
Fugacities and fugacity coefficients - Slide 16.13 - Video timestamp
Fundamental relation concavity - Slide 04.15 - Video timestamp
Fundamental relation concavity - Slide 06.23 - Video timestamp
Fundamental relation concavity - Slide 07.23 - Video timestamp
Fundamental relation construction from measurements - Slide 05.28 - Video timestamp
Fundamental relation construction from measurements - Slide 06.13 - Video timestamp
Fundamental relation definition - Slide 02.41 - Video timestamp
Fundamental relation definition - Slide 03.11 - Video timestamp
Fundamental relation for a single particle in a box - Slide 13.13 - Video timestamp
Fundamental relation for chemical equilibrium states - Slide 19.12 - Video timestamp
Fundamental relation fundamental $u$-$s$-$v$ surface - Slide 09.26 - Video timestamp
Fundamental relation of a pure substance - Slide 09.20 - Video timestamp
Fundamental relation representation on $E$-$S$ diagrams - Slide 03.18 - Video timestamp
Fundamental relation when volume is the only important parameter - Slide 13.16 - Video timestamp
Gas constant - Slide 13.11 - Video timestamp
Gheorghiu-Svirschevski, Speranta - Slide 23.27 - Video timestamp
Ghoniem, Ahmed F. - Slide 11.20 - Video timestamp
Gibbs free energy definition - Slide 05.25 - Video timestamp
Gibbs free energy definition - Slide 06.14 - Video timestamp
Gibbs free energy ideal and excess - Slide 16.09 - Video timestamp
Gibbs free energy of combustion and fuel exergy - Slide 10.15 - Video timestamp
Gibbs paradox - Slide 13.11 - Video timestamp
Gibbs phase rule - Slide 09.17 - Video timestamp
Gibbs relation for a continuum - Slide 22.17 - Video timestamp
Gibbs relation for a continuum - Slide 23.06 - Video timestamp
Gibbs relation for a single particle in a box - Slide 13.16 - Video timestamp
Gibbs relation for small systems - Slide 11.31 - Video timestamp
Gibbs relation for small systems - Slide 11.33 - Video timestamp
Gibbs relation general - Slide 03.13 - Video timestamp
Gibbs relation general - Slide 08.14 - Video timestamp
Gibbs relation general - Slide 09.06 - Video timestamp
Gibbs relation in terms of molar and mass specific properties - Slide 22.16 - Video timestamp
Gibbs relation in terms of volume specific properties - Slide 22.17 - Video timestamp
Gibbs, Josiah Willard - Slide 01.03 - Video timestamp
Gibbs-Duhem relation and local-equilibrium simple-system bulk-flow approximations - Slide 22.15 - Video timestamp
Gibbs-Duhem relation and local-equilibrium simple-system bulk-flow approximations - Slide 24.06 - Video timestamp
Gibbs-Duhem relation for a continuum - Slide 22.17 - Video timestamp
Gibbs-Duhem relation for a continuum - Slide 24.06 - Video timestamp
Gibbs-Duhem relation for a continuum - Slide 25.04 - Video timestamp
Gibbs-Duhem relation for a pure substance - Slide 09.24 - Video timestamp
Gibbs-Duhem relation for a pure substance - Slide 11.34 - Video timestamp
Gibbs-Duhem relation general - Slide 08.14 - Video timestamp
Gibbs-Duhem relation general - Slide 09.06 - Video timestamp
Gibbs-Duhem relation general - Slide 11.32 - Video timestamp
Gibbs-Duhem relation in terms of molar and mass specific properties - Slide 22.17 - Video timestamp
Gibbs-Duhem relation in terms of volume specific properties - Slide 22.16 - Video timestamp
Glansdorff, Paul - Slide 23.38 - Video timestamp
Glansdorff-Prigogine minimum entropy production theorem - Slide 23.38 - Video timestamp
Glaser bubble chamber - Slide 15.20 - Video timestamp
Global warming average temperature of atmospheric air - Slide 15.10 - Video timestamp
Global warming average temperature of upper ocean layers - Slide 15.10 - Video timestamp
Global warming climate4you.com website - Slide 15.10 - Video timestamp
Global warming delay between CO2 and temperature peaks - Slide 15.10 - Video timestamp
Global warming solar wind activity measured by sun spots - Slide 15.10 - Video timestamp
Gordon, Sanford - Slide 19.23 - Video timestamp
Grmela, Miroslav - Slide 23.27 - Video timestamp
Grmela, Miroslav - Slide 23.33 - Video timestamp
Guggenheim binary mixture model - Slide 16.10 - Video timestamp
Guggenheim, Edward Armand - Slide 01.03 - Video timestamp
Gyftopoulos, Elias P. - Slide 01.04 - Video timestamp
Gyftopoulos, Elias P. - Slide 23.27 - Video timestamp
Gyftopoulos, Elias P. - Slide 25.28 - Video timestamp
Hadjiconstantinou, Nicolas G. - Slide 08.09 - Video timestamp
Hadjiconstantinou, Nicolas G. - Slide 21.09 - Video timestamp
Hall effect - Slide 24.19 - Video timestamp
Hatsopoulos, George N. - Slide 01.03 - Video timestamp
Hatsopoulos, George N. - Slide 01.04 - Video timestamp
Hatsopoulos, George N. - Slide 01.25 - Video timestamp
Hatsopoulos, George N. - Slide 02.16 - Video timestamp
Hatsopoulos, George N. - Slide 23.27 - Video timestamp
Hatsopoulos, George N. - Slide 25.22 - Video timestamp
Hatsopoulos, George N. - Slide 25.28 - Video timestamp
Heat bath - Slide 07.12 - Video timestamp
Heat capacity at costant pressure - Slide 05.21 - Video timestamp
Heat capacity at costant volume - Slide 05.22 - Video timestamp
Heat conduction Cattaneo-Vernotte equation - Slide 21.20 - Video timestamp
Heat conduction Fourier equation - Slide 21.17 - Video timestamp
Heat conduction in anisotropic media - Slide 21.18 - Video timestamp
Heat conduction vs near-equilibrium chemical kinetics - Slide 22.03 - Video timestamp
Heat engines between reservoirs - Slide 05.13 - Video timestamp
Heat engines, heat pumps, refrigerators - Slide 05.10 - Video timestamp
Heat flux definition in �Heat&diffusion� interactions - Slide 22.23 - Video timestamp
Heat flux definition in �Heat&diffusion� interactions - Slide 22.24 - Video timestamp
Heat flux definition in �Heat&diffusion� interactions - Slide 22.25 - Video timestamp
Heat flux definition in �Heat&diffusion� interactions - Slide 24.03 - Video timestamp
Heat flux in Fourier conduction - Slide 21.17 - Video timestamp
Heat flux vs energy flux in �Heat&diffusion� interactions - Slide 22.23 - Video timestamp
Heat flux vs energy flux in �Heat&diffusion� interactions - Slide 22.24 - Video timestamp
Heat flux vs energy flux in �Heat&diffusion� interactions - Slide 22.25 - Video timestamp
Heat flux vs energy flux in �Heat&diffusion� interactions - Slide 24.03 - Video timestamp
Heat flux vs entropy flux in �Heat&diffusion� interactions - Slide 22.23 - Video timestamp
Heat flux vs entropy flux in �Heat&diffusion� interactions - Slide 22.24 - Video timestamp
Heat flux vs entropy flux in �Heat&diffusion� interactions - Slide 22.25 - Video timestamp
Heat flux vs entropy flux in �Heat&diffusion� interactions - Slide 24.03 - Video timestamp
Heat interaction definition - Slide 05.06 - Video timestamp
Heat interaction definition - Slide 06.02 - Video timestamp
Heat interaction definition - Slide 22.19 - Video timestamp
Heat interaction definition - Slide 24.03 - Video timestamp
Heat interaction definition versus usual understanding - Slide 05.07 - Video timestamp
Heat interaction generalization to heat&diffusion interaction - Slide 22.21 - Video timestamp
Heat interaction in a continuum - Slide 05.08 - Video timestamp
Heat interaction in a continuum - Slide 06.03 - Video timestamp
Heat interaction measurable heat flux in heat&diffusion - Slide 22.23 - Video timestamp
Heat interaction transport velocities for energy and entropy - Slide 22.08 - Video timestamp
Heat of transport - Slide 24.03 - Video timestamp
Heat transfer Cattaneo-Vernotte thermal conduction equation - Slide 21.20 - Video timestamp
Heat transfer Fourier law of thermal conduction - Slide 21.17 - Video timestamp
Heat transfer in anisotropic media - Slide 21.17 - Video timestamp
Heat transfer in anisotropic media - Slide 23.19 - Video timestamp
Heat transfer requires nonequilibrium - Slide 05.08 - Video timestamp
Heat transfer requires nonequilibrium - Slide 21.15 - Video timestamp
Heat transfer steepest entropy ascent interpretation - Slide 23.19 - Video timestamp
Heat&diffusion interaction definition - Slide 22.21 - Video timestamp
Heat&diffusion interaction definition - Slide 22.23 - Video timestamp
Heat&diffusion interaction definition - Slide 23.06 - Video timestamp
Heat&diffusion interaction relation between energy flux, entropy flux, and molar fluxes - Slide 23.03 - Video timestamp
Heat&diffusion interaction relation between independent diffusive fluxes - Slide 24.02 - Video timestamp
Heat&diffusion interaction relation between independent diffusive fluxes - Slide 25.03 - Video timestamp
Heating values and exergy of hydrocarbons - Slide 10.15 - Video timestamp
Heating values and exergy of hydrocarbons - Slide 18.19 - Video timestamp
Helmholtz free energy - Slide 06.14 - Video timestamp
Helmholtz, Hermann, von - Slide 01.03 - Video timestamp
Henry's law - Slide 17.04 - Video timestamp
Hess relation - Slide 18.09 - Video timestamp
Hessian - Slide 06.23 - Video timestamp
Hessian - Slide 06.24 - Video timestamp
Hessian - Slide 07.16 - Video timestamp
Hessian - Slide 07.23 - Video timestamp
Hessian - Slide 16.09 - Video timestamp
Hill, Terrell L. - Slide 06.14 - Video timestamp
History of fuel to power conversion - Slide 10.17 - Video timestamp
Home energy score - Slide 10.25 - Video timestamp
Hortsmann free entropy - Slide 06.17 - Video timestamp
Hybrid solar-fossil power and CHP production - Slide 10.38 - Video timestamp
Ideal entropy of isothermobaric mixing - Slide 14.04 - Video timestamp
Ideal entropy of isothermobaric mixing - Slide 16.09 - Video timestamp
Ideal Amagat-Leduc mixture behavior - Slide 12.10 - Video timestamp
Ideal gas behavior - Slide 09.22 - Video timestamp
Ideal gas equation of state for a single particle in a box - Slide 13.13 - Video timestamp
Ideal gas model - Slide 09.22 - Video timestamp
Ideal gas model and Lennard-Jones potential - Slide 12.09 - Video timestamp
Ideal gas model and Lennard-Jones potential - Slide 13.17 - Video timestamp
Ideal gas model and Lennard-Jones potential - Slide 14.03 - Video timestamp
Ideal Gibbs-Dalton mixture behavior - Slide 12.10 - Video timestamp
Ideal Gibbs-Dalton mixture behavior - Slide 13.05 - Video timestamp
Ideal Gibbs-Dalton mixture of ideal gases - Slide 12.12 - Video timestamp
Ideal incompressible behavior - Slide 09.23 - Video timestamp
Ideal incompressible fluid model - Slide 09.21 - Video timestamp
Ideal incompressible solid model - Slide 09.21 - Video timestamp
Ideal solution behavior - Slide 13.17 - Video timestamp
Ideal solution behavior - Slide 14.03 - Video timestamp
Information theory interpretation - Slide 13.12 - Video timestamp
Intensive property - Slide 09.15 - Video timestamp
Intensive state - Slide 09.15 - Video timestamp
Interdiffusion coefficient - Slide 25.12 - Video timestamp
Interdiffusion of two constituents - Slide 25.11 - Video timestamp
Inversion of population - Slide 20.21 - Video timestamp
Irreversibility in fuel-cell based technologies - Slide 10.23 - Video timestamp
Irreversibility of flame-based combustion - Slide 10.20 - Video timestamp
Irreversibility of flame-based combustion - Slide 11.05 - Video timestamp
Irreversible process, definition - Slide 02.21 - Video timestamp
Isobaric expansion coefficient - Slide 05.23 - Video timestamp
Isoentropic compressibility - Slide 05.24 - Video timestamp
Isothermal compressibility - Slide 05.23 - Video timestamp
Jacobian determinants, general properties - Slide 07.06 - Video timestamp
Jaynes, Edwin T. - Slide 13.12 - Video timestamp
Jordan, Richard - Slide 23.27 - Video timestamp
Jordan, Richard - Slide 23.34 - Video timestamp
Joule coefficient - Slide 05.24 - Video timestamp
Joule heating in electrical conduction - Slide 24.13 - Video timestamp
Joule heating in electrical conduction - Slide 24.18 - Video timestamp
Joule, James P. - Slide 01.03 - Video timestamp
Joule-Thomson coefficient - Slide 05.24 - Video timestamp
Kaufman, Allan N. - Slide 23.27 - Video timestamp
Keck, James C. - Slide 19.21 - Video timestamp
Keck, James C. - Slide 19.23 - Video timestamp
Keck, James C. - Slide 20.18 - Video timestamp
Keck, James C. - Slide 25.28 - Video timestamp
Keenan school of teaching Thermodynamics - Slide 01.04 - Video timestamp
Keenan, Joseph H. - Slide 01.03 - Video timestamp
Keenan, Joseph H. - Slide 01.04 - Video timestamp
Kelvin, William Thomson, Lord - Slide 01.03 - Video timestamp
Kinderlehrer, David - Slide 23.27 - Video timestamp
Kinderlehrer, David - Slide 23.34 - Video timestamp
Kjelstrup, Signe - Slide 22.12 - Video timestamp
Kjelstrup, Signe - Slide 25.22 - Video timestamp
Knudsen diffusion - Slide 25.17 - Video timestamp
Knudsen number - Slide 22.14 - Video timestamp
Lagrange multipliers, method - Slide 13.12 - Video timestamp
Lagrange multipliers, method - Slide 19.22 - Video timestamp
Lagrange multipliers, method - Slide 21.09 - Video timestamp
Lagrange multipliers, method - Slide 23.17 - Video timestamp
Lagrange multipliers, method - Slide 23.26 - Video timestamp
Lagrange multipliers, method - Slide 23.32 - Video timestamp
Lagrangian fluxes - Slide 22.08 - Video timestamp
Lagrangian fluxes - Slide 22.10 - Video timestamp
Lagrangian fluxes - Slide 23.02 - Video timestamp
Lamb law of bulk viscosity - Slide 23.14 - Video timestamp
Lamb law of bulk viscosity - Slide 23.15 - Video timestamp
Lamb law of bulk viscosity - Slide 24.02 - Video timestamp
Laser based on nonequilibrium buildup in a nozzle - Slide 20.19 - Video timestamp
Law of mass action at chemical equilibrium - Slide 19.14 - Video timestamp
Law of mass action at non-equilibrium - Slide 19.14 - Video timestamp
Law of mass action for ideal Gibbs-Dalton gas mixtures - Slide 19.14 - Video timestamp
Law of mass action for ideal Gibbs-Dalton gas mixtures - Slide 19.19 - Video timestamp
Law of mass action for ideal Gibbs-Dalton gas mixtures - Slide 20.05 - Video timestamp
Law of mass action for ideal solutions - Slide 19.15 - Video timestamp
Law of mass action in terms of activities - Slide 19.15 - Video timestamp
Law of maximum local entropy production - Slide 23.27 - Video timestamp
Law of maximum local entropy production - Slide 23.36 - Video timestamp
Law of maximum local entropy production - Slide 23.37 - Video timestamp
Law of maximum local entropy production vs minimum global entropy production - Slide 23.38 - Video timestamp
Law of time evolution and the first law of Thermodynamics - Slide 01.13 - Video timestamp
Law of time evolution and the second law of Thermodynamics - Slide 01.13 - Video timestamp
Law of time evolution of the state of a system - Slide 01.13 - Video timestamp
Learning curve in fuel-to-power conversion technologies - Slide 10.17 - Video timestamp
Learning curve in fuel-to-power conversion technologies - Slide 11.15 - Video timestamp
LeChatelier-Braun principle assertion I - Slide 06.25 - Video timestamp
LeChatelier-Braun principle assertion I - Slide 07.16 - Video timestamp
LeChatelier-Braun principle assertion I - Slide 07.26 - Video timestamp
LeChatelier-Braun principle assertion I - Slide 23.13 - Video timestamp
LeChatelier-Braun principle assertion II - Slide 07.27 - Video timestamp
LeChatelier-Braun principle assertion II - Slide 08.02 - Video timestamp
LeChatelier-Braun principle assertion II - Slide 25.05 - Video timestamp
LeChatelier-Braun principle for a van der Waals fluid - Slide 15.19 - Video timestamp
Legendre transform definition - Slide 05.30 - Video timestamp
Legendre transform definition - Slide 07.16 - Video timestamp
Legendre transform definition - Slide 07.26 - Video timestamp
Legendre transform of fundamental relation in energy form - Slide 06.14 - Video timestamp
Legendre transform of fundamental relation in entropy form - Slide 06.17 - Video timestamp
Lennard-Jones binary mixture model - Slide 16.17 - Video timestamp
Lennard-Jones potential ideal gas behavior - Slide 14.03 - Video timestamp
Lennard-Jones potential ideal solution behavior - Slide 13.17 - Video timestamp
Lennard-Jones potential ideal solution behavior - Slide 14.03 - Video timestamp
Lennard-Jones potential Lennradjonesium - Slide 15.17 - Video timestamp
Lennard-Jones potential model of intermolecular forces - Slide 12.09 - Video timestamp
Lennard-Jones potential model of intermolecular forces - Slide 13.04 - Video timestamp
Lennard-Jones potential model of intermolecular forces - Slide 15.16 - Video timestamp
Lieb, Elliot H. - Slide 03.22 - Video timestamp
Liquid-vapor equilibrium - Slide 09.24 - Video timestamp
Liquid-vapor equilibrium - Slide 09.25 - Video timestamp
Liquid-vapor equilibrium - Slide 16.03 - Video timestamp
Liquid-vapor equilibrium - Slide 16.06 - Video timestamp
Liquid-vapor equilibrium - Slide 16.15 - Video timestamp
Liquid-vapor equilibrium - Slide 17.03 - Video timestamp
Local equilibrium assumption in general nonequilibrium modeling - Slide 23.06 - Video timestamp
Local equilibrium assumption in general nonequilibrium modeling - Slide 24.04 - Video timestamp
Local equilibrium assumption in heat transfer - Slide 05.09 - Video timestamp
Logarithmic mean of forward and backward reactions - Slide 21.03 - Video timestamp
Logarithmic mean of inlet and outlet temperatures - Slide 10.10 - Video timestamp
Lorente, Sylvie - Slide 23.35 - Video timestamp
Lyapunov, Aleksandr Mikhailovich - Slide 01.24 - Video timestamp
Macroscopic limit simple-system model - Slide 08.07 - Video timestamp
Macroscopic limit simple-system model - Slide 09.02 - Video timestamp
Macroscopic limit simple-system model - Slide 09.06 - Video timestamp
Manometer - Slide 05.18 - Video timestamp
Many-particle limit simple-system model - Slide 08.07 - Video timestamp
Many-particle limit simple-system model - Slide 09.02 - Video timestamp
Many-particle limit simple-system model - Slide 09.06 - Video timestamp
Margules one-parameter binary mixture model - Slide 16.10 - Video timestamp
Margules one-parameter binary mixture model - Slide 16.14 - Video timestamp
Margules one-parameter binary mixture model - Slide 17.07 - Video timestamp
Margules two-parameter binary mixture model - Slide 16.10 - Video timestamp
Margules two-parameter binary mixture model - Slide 16.14 - Video timestamp
Martyushev, Leonid M. - Slide 23.27 - Video timestamp
Mass densities in terms of mole and mass fractions and molar densities - Slide 22.11 - Video timestamp
Mass fractions in terms of mole fractions and molar and mass densities - Slide 22.11 - Video timestamp
Massieu free entropy - Slide 06.17 - Video timestamp
Massieu, Francois J.D. - Slide 01.03 - Video timestamp
Material derivative - Slide 22.10 - Video timestamp
Mauri, Roberto - Slide 15.21 - Video timestamp
Maximum entropy principle and chemical equilibrium - Slide 19.22 - Video timestamp
Maximum entropy principle for reacting systems - Slide 19.05 - Video timestamp
Maximum entropy principle proof - Slide 02.39 - Video timestamp
Maximum entropy principle proof - Slide 03.10 - Video timestamp
Maximum local entropy production - Slide 23.27 - Video timestamp
Maximum local entropy production - Slide 23.36 - Video timestamp
Maximum local entropy production rate principle - Slide 21.09 - Video timestamp
Maximum work obtainable from a chemical reaction - Slide 18.16 - Video timestamp
Maxwell relations - Slide 06.15 - Video timestamp
Maxwell relations - Slide 06.16 - Video timestamp
Maxwell relations - Slide 06.18 - Video timestamp
Maxwell relations - Slide 07.04 - Video timestamp
Maxwell relations - Slide 19.12 - Video timestamp
Maxwell-Boltzmann distribution of velocities - Slide 20.09 - Video timestamp
Maxwell-Stefan interdiffusion coefficient - Slide 25.12 - Video timestamp
Mayer relation - Slide 05.24 - Video timestamp
Mayer relation - Slide 07.10 - Video timestamp
Mayer relation for the van der Waals model - Slide 15.18 - Video timestamp
Mazur, Peter - Slide 01.03 - Video timestamp
Mazur, Peter - Slide 22.23 - Video timestamp
Mazur, Peter - Slide 23.15 - Video timestamp
McBride, Bonnie J. - Slide 19.23 - Video timestamp
Mean free path - Slide 22.14 - Video timestamp
Measurable heat flux in a heat&diffusion interaction - Slide 22.21 - Video timestamp
Measurable heat flux in a heat&diffusion interaction - Slide 22.23 - Video timestamp
Measurable heat flux in a heat&diffusion interaction - Slide 24.03 - Video timestamp
Measurable heat flux in a heat&diffusion interaction - Slide 24.04 - Video timestamp
Measurement procedure defining adiabatic availability - Slide 02.23 - Video timestamp
Measurement procedure defining available energy - Slide 02.33 - Video timestamp
Measurement procedure defining chemical potentials - Slide 05.26 - Video timestamp
Measurement procedure defining energy - Slide 01.18 - Video timestamp
Measurement procedure defining energy - Slide 02.11 - Video timestamp
Measurement procedure defining energy - Slide 03.02 - Video timestamp
Measurement procedure defining entropy - Slide 02.32 - Video timestamp
Measurement procedure defining entropy - Slide 03.06 - Video timestamp
Measurement procedure defining heat capacities - Slide 05.20 - Video timestamp
Measurement procedure defining partial pressures - Slide 05.26 - Video timestamp
Measurement procedure defining pressure - Slide 05.18 - Video timestamp
Measurement procedure defining temperature - Slide 05.17 - Video timestamp
Measurement procedure defining temperature of a thermal reservoir - Slide 02.29 - Video timestamp
Mechano-caloric coefficient - Slide 25.09 - Video timestamp
Mesoscopic Nonequilibrium Thermodynamics - Slide 25.24 - Video timestamp
Metastable equilibrium state definition - Slide 01.24 - Video timestamp
Metastable equilibrium state in a partially miscible mixture - Slide 17.07 - Video timestamp
Metastable equilibrium state in Margules one-parameter mixture model - Slide 17.09 - Video timestamp
Metastable equilibrium state in Van der Waals' fluid model - Slide 15.19 - Video timestamp
Mielke, Alexander - Slide 23.27 - Video timestamp
Mielke, Alexander - Slide 23.34 - Video timestamp
Minimum energy principle - Slide 02.40 - Video timestamp
Minimum energy principle - Slide 03.10 - Video timestamp
Minimum entropy production theorem - Slide 23.38 - Video timestamp
Minimum exergy required for low temperature heating - Slide 10.13 - Video timestamp
Minimum work of complete separation of a mixture - Slide 14.13 - Video timestamp
Minimum work of complete separation of a mixture - Slide 15.05 - Video timestamp
Minimum work of partial separation of a mixture - Slide 14.14 - Video timestamp
Minimum work of partitioning a small system - Slide 09.10 - Video timestamp
Minimum work required for a chemical reaction - Slide 18.16 - Video timestamp
Minimum work required to remove CO2 from atmospheric air - Slide 14.14 - Video timestamp
Miscibility gap - Slide 17.08 - Video timestamp
Mixing and demixing graphical representation - Slide 15.06 - Video timestamp
Mixing and demixing minimum work of complete separation - Slide 14.13 - Video timestamp
Mixing and demixing minimum work of complete separation - Slide 15.05 - Video timestamp
Mixing and demixing minimum work of partial separation - Slide 14.14 - Video timestamp
Mixing and demixing of a liquid mixture - Slide 14.16 - Video timestamp
Mixing and demixing of atmospheric air - Slide 14.15 - Video timestamp
Mixing and demixing of ideal gases - Slide 12.13 - Video timestamp
Mixing and demixing of ideal gases - Slide 13.07 - Video timestamp
Mixtures dilute non-ideal solutions - Slide 17.04 - Video timestamp
Mixtures ideal and excess chemical potentials - Slide 16.09 - Video timestamp
Mixtures liquid-vapor equilibria - Slide 16.02 - Video timestamp
Mixtures liquid-vapor equilibria - Slide 16.18 - Video timestamp
Mixtures liquid-vapor equilibria - Slide 17.02 - Video timestamp
Mixtures partial pressures - Slide 11.30 - Video timestamp
Mixtures properties from chemical potentials - Slide 11.30 - Video timestamp
Mixtures properties from partial properties - Slide 12.04 - Video timestamp
Mixtures properties from properties of mixing - Slide 13.03 - Video timestamp
Mixtures properties in general depend on n - Slide 11.30 - Video timestamp
Mixtures properties within the simple-system model - Slide 11.30 - Video timestamp
Mixtures stable equilibrium properties - Slide 11.30 - Video timestamp
Mixtures stable equilibrium properties - Slide 12.02 - Video timestamp
Mixtures various binary mixture models - Slide 16.10 - Video timestamp
Model reduction schemes in chemical kinetics - Slide 19.21 - Video timestamp
Modeling how nonequilibrium states evolve in time - Slide 13.15 - Video timestamp
Modes of interaction between systems Bulk flow - Slide 08.17 - Video timestamp
Modes of interaction between systems Bulk flow - Slide 23.03 - Video timestamp
Modes of interaction between systems Bulk flow - Slide 23.06 - Video timestamp
Modes of interaction between systems Bulk flow - Slide 24.04 - Video timestamp
Modes of interaction between systems Heat - Slide 05.06 - Video timestamp
Modes of interaction between systems Heat - Slide 06.02 - Video timestamp
Modes of interaction between systems Heat - Slide 22.19 - Video timestamp
Modes of interaction between systems Heat&diffusion - Slide 22.21 - Video timestamp
Modes of interaction between systems Heat&diffusion - Slide 22.23 - Video timestamp
Modes of interaction between systems Heat&diffusion - Slide 23.06 - Video timestamp
Modes of interaction between systems Heat&diffusion - Slide 24.03 - Video timestamp
Modes of interaction between systems Work - Slide 05.04 - Video timestamp
Molar densities in terms of mole and mass fractions and mass densities - Slide 22.11 - Video timestamp
Mole fractions in terms of mass fractions and molar and mass densities - Slide 22.11 - Video timestamp
Molecular motors - Slide 25.19 - Video timestamp
Mollier $h$-$s$ diagram for water - Slide 09.28 - Video timestamp
Momentum balance in fluid mechanics - Slide 23.04 - Video timestamp
Momentum flux - Slide 22.08 - Video timestamp
Momentum flux - Slide 22.12 - Video timestamp
Momentum flux - Slide 23.10 - Video timestamp
Morel, Richard E. - Slide 23.27 - Video timestamp
Morrison, Philip J. - Slide 23.27 - Video timestamp
Mutual equilibrium between ocean and atmosphere - Slide 15.10 - Video timestamp
Mutual equilibrium CO2 concentration at sea level - Slide 15.10 - Video timestamp
Mutual equilibrium definition - Slide 02.26 - Video timestamp
Mutual equilibrium necessary conditions - Slide 03.15 - Video timestamp
Mutual equilibrium necessary conditions - Slide 04.07 - Video timestamp
Mutual equilibrium proof of chemical potential equality - Slide 04.12 - Video timestamp
Mutual equilibrium proof of pressure equality - Slide 04.09 - Video timestamp
Mutual equilibrium proof of temperature equality - Slide 04.09 - Video timestamp
Mutual equilibrium Young-Laplace equation - Slide 04.16 - Video timestamp
Nabla - Slide 21.20 - Video timestamp
Nanothermodynamics - Slide 06.14 - Video timestamp
Navier law of momentum diffusion - Slide 23.14 - Video timestamp
Navier law of momentum diffusion - Slide 23.15 - Video timestamp
Navier law of momentum diffusion - Slide 24.02 - Video timestamp
Near-equilibrium linearized relation between rates and affinities - Slide 21.05 - Video timestamp
Near-equilibrium linearized relation between rates and affinities - Slide 21.07 - Video timestamp
Near-equilibrium Onsager relations - Slide 21.07 - Video timestamp
Negative temperatures - Slide 03.19 - Video timestamp
Nernst effect - Slide 24.19 - Video timestamp
Nernst, Walther H. - Slide 01.03 - Video timestamp
Newcomen, Thomas - Slide 10.19 - Video timestamp
Nonequilibrium cross effects - Slide 23.15 - Video timestamp
Nonequilibrium cross effects - Slide 24.02 - Video timestamp
Nonequilibrium cross effects - Slide 25.02 - Video timestamp
Nonequilibrium cross effects - Slide 25.05 - Video timestamp
Nonequilibrium gasdynamic infrared power laser - Slide 20.19 - Video timestamp
Nonequilibrium law of mass action for ideal Gibbs-Dalton gas mixtures - Slide 19.14 - Video timestamp
Nonequilibrium law of mass action for ideal Gibbs-Dalton gas mixtures - Slide 19.19 - Video timestamp
Nonequilibrium law of mass action for ideal Gibbs-Dalton gas mixtures - Slide 20.05 - Video timestamp
Nonequilibrium law of mass action for ideal solutions - Slide 19.15 - Video timestamp
Nonequilibrium law of mass action in terms of activities - Slide 19.15 - Video timestamp
Nonequilibrium states and the fourth law of thermodyanmics - Slide 23.25 - Video timestamp
Nonequilibrium states modeling time evolution - Slide 13.15 - Video timestamp
Nonequilibrium states representation on $E$-$S$ diagrams - Slide 03.18 - Video timestamp
Nonequilibrium theory Coleman-Noll procedure vs ours - Slide 22.04 - Video timestamp
Nonequilibrium theory heat transfer vs chemical kinetics - Slide 22.03 - Video timestamp
Nonequilibrium theory the logic and the assumptions - Slide 22.03 - Video timestamp
Non-Local nonequilibrium models - Slide 25.24 - Video timestamp
Non-work interaction definition - Slide 05.05 - Video timestamp
Non-work interaction not necessarily heat - Slide 05.05 - Video timestamp
NRTL mixture model - Slide 16.10 - Video timestamp
Ohm law of charge diffusion - Slide 23.14 - Video timestamp
Ohm law of charge diffusion - Slide 23.15 - Video timestamp
Ohm law of charge diffusion - Slide 24.02 - Video timestamp
Onsager reciprocity relations near chemical equilbrium - Slide 21.07 - Video timestamp
Onsager reciprocity relations proof from Ziegler's maximal entropy production principle - Slide 21.09 - Video timestamp
Onsager reciprocity relations proof from Ziegler's maximal entropy production principle - Slide 23.17 - Video timestamp
Onsager reciprocity relations sketch of original proof - Slide 23.16 - Video timestamp
Onsager reciprocity relations summary of cross effects - Slide 23.15 - Video timestamp
Onsager reciprocity relations summary of cross effects - Slide 24.02 - Video timestamp
Onsager reciprocity relations summary of cross effects - Slide 25.02 - Video timestamp
Onsager, Lars - Slide 01.03 - Video timestamp
Onsager, Lars - Slide 21.07 - Video timestamp
Osmotic free energy definition - Slide 06.14 - Video timestamp
Osmotic power, blue energy - Slide 14.11 - Video timestamp
Osmotic pressure and blue energy - Slide 14.11 - Video timestamp
Osmotic pressure definition - Slide 14.05 - Video timestamp
Osmotic pressure in biology - Slide 14.06 - Video timestamp
Osmotic pressure in desalination - Slide 14.10 - Video timestamp
Osmotic pressure in lithium-ion batteries - Slide 14.07 - Video timestamp
Osmotic pressure of seawater - Slide 14.08 - Video timestamp
Osmotic pressure Van't Hoff relation - Slide 14.05 - Video timestamp
Ottinger, Hans Christian - Slide 22.12 - Video timestamp
Ottinger, Hans Christian - Slide 23.27 - Video timestamp
Ottinger, Hans Christian - Slide 23.33 - Video timestamp
Otto, Felix - Slide 23.27 - Video timestamp
Otto, Felix - Slide 23.34 - Video timestamp
Ouzo effect - Slide 17.11 - Video timestamp
Oxidation of hydrocarbons - Slide 18.18 - Video timestamp
Park, James L. - Slide 23.27 - Video timestamp
Park, James L. - Slide 25.28 - Video timestamp
Parsons, Charles A. - Slide 10.19 - Video timestamp
Partial pressure and chemical potential - Slide 11.35 - Video timestamp
Partial pressure definition - Slide 05.26 - Video timestamp
Partial pressure definition - Slide 11.35 - Video timestamp
Partial pressure for small systems - Slide 11.35 - Video timestamp
Partial pressure measurement - Slide 06.10 - Video timestamp
Partial properties from chemical potentials - Slide 11.30 - Video timestamp
Partial properties from chemical potentials - Slide 12.03 - Video timestamp
Partial properties from partial pressures - Slide 12.08 - Video timestamp
Partial properties from properties of mixing - Slide 12.05 - Video timestamp
Partial shifting chemical equilibrium - Slide 20.16 - Video timestamp
Partial stable equilibrium states - Slide 19.11 - Video timestamp
Partition function - Slide 13.13 - Video timestamp
Partition function - Slide 13.16 - Video timestamp
Partitioning small systems Euler free energy - Slide 09.10 - Video timestamp
Partitioning small systems minimum work - Slide 09.10 - Video timestamp
Peletier, Mark A. - Slide 23.27 - Video timestamp
Peltier effect - Slide 23.15 - Video timestamp
Peltier effect - Slide 24.02 - Video timestamp
Peltier effect - Slide 24.14 - Video timestamp
Perfect gas behavior - Slide 09.22 - Video timestamp
Perfect gas model - Slide 09.22 - Video timestamp
Perfect incompressible behavior - Slide 09.23 - Video timestamp
Perfect incompressible fluid model - Slide 09.21 - Video timestamp
Perfect incompressible solid model - Slide 09.21 - Video timestamp
Perpetual motion machine of the second kind - Slide 01.25 - Video timestamp
Perpetual motion machine of the second kind - Slide 02.19 - Video timestamp
Perpetual motion machine of the second kind - Slide 02.20 - Video timestamp
Phase definition - Slide 09.16 - Video timestamp
Phase Gibbs rule - Slide 09.17 - Video timestamp
Photon flux carried by electromagnetic radiation - Slide 24.05 - Video timestamp
Pioneers of Thermodynamics - Slide 01.03 - Video timestamp
Planck free entropy - Slide 06.17 - Video timestamp
Planck, Max - Slide 01.03 - Video timestamp
Potential energy surface - Slide 19.08 - Video timestamp
Potential energy surface - Slide 20.08 - Video timestamp
Poynting effect - Slide 16.03 - Video timestamp
Prausnitz, John M. - Slide 01.03 - Video timestamp
Pressure retarded osmosis - Slide 14.11 - Video timestamp
Pressure tensor - Slide 22.08 - Video timestamp
Pressure capturing tendency for energy - Slide 06.06 - Video timestamp
Pressure definition - Slide 02.42 - Video timestamp
Pressure definition - Slide 03.14 - Video timestamp
Pressure equality at mutual equilibrium - Slide 03.15 - Video timestamp
Pressure for a single particle in a box - Slide 13.16 - Video timestamp
Pressure measurement - Slide 05.18 - Video timestamp
Pressure measurement - Slide 06.09 - Video timestamp
Pressure mechanical versus thermodynamic - Slide 22.08 - Video timestamp
Pressure mechanical versus thermodynamic - Slide 23.07 - Video timestamp
Pressure mechanical versus thermodynamic - Slide 23.14 - Video timestamp
Pressure vs force per unit area - Slide 05.19 - Video timestamp
Pressure-volume diagram for a van der Waals fluid - Slide 09.30 - Video timestamp
Pressure-volume diagram for water - Slide 09.29 - Video timestamp
Prigogine Prize for Thermodynamics - Slide 21.13 - Video timestamp
Prigogine Prize for Thermodynamics - Slide 25.27 - Video timestamp
Prigogine, Ilya - Slide 01.03 - Video timestamp
Prigogine, Ilya - Slide 21.13 - Video timestamp
Prigogine, Ilya - Slide 23.38 - Video timestamp
Prigogine, Ilya - Slide 25.28 - Video timestamp
Primary energy savings in heat and power cogeneration - Slide 10.26 - Video timestamp
Primary energy savings in hybrid solar-fossil power production - Slide 10.39 - Video timestamp
Principal radii of interfacial curvature - Slide 04.20 - Video timestamp
Principle of detailed balance - Slide 20.13 - Video timestamp
Process definition - Slide 01.14 - Video timestamp
Process definition - Slide 02.08 - Video timestamp
Process reversible - Slide 02.08 - Video timestamp
Product-favored reaction - Slide 18.12 - Video timestamp
Properties of formation - Slide 18.09 - Video timestamp
Properties of reaction - Slide 17.15 - Video timestamp
Properties of reaction - Slide 18.05 - Video timestamp
Property definition - Slide 01.11 - Video timestamp
Property definition - Slide 02.05 - Video timestamp
Property extensive - Slide 09.13 - Video timestamp
Property extensive - Slide 22.12 - Video timestamp
Property intensive - Slide 09.15 - Video timestamp
Property of isothermobaric mixing - Slide 12.05 - Video timestamp
Property specific - Slide 09.14 - Video timestamp
Proportionality relations - Slide 17.14 - Video timestamp
Proportionality relations - Slide 18.04 - Video timestamp
Proportionality relations - Slide 19.03 - Video timestamp
Pulsion work - Slide 08.21 - Video timestamp
Pulsion work - Slide 22.23 - Video timestamp
Pure substance properties of homogeneous SES's - Slide 09.20 - Video timestamp
Pure substance properties of ideal gas SES's - Slide 09.22 - Video timestamp
Pure substance properties of ideal incompressible SES's - Slide 09.21 - Video timestamp
Pure substance properties of two-phase SES's - Slide 09.25 - Video timestamp
Quantum Thermodynamics, Hatsopoulos and Gyftopoulos pioneers - Slide 01.05 - Video timestamp
Quincke effect - Slide 23.15 - Video timestamp
Quincke effect - Slide 24.02 - Video timestamp
Radiation, energy and entropy of - Slide 10.43 - Video timestamp
Radiation, energy and entropy of - Slide 24.05 - Video timestamp
Ramsey, Norman F. - Slide 03.19 - Video timestamp
Rankine, William J.M. - Slide 01.03 - Video timestamp
Raoult's law - Slide 16.03 - Video timestamp
Raoult's law - Slide 18.21 - Video timestamp
Raoult's lawii - Slide 17.04 - Video timestamp
Rational Extended Thermodynamics - Slide 25.24 - Video timestamp
Rayleigh-Benard instability - Slide 23.36 - Video timestamp
Reactant-favored reaction - Slide 18.12 - Video timestamp
Reaction coordinates - Slide 17.14 - Video timestamp
Reaction coordinates - Slide 18.04 - Video timestamp
Reaction coordinates - Slide 19.03 - Video timestamp
Reaction rate constants - Slide 20.11 - Video timestamp
Reaction rate constants - Slide 20.15 - Video timestamp
Reaction rates - Slide 20.11 - Video timestamp
Reaction rates - Slide 20.15 - Video timestamp
Reaction rates - Slide 21.03 - Video timestamp
Reaction rates - Slide 21.05 - Video timestamp
Real-estate energy-efficiency regulations - Slide 10.25 - Video timestamp
Redlich-Kister binary mixture model - Slide 16.10 - Video timestamp
Relative diffusive fluxes - Slide 24.06 - Video timestamp
Relative diffusive fluxes - Slide 24.06 - Video timestamp
Relative diffusive fluxes - Slide 25.03 - Video timestamp
Relative volatility - Slide 16.05 - Video timestamp
Reservoir: see Thermal reservoir - Slide 02.26 - Video timestamp
Reuss effect - Slide 23.15 - Video timestamp
Reuss effect - Slide 24.02 - Video timestamp
Reverse electrodialysis - Slide 14.11 - Video timestamp
Reversible combustion - Slide 18.28 - Video timestamp
Reversible process criteria for a weight process - Slide 02.24 - Video timestamp
Reversible process definition - Slide 02.21 - Video timestamp
Reynolds theorem - Slide 22.09 - Video timestamp
Righi-Leduc effect - Slide 21.18 - Video timestamp
Rohsenow, Warren M. - Slide 22.05 - Video timestamp
Savery, Thomas - Slide 10.19 - Video timestamp
Scatchard binary mixture model - Slide 16.10 - Video timestamp
Seawater desalination - Slide 14.10 - Video timestamp
Second coefficient of viscosity - Slide 23.14 - Video timestamp
Second law of Thermodynamics and the law of time evolution - Slide 01.13 - Video timestamp
Second law of Thermodynamics Clausius statement - Slide 04.23 - Video timestamp
Second law of Thermodynamics compatible compositions - Slide 19.04 - Video timestamp
Second law of Thermodynamics for systems with chemical reactions - Slide 19.04 - Video timestamp
Second law of Thermodynamics general statement - Slide 01.25 - Video timestamp
Second law of Thermodynamics Hatsopoulos-Keenan statement - Slide 01.25 - Video timestamp
Second law of Thermodynamics Hatsopoulos-Keenan statement - Slide 02.16 - Video timestamp
Second law of Thermodynamics Hatsopoulos-Keenan statement - Slide 02.22 - Video timestamp
Second law of Thermodynamics Hatsopoulos-Keenan statement for reacting systems - Slide 19.04 - Video timestamp
Second law of Thermodynamics importance of second part - Slide 02.22 - Video timestamp
Second law of Thermodynamics importance of second part - Slide 03.04 - Video timestamp
Second law of Thermodynamics Kelvin-Planck statement - Slide 01.25 - Video timestamp
Second law of Thermodynamics Kelvin-Planck statement - Slide 02.19 - Video timestamp
Second law of Thermodynamics proof of Clausius statement - Slide 04.23 - Video timestamp
Second law of Thermodynamics proof of Clausius statement - Slide 05.02 - Video timestamp
Second law of Thermodynamics proof of generalized Clausius statement - Slide 22.22 - Video timestamp
Second-law efficiency for a heat engine - Slide 05.13 - Video timestamp
Second-law efficiency for a heat pump - Slide 05.15 - Video timestamp
Second-law efficiency for a refrigerator - Slide 05.14 - Video timestamp
Second-law efficiency general definition - Slide 08.31 - Video timestamp
Second-law efficiency in heating and cooling of bulk flows - Slide 09.08 - Video timestamp
Second-law efficiency of a thermoelectric generator - Slide 24.17 - Video timestamp
Second-law efficiency of a thermoelectric generator - Slide 25.07 - Video timestamp
Second-law efficiency of fuel-to-power conversion - Slide 11.14 - Video timestamp
Second-law efficiency of fuel-to-power conversion technologies - Slide 10.17 - Video timestamp
Seebeck effect - Slide 23.15 - Video timestamp
Seebeck effect - Slide 24.02 - Video timestamp
Seebeck effect - Slide 24.12 - Video timestamp
Self diffusion - Slide 25.12 - Video timestamp
Semipermeable membranes - Slide 11.35 - Video timestamp
Semipermeable membranes - Slide 12.03 - Video timestamp
Semipermeable membranes - Slide 12.15 - Video timestamp
Semipermeable membranes - Slide 13.10 - Video timestamp
Semipermeable membranes - Slide 15.07 - Video timestamp
Shannon information entropy - Slide 13.12 - Video timestamp
Shapiro, Asher H. - Slide 22.05 - Video timestamp
Shear viscosity - Slide 23.14 - Video timestamp
Sieniutycz, Stanislaw - Slide 23.27 - Video timestamp
Sieniutycz, Stanislaw - Slide 23.34 - Video timestamp
Silvestri, Mario - Slide 25.28 - Video timestamp
Simple-system model and rarefaction effects near walls - Slide 08.13 - Video timestamp
Simple-system model effect of inserting and removing partitions - Slide 08.13 - Video timestamp
Simple-system model effect of inserting and removing partitions - Slide 09.05 - Video timestamp
Simple-system model extension for reacting systems - Slide 19.10 - Video timestamp
Simple-system model extension for reacting systems - Slide 20.03 - Video timestamp
Simple-system model proof of Euler relation - Slide 08.15 - Video timestamp
Simple-system model rarefaction effects near walls - Slide 08.08 - Video timestamp
Simple-system model rarefaction effects near walls - Slide 09.03 - Video timestamp
Simple-system model valid in the macroscopic limit - Slide 08.07 - Video timestamp
Small scale hydrodynamics - Slide 25.24 - Video timestamp
Small systems and Euler free energy - Slide 09.10 - Video timestamp
Small systems definition of partial pressure - Slide 11.35 - Video timestamp
Small systems general comments on the range of validity of thermodynamics - Slide 06.01 - Video timestamp
Small systems minimum work of partitioning - Slide 09.10 - Video timestamp
Small systems much of thermodynamics still holds - Slide 06.01 - Video timestamp
Small systems properties of a pure substance - Slide 06.11 - Video timestamp
Small systems properties of a pure substance - Slide 11.33 - Video timestamp
Small systems properties of mixtures - Slide 06.11 - Video timestamp
Small systems properties of mixtures - Slide 11.31 - Video timestamp
Small systems properties of mixtures - Slide 11.37 - Video timestamp
Small systems SES properties depend on n - Slide 09.09 - Video timestamp
Small systems simple-system model (large n limit) - Slide 09.06 - Video timestamp
Small systems vs large n limit - Slide 08.07 - Video timestamp
Small systems vs large n limit - Slide 09.02 - Video timestamp
Small systems vs large n limit - Slide 11.31 - Video timestamp
Small systems vs large n limit - Slide 11.33 - Video timestamp
Solar energy and solar entropy - Slide 10.43 - Video timestamp
Solar energy and solar entropy - Slide 11.26 - Video timestamp
Solar energy and solar entropy - Slide 24.05 - Video timestamp
Solar radiation, energy and entropy - Slide 24.05 - Video timestamp
Solubility gap - Slide 17.08 - Video timestamp
Sommerfeld, Arnold - Slide 01.03 - Video timestamp
Sonin, Ain A. - Slide 22.05 - Video timestamp
Soret effect - Slide 23.15 - Video timestamp
Soret effect - Slide 24.02 - Video timestamp
Soret effect - Slide 25.15 - Video timestamp
Specific heat for an incompressible substance - Slide 09.21 - Video timestamp
Specific heats and degrees of freedom for ideal gases - Slide 09.22 - Video timestamp
Specific property - Slide 09.14 - Video timestamp
Speed of sound propagation - Slide 05.24 - Video timestamp
Spin-Hall effect - Slide 24.19 - Video timestamp
Spin-Nernst effect - Slide 24.19 - Video timestamp
Spinodal curve in Margules one-parameter mixture model - Slide 17.07 - Video timestamp
Spinodal curve in Van der Waals' fluid model - Slide 15.19 - Video timestamp
Spinodal decomposition - Slide 15.21 - Video timestamp
Spinodal decomposition - Slide 17.10 - Video timestamp
Spin-Seebeck effect - Slide 24.20 - Video timestamp
Spontanueous emission of photons - Slide 20.20 - Video timestamp
Stability conditions and availability functions - Slide 06.22 - Video timestamp
Stability conditions and availability functions - Slide 06.24 - Video timestamp
Stability conditions and availability functions - Slide 07.14 - Video timestamp
Stability conditions and availability functions - Slide 07.18 - Video timestamp
Stability conditions and availability functions - Slide 07.20 - Video timestamp
Stability conditions and availability functions - Slide 07.22 - Video timestamp
Stability conditions and availability functions - Slide 07.24 - Video timestamp
Stability conditions and LeChatelier-Braun principle - Slide 06.25 - Video timestamp
Stability conditions and LeChatelier-Braun principle - Slide 07.16 - Video timestamp
Stability conditions and LeChatelier-Braun principle - Slide 07.26 - Video timestamp
Stability conditions for a partially miscible mixture - Slide 16.11 - Video timestamp
Stability conditions for a partially miscible mixture - Slide 17.07 - Video timestamp
Stable equilibrium state definition - Slide 01.24 - Video timestamp
Stable equilibrium state for systems with chemical reaction - Slide 19.05 - Video timestamp
Stable equilibrium state heterogeneous - Slide 09.16 - Video timestamp
Stable equilibrium state homogeneous - Slide 09.16 - Video timestamp
Stable equilibrium state properties depend on n, for small systems - Slide 09.09 - Video timestamp
Stable equilibrium state properties of a pure substance (large n) - Slide 06.11 - Video timestamp
Stable equilibrium state properties of a pure substance (large n) - Slide 11.34 - Video timestamp
Stable equilibrium state properties of a pure substance (small n) - Slide 06.11 - Video timestamp
Stable equilibrium state properties of a pure substance (small n) - Slide 11.33 - Video timestamp
Stable equilibrium state properties of mixtures (large n) - Slide 06.11 - Video timestamp
Stable equilibrium state properties of mixtures (large n) - Slide 11.32 - Video timestamp
Stable equilibrium state properties of mixtures (small n) - Slide 06.11 - Video timestamp
Stable equilibrium state properties of mixtures (small n) - Slide 11.31 - Video timestamp
Standard reversible weight process - Slide 02.28 - Video timestamp
State changes, law of time evolution - Slide 01.13 - Video timestamp
State changes, law of time evolution - Slide 02.08 - Video timestamp
State of a system definition - Slide 01.12 - Video timestamp
State of a system definition - Slide 02.06 - Video timestamp
State of a system equilibrium - Slide 01.22 - Video timestamp
State of a system equilibrium - Slide 02.14 - Video timestamp
State of a system metastable equilibrium - Slide 01.04 - Video timestamp
State of a system metastable equilibrium - Slide 02.15 - Video timestamp
State of a system nonequilibrium - Slide 01.22 - Video timestamp
State of a system nonequilibrium - Slide 02.14 - Video timestamp
State of a system representation on $E$-$S$ diagrams - Slide 03.18 - Video timestamp
State of a system stable equilibrium - Slide 01.24 - Video timestamp
State of a system stable equilibrium - Slide 02.15 - Video timestamp
State of a system steady - Slide 01.22 - Video timestamp
State of a system steady - Slide 02.14 - Video timestamp
State of a system unstable equilibrium - Slide 01.24 - Video timestamp
State of a system unstable equilibrium - Slide 02.15 - Video timestamp
State of a system unsteady - Slide 01.22 - Video timestamp
State of a system unsteady - Slide 02.14 - Video timestamp
State principle - Slide 02.41 - Video timestamp
State principle - Slide 03.11 - Video timestamp
State principle in reacting systems - Slide 19.05 - Video timestamp
Steepest entropy ascent a �great� principle from Nonequilbrium Thermodynamics - Slide 23.28 - Video timestamp
Steepest entropy ascent abstract geometrical construction - Slide 23.29 - Video timestamp
Steepest entropy ascent and the fourth law of Thermodynamics - Slide 23.25 - Video timestamp
Steepest entropy ascent dissipation metric - Slide 23.19 - Video timestamp
Steepest entropy ascent entropy production rate - Slide 23.31 - Video timestamp
Steepest entropy ascent general evolution equation - Slide 23.32 - Video timestamp
Steepest entropy ascent generalized overall degree of disequilibrium - Slide 23.31 - Video timestamp
Steepest entropy ascent graphical illustration - Slide 23.21 - Video timestamp
Steepest entropy ascent implies Onsager reciprocity - Slide 23.20 - Video timestamp
Steepest entropy ascent in anisotropic heat conduction - Slide 23.19 - Video timestamp
Steepest entropy ascent maximum entropy production rate principle - Slide 21.09 - Video timestamp
Steepest entropy ascent model of relaxation toward SES - Slide 15.08 - Video timestamp
Steepest entropy ascent nonequilibrium Massieu operator - Slide 23.31 - Video timestamp
Steepest entropy ascent orthogonality condition - Slide 23.30 - Video timestamp
Steepest entropy ascent variational statement - Slide 23.32 - Video timestamp
Steepest entropy ascent versus GENERIC - Slide 23.33 - Video timestamp
Steepest entropy ascent versus gradient flows - Slide 23.33 - Video timestamp
Steepest-entropy-ascent time evolution towards stable equilibrium - Slide 13.15 - Video timestamp
Stefan-Boltzmann constant - Slide 24.05 - Video timestamp
Stevin, Simon - Slide 15.09 - Video timestamp
Stimulated emission of photons - Slide 20.20 - Video timestamp
Stoichiometry - Slide 17.14 - Video timestamp
Stoichiometry - Slide 18.04 - Video timestamp
Stoichiometry - Slide 19.03 - Video timestamp
Stratification of air components in the atmosphere - Slide 15.09 - Video timestamp
Stratification of gas and liquid charge carriers in an electric field - Slide 15.13 - Video timestamp
Stratification of ideal gas and liquid mixtures - Slide 14.17 - Video timestamp
Stratification of ideal gas and liquid mixtures in a centrifuge - Slide 15.11 - Video timestamp
Stratification of ideal gas and liquid mixtures in a gravity field - Slide 15.08 - Video timestamp
Stress tensor - Slide 22.08 - Video timestamp
Surface tension and Young-Laplace equation - Slide 04.19 - Video timestamp
Surprise - Slide 13.12 - Video timestamp
Swenson, Rod - Slide 23.27 - Video timestamp
System definition - Slide 01.09 - Video timestamp
System definition - Slide 02.04 - Video timestamp
System definition, for systems with chemical reactions - Slide 19.04 - Video timestamp
System SES properties for small n - Slide 09.02 - Video timestamp
System SES properties for small n - Slide 09.09 - Video timestamp
System simple-system model for large n - Slide 08.08 - Video timestamp
System small vs large n limit - Slide 08.07 - Video timestamp
System small vs large n limit - Slide 09.02 - Video timestamp
System small vs large n limit - Slide 11.31 - Video timestamp
System with chemical reactions - Slide 17.12 - Video timestamp
System with chemical reactions - Slide 18.03 - Video timestamp
Temperature definition for a general SES - Slide 02.42 - Video timestamp
Temperature definition for a general SES - Slide 03.14 - Video timestamp
Temperature definition for a thermal reservoir - Slide 02.29 - Video timestamp
Temperature definition for a thermal reservoir - Slide 03.05 - Video timestamp
Temperature equality at mutual equilibrium - Slide 03.15 - Video timestamp
Temperature escaping tendency for energy - Slide 06.05 - Video timestamp
Temperature log-mean, in heating, cooling, boiling and condensing of bulk flows - Slide 10.10 - Video timestamp
Temperature measurement - Slide 05.17 - Video timestamp
Temperature measurement - Slide 06.08 - Video timestamp
Temperature negative - Slide 03.19 - Video timestamp
Temperature versus average kinetic energy - Slide 03.18 - Video timestamp
Termodiffusion coefficient - Slide 25.14 - Video timestamp
The bends (decompression sickness) - Slide 17.05 - Video timestamp
Thermal conductivity Fourier law of thermal conduction - Slide 21.17 - Video timestamp
Thermal conductivity of an anisotropic material - Slide 21.18 - Video timestamp
Thermal diffusivity - Slide 20.21 - Video timestamp
Thermal reservoir definition - Slide 02.26 - Video timestamp
Thermal reservoir with fixed V and n - Slide 02.33 - Video timestamp
Thermal reservoir with fixed V and n - Slide 06.20 - Video timestamp
Thermal reservoir with fixed V and n - Slide 07.12 - Video timestamp
Thermal reservoir with fixed V and variable n_i - Slide 07.19 - Video timestamp
Thermal reservoir with variable V and n - Slide 06.19 - Video timestamp
Thermal reservoir with variable V and n - Slide 07.21 - Video timestamp
Thermal reservoir with variable V and fixed n - Slide 07.17 - Video timestamp
Thermocouple - Slide 24.12 - Video timestamp
Thermocouple - Slide 24.20 - Video timestamp
Thermodiffusion effects - Slide 25.10 - Video timestamp
Thermodynamics much of it applies also to modeling of small systems - Slide 06.01 - Video timestamp
Thermodynamics of small systems - Slide 06.14 - Video timestamp
Thermodynamics, what is it? - Slide 01.09 - Video timestamp
Thermoelectric effects - Slide 24.07 - Video timestamp
Thermoelectric effects - Slide 25.06 - Video timestamp
Thermoelectric generator - Slide 24.13 - Video timestamp
Thermometer - Slide 05.17 - Video timestamp
Thermo-osmosis effect - Slide 25.08 - Video timestamp
Thermo-osmotic permeability - Slide 25.09 - Video timestamp
Thermophoresis - Slide 25.13 - Video timestamp
Thermophoresis - Slide 25.16 - Video timestamp
Thermophoresis - Slide 25.20 - Video timestamp
Third law of Thermodynamics - Slide 03.16 - Video timestamp
Third law of Thermodynamics - Slide 03.18 - Video timestamp
Third law of Thermodynamics - Slide 03.19 - Video timestamp
Thomson effect - Slide 24.18 - Video timestamp
Time evolution towards stable equilibrium - Slide 13.15 - Video timestamp
Total potentials definition - Slide 14.17 - Video timestamp
Total potentials definition - Slide 15.13 - Video timestamp
Total potentials in heat&diffusion interactions - Slide 22.24 - Video timestamp
Total potentials in heat&diffusion interactions - Slide 22.25 - Video timestamp
Total potentials in heat&diffusion interactions - Slide 23.03 - Video timestamp
Total potentials in heat&diffusion interactions - Slide 24.04 - Video timestamp
Touchette, Hugo - Slide 23.27 - Video timestamp
Transition state - Slide 19.08 - Video timestamp
Transport velocity for a generic extensive property - Slide 22.08 - Video timestamp
Transport velocity for energy and entropy - Slide 22.08 - Video timestamp
Transport velocity for mass, barycentric velocity - Slide 22.08 - Video timestamp
Tribus, Myron - Slide 13.12 - Video timestamp
Trigeneration - Slide 11.13 - Video timestamp
Triple point of water - Slide 02.26 - Video timestamp
UNIFAC mixture model - Slide 16.10 - Video timestamp
UNIQUAC mixture model - Slide 16.10 - Video timestamp
Unstable equilibrium state, definition - Slide 01.24 - Video timestamp
Upper bounded vs unbounded energy spectrum - Slide 13.14 - Video timestamp
Uranium enrichment in centrifuges - Slide 15.12 - Video timestamp
Van der Waals p-V diagram - Slide 09.30 - Video timestamp
Van der Waals cloud and bubble chambers - Slide 15.20 - Video timestamp
Van der Waals forces vs covalent bonds - Slide 17.17 - Video timestamp
Van der Waals forces vs covalent bonds - Slide 18.07 - Video timestamp
Van der Waals isotherms and chemical potential - Slide 15.19 - Video timestamp
Van der Waals liquid-vapor spinodal decomposition - Slide 15.21 - Video timestamp
Van der Waals metastable and unstable states - Slide 15.19 - Video timestamp
Van der Waals model for a pure substance - Slide 09.30 - Video timestamp
Van der Waals model for a pure substance - Slide 15.18 - Video timestamp
Van der Waals, Johannes - Slide 01.03 - Video timestamp
Van Laar binary mixture model - Slide 15.14 - Video timestamp
Van Laar binary mixture model - Slide 16.10 - Video timestamp
Van Laar binary mixture model - Slide 16.14 - Video timestamp
Van 't Hoff relation for osmotic pressure - Slide 14.05 - Video timestamp
Van 't Hoff, Jacobus - Slide 01.03 - Video timestamp
Velocity of transport for a generic extensive property - Slide 22.08 - Video timestamp
Velocity of transport for energy and entropy - Slide 22.08 - Video timestamp
Velocity of transport for mass, barycentric velocity - Slide 22.08 - Video timestamp
Vibrational levels of the CO2 molecule - Slide 20.19 - Video timestamp
Viscosity, second coefficient of - Slide 23.14 - Video timestamp
Viscosity, shear vs bulk - Slide 23.14 - Video timestamp
Viscous dissipation function - Slide 23.06 - Video timestamp
Viscous dissipation function - Slide 23.07 - Video timestamp
Viscous dissipation function - Slide 23.08 - Video timestamp
Viscous dissipation function - Slide 23.09 - Video timestamp
Volta effect - Slide 23.15 - Video timestamp
Volta effect - Slide 24.02 - Video timestamp
Volume of isothermobaric mixing - Slide 12.07 - Video timestamp
Von Spakovsky, Michael R. - Slide 23.27 - Video timestamp
Water desalination - Slide 14.10 - Video timestamp
Watt, James - Slide 10.19 - Video timestamp
Weight process criteria for reversibility - Slide 02.24 - Video timestamp
Weight process criteria for reversibility - Slide 02.36 - Video timestamp
Weight process criteria for reversibility - Slide 03.08 - Video timestamp
Weight process definition - Slide 01.15 - Video timestamp
Weight process definition - Slide 02.09 - Video timestamp
Weight process standard reversible - Slide 02.28 - Video timestamp
Weight process versus adiabatic process - Slide 05.04 - Video timestamp
Wilson binary mixture model - Slide 16.10 - Video timestamp
Wilson cloud chamber - Slide 15.20 - Video timestamp
Wine, alcohol content - Slide 14.16 - Video timestamp
Work interaction, definition - Slide 05.04 - Video timestamp
Young-Laplace equation for surface tension - Slide 04.19 - Video timestamp
Zanchini, Enzo - Slide 03.22 - Video timestamp
Ziegler orthogonality relations - Slide 21.09 - Video timestamp
Ziegler orthogonality relations - Slide 21.10 - Video timestamp
Ziegler orthogonality relations - Slide 23.17 - Video timestamp
Ziegler orthogonality relations - Slide 23.18 - Video timestamp
Ziegler, Hans - Slide 01.03 - Video timestamp
Ziegler, Hans - Slide 21.09 - Video timestamp
Ziegler, Hans - Slide 21.10 - Video timestamp
Ziegler, Hans - Slide 23.18 - Video timestamp
Ziegler, Hans - Slide 23.27 - Video timestamp

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Complete analytical index all topics covered in the course

Activated complex - Slide 19.08 - Video timestamp

Activated complex - Slide 20.02 - Video timestamp

Activated complex - Slide 20.08 - Video timestamp

Active matter - Slide 25.18 - Video timestamp

Activities and activity coefficients - Slide 16.12 - Video timestamp

Adiabatic availability definition - Slide 02.23 - Video timestamp

Adiabatic availability graphical representation - Slide 03.21 - Video timestamp

Adiabatic availability graphical representation - Slide 04.03 - Video timestamp

Adiabatic availability of mixing ideal gases - Slide 12.14 - Video timestamp

Adiabatic availability of mixing ideal gases - Slide 12.15 - Video timestamp

Adiabatic availability of mixing ideal gases - Slide 13.08 - Video timestamp

Adiabatic availability of mixing ideal gases - Slide 15.04 - Video timestamp

Adiabatic flame temperature in a closed combustion chamber - Slide 18.25 - Video timestamp

Adiabatic flame temperature in a closed combustion chamber - Slide 18.27 - Video timestamp

Adiabatic flame temperature in a closed combustion chamber - Slide 19.20 - Video timestamp

Adiabatic flame temperature in an open burner - Slide 18.22 - Video timestamp

Adiabatic process definition - Slide 05.04 - Video timestamp

Adiabatic process versus weight process - Slide 05.04 - Video timestamp

Advanced Thermodynamics, 2.43 Course introduction - Slide 01.01 - Video timestamp

Advanced Thermodynamics, 2.43 Course objectives, Part 1 - Slide 01.05 - Video timestamp

Advanced Thermodynamics, 2.43 Course objectives, Part 2 - Slide 01.06 - Video timestamp

Advanced Thermodynamics, 2.43 Course objectives, Part 3 - Slide 01.07 - Video timestamp

Advanced Thermodynamics, 2.43 Grading policy - Slide 01.08 - Video timestamp

Affinity and degree of disequilibrium - Slide 20.13 - Video timestamp

Affinity and direction of reaction - Slide 20.14 - Video timestamp

Affinity and reaction rates - Slide 21.03 - Video timestamp

Affinity and reaction rates - Slide 21.05 - Video timestamp

Affinity De Donder - Slide 19.11 - Video timestamp

Affinity entropic versus energetic - Slide 20.04 - Video timestamp

Affinity of a reaction - Slide 19.12 - Video timestamp

Allocation methods in heat and power cogeneration - Slide 10.25 - Video timestamp

Allocation methods in heat and power cogeneration - Slide 11.16 - Video timestamp

Allocation methods in hybrid solar-fossil power production - Slide 10.38 - Video timestamp

Allocation methods in hybrid solar-fossil power production - Slide 11.23 - Video timestamp

Amagat law of additive volumes - Slide 12.12 - Video timestamp

Anand, Lallit - Slide 22.04 - Video timestamp

Anisotropic Fourier conduction - Slide 21.17 - Video timestamp

Anisotropic Fourier conduction - Slide 21.19 - Video timestamp

Antanovskii, Leonid K. - Slide 25.24 - Video timestamp

Arrhenius law and activation barrier - Slide 20.10 - Video timestamp

Availability function and related stability conditions - Slide 06.22 - Video timestamp

Availability function general concept - Slide 06.20 - Video timestamp

Availability function graphical representation - Slide 06.21 - Video timestamp

Availability function graphical representation - Slide 07.13 - Video timestamp

Availability function w.r.to a fixed V and n reservoir - Slide 06.19 - Video timestamp

Availability function w.r.to a fixed V and n reservoir - Slide 07.12 - Video timestamp

Availability function w.r.to a fixed V and variable n_i reservoir - Slide 07.19 - Video timestamp

Availability function w.r.to a variable V and n reservoir - Slide 07.21 - Video timestamp

Availability function w.r.to a variable V and fixed n reservoir - Slide 07.17 - Video timestamp

Available energy and its related availability function - Slide 06.20 - Video timestamp

Available energy and its related availability function - Slide 07.12 - Video timestamp

Available energy graphical representation - Slide 03.25 - Video timestamp

Available energy graphical representation - Slide 04.05 - Video timestamp

Available energy graphical representation - Slide 06.21 - Video timestamp

Available energy graphical representation - Slide 07.13 - Video timestamp

Available energy w.r.to a fixed V and n reservoir - Slide 02.33 - Video timestamp

Available energy w.r.to a fixed V and n reservoir - Slide 06.20 - Video timestamp

Available energy w.r.to a fixed V and n reservoir - Slide 07.12 - Video timestamp

Available energy w.r.to a fixed V and variable n_i reservoir - Slide 07.19 - Video timestamp

Available energy w.r.to a variable V and n reservoir - Slide 07.21 - Video timestamp

Available energy w.r.to a variable V and fixed n reservoir - Slide 06.19 - Video timestamp

Available energy w.r.to a variable V and fixed n reservoir - Slide 07.17 - Video timestamp

Average kinetic energy versus temperature - Slide 03.18 - Video timestamp

Avogadro's number - Slide 13.11 - Video timestamp

Azeotrope - Slide 16.15 - Video timestamp

Balance equations for a continuum of a generic extensive property - Slide 22.06 - Video timestamp

Balance equations for a continuum of a generic extensive property - Slide 22.09 - Video timestamp

Balance equations for a continuum of the main extensive properties - Slide 23.04 - Video timestamp

Balance equations for a continuum one-dimensional heat and mass transfer - Slide 22.05 - Video timestamp

Balance equations for a continuum Reynolds theorem - Slide 22.09 - Video timestamp

Balancing the stoichiometric coefficients - Slide 18.09 - Video timestamp

Baricentric velocity - Slide 22.08 - Video timestamp

Baricentric velocity - Slide 22.11 - Video timestamp