| Sl.No | Chapter Name | MP4 Download |
|---|---|---|
| 1 | Lecture 1 : Rate: the reaction velocity | Download |
| 2 | Lecture 2 : Its elementary - rate law equations | Download |
| 3 | Lecture 3 : Arrhenius equation: what's the fuss about? | Download |
| 4 | Lecture 4 : Dance of atoms: from Newton to Hamilton | Download |
| 5 | Lecture 5 : Boltzmann distribution: a story of Hamilton, Liouville and Boltzmann | Download |
| 6 | Lecture 6 : Maxwell Boltzmann distribution: how fast are molecules moving? | Download |
| 7 | Lecture 7 : Kinetic theory of collisions: initial estimate | Download |
| 8 | Lecture 8 : Boltzmann distribution and kinetic theory of collisions | Download |
| 9 | Lecture 9 : Kinetic theory of collisions: a discussion | Download |
| 10 | Lecture 10 : Kinetic theory of collisions: reactive cross section | Download |
| 11 | Lecture 11 : Problem solving session 1 | Download |
| 12 | Lecture 12 : Problem solving session 2 | Download |
| 13 | Lecture 13 : Kinetic theory of collision and equilibrium constant | Download |
| 14 | Lecture 14 : Critique of kinetic theory of collisions | Download |
| 15 | Lecture 15 : Transition state theory and partition functions | Download |
| 16 | Lecture 16 : Partitioning the partition function | Download |
| 17 | Lecture 17 : Translating, rotating and vibrating quantum mechanically | Download |
| 18 | Lecture 18 : Partition function and equilibrium constant | Download |
| 19 | Lecture 19 : What is a transition state? | Download |
| 20 | Lecture 20 : A puzzle: cars on highway | Download |
| 21 | Lecture 21 : Transition state theory: derivation 1 | Download |
| 22 | Lecture 22 : Practical calculation of TST rate | Download |
| 23 | Lecture 23 : Calculating TST rate for the reaction H+HBr | Download |
| 24 | Lecture 24 : Collision theory as a special case of TST | Download |
| 25 | Lecture 25 : TST: an intuitive proof in one dimension | Download |
| 26 | Lecture 26 : Rate as a flux across a dividing surface | Download |
| 27 | Lecture 27 : Transition state theory: derivation 2 from dynamical perspective | Download |
| 28 | Lecture 28 : Discussion of the assumptions of TST | Download |
| 29 | Lecture 29 : Thermodynamic formulation of TST | Download |
| 30 | Lecture 30 : Problem solving session 3 | Download |
| 31 | Lecture 31 : Problem solving session 4 | Download |
| 32 | Lecture 32 : Hills and valleys of potential energy surfaces | Download |
| 33 | Lecture 33 : Molecular dynamics: rolling spheres on potential energy surfaces | Download |
| 34 | Lecture 34 : Predictions from potential energy surfaces - rotational vs vibrational energies | Download |
| 35 | Lecture 35 : Free energy and potential of mean force | Download |
| 36 | Lecture 36 : Transmission coefficient and molecualr dynamics | Download |
| 37 | Lecture 37 : Problem solving session 5 | Download |
| 38 | Lecture 38 : Microcanonical rate constant: putting balls in jars | Download |
| 39 | Lecture 39 : Microcanonical rate constant: RRK model | Download |
| 40 | Lecture 40 : Microcanonical rate constant: magic of Marcus - RRKM model | Download |
| 41 | Lecture 41 : Canonical TST from micrononical RRKM model | Download |
| 42 | Lecture 42 : Sum and density of states | Download |
| 43 | Lecture 43 : Unimolecular decay - revisited | Download |
| 44 | Lecture 44 : Unimolecular decay: RRK's approach | Download |
| 45 | Lecture 45 : Unimolecular decay: RRKM's approach | Download |
| 46 | Lecture 46 : Problem solving session 6 | Download |
| Sl.No | Chapter Name | English |
|---|---|---|
| 1 | Lecture 1 : Rate: the reaction velocity | Download Verified |
| 2 | Lecture 2 : Its elementary - rate law equations | Download Verified |
| 3 | Lecture 3 : Arrhenius equation: what's the fuss about? | Download Verified |
| 4 | Lecture 4 : Dance of atoms: from Newton to Hamilton | Download Verified |
| 5 | Lecture 5 : Boltzmann distribution: a story of Hamilton, Liouville and Boltzmann | Download Verified |
| 6 | Lecture 6 : Maxwell Boltzmann distribution: how fast are molecules moving? | Download Verified |
| 7 | Lecture 7 : Kinetic theory of collisions: initial estimate | Download To be verified |
| 8 | Lecture 8 : Boltzmann distribution and kinetic theory of collisions | Download To be verified |
| 9 | Lecture 9 : Kinetic theory of collisions: a discussion | Download To be verified |
| 10 | Lecture 10 : Kinetic theory of collisions: reactive cross section | Download To be verified |
| 11 | Lecture 11 : Problem solving session 1 | Download To be verified |
| 12 | Lecture 12 : Problem solving session 2 | Download To be verified |
| 13 | Lecture 13 : Kinetic theory of collision and equilibrium constant | Download To be verified |
| 14 | Lecture 14 : Critique of kinetic theory of collisions | Download To be verified |
| 15 | Lecture 15 : Transition state theory and partition functions | Download To be verified |
| 16 | Lecture 16 : Partitioning the partition function | Download To be verified |
| 17 | Lecture 17 : Translating, rotating and vibrating quantum mechanically | Download To be verified |
| 18 | Lecture 18 : Partition function and equilibrium constant | Download To be verified |
| 19 | Lecture 19 : What is a transition state? | Download To be verified |
| 20 | Lecture 20 : A puzzle: cars on highway | Download To be verified |
| 21 | Lecture 21 : Transition state theory: derivation 1 | Download To be verified |
| 22 | Lecture 22 : Practical calculation of TST rate | Download To be verified |
| 23 | Lecture 23 : Calculating TST rate for the reaction H+HBr | Download To be verified |
| 24 | Lecture 24 : Collision theory as a special case of TST | Download To be verified |
| 25 | Lecture 25 : TST: an intuitive proof in one dimension | Download To be verified |
| 26 | Lecture 26 : Rate as a flux across a dividing surface | PDF unavailable |
| 27 | Lecture 27 : Transition state theory: derivation 2 from dynamical perspective | PDF unavailable |
| 28 | Lecture 28 : Discussion of the assumptions of TST | PDF unavailable |
| 29 | Lecture 29 : Thermodynamic formulation of TST | PDF unavailable |
| 30 | Lecture 30 : Problem solving session 3 | PDF unavailable |
| 31 | Lecture 31 : Problem solving session 4 | PDF unavailable |
| 32 | Lecture 32 : Hills and valleys of potential energy surfaces | PDF unavailable |
| 33 | Lecture 33 : Molecular dynamics: rolling spheres on potential energy surfaces | PDF unavailable |
| 34 | Lecture 34 : Predictions from potential energy surfaces - rotational vs vibrational energies | PDF unavailable |
| 35 | Lecture 35 : Free energy and potential of mean force | PDF unavailable |
| 36 | Lecture 36 : Transmission coefficient and molecualr dynamics | PDF unavailable |
| 37 | Lecture 37 : Problem solving session 5 | PDF unavailable |
| 38 | Lecture 38 : Microcanonical rate constant: putting balls in jars | PDF unavailable |
| 39 | Lecture 39 : Microcanonical rate constant: RRK model | PDF unavailable |
| 40 | Lecture 40 : Microcanonical rate constant: magic of Marcus - RRKM model | PDF unavailable |
| 41 | Lecture 41 : Canonical TST from micrononical RRKM model | PDF unavailable |
| 42 | Lecture 42 : Sum and density of states | PDF unavailable |
| 43 | Lecture 43 : Unimolecular decay - revisited | PDF unavailable |
| 44 | Lecture 44 : Unimolecular decay: RRK's approach | PDF unavailable |
| 45 | Lecture 45 : Unimolecular decay: RRKM's approach | PDF unavailable |
| 46 | Lecture 46 : Problem solving session 6 | PDF unavailable |
| Sl.No | Language | Book link |
|---|---|---|
| 1 | English | Not Available |
| 2 | Bengali | Not Available |
| 3 | Gujarati | Not Available |
| 4 | Hindi | Not Available |
| 5 | Kannada | Not Available |
| 6 | Malayalam | Not Available |
| 7 | Marathi | Not Available |
| 8 | Tamil | Not Available |
| 9 | Telugu | Not Available |