Degree | Type | Year | Semester |
---|---|---|---|
2500097 Physics | OB | 3 | A |
You can check it through this link. To consult the language you will need to enter the CODE of the subject. Please note that this information is provisional until 30 November 2023.
Some course of introduction to thermodynamics is preferred
1. To understand the conditions of a thermodynamical systems
2. To identify system and environment
3. Distinguish between state variables and process variables
4. To interpret the different kinds of thermal processes
5. To understand the concept of the thermodynamical limit
6. To derive the partition function of a system and find the state equations from it
7. To apply the energy equipartition theorem
8. To distinguish between reversible and irreversible processes
9. To change the fundamental equation of representation
10.To understand the microscopic concept of pressure of a gas
11. Interpret the stability criteria and relate them with the onset of phase ransitions
12. To analyze the first and second order phase transitions. Understand the Landau theory for phase transitions
13. To construct the Ising model. Apply the mean field approximation, the interactions between nearest neighbours and the method of transfer matrix
14. To distinguish between ideal and real gases. Connect the intermolecular potential with the virial expansion
15. To understand the processes of cooling gases
16. To interpret the electromagnetic radiation as a gas of bosons and obtain the equations of state
17. Make use of the grancanonical ensable to study the fluctuations in the number of particles and the phase equilibrium
1. Formal structure of thermodynamics
1.0. Review of the laws of thermodynamics
1.1. The fundamental equation
1.2. Euler's form of internal energy. Gibbs-Duhem equation
1.3. Transformed by Legendre. Thermodynamic potentials
1.4. Maxwell relations for a fluid
1.5. Stability conditions
2. Microscopic description of macroscopic systems
2.1. Microstats and Macrostats. Phase space
2.2. Ensembles
2.3. Microcanonical ensemble
2.4 Thermodynamic-Statistical Mechanical Connection
2.5. Application to the ideal monoatomic gas
2.6. Discrete systems
2.7. Statistical entropy
2.8. Maxwell-Boltzmann distribution
2.9. Pressure
2.10. Effusion
3. Canonical ensemble
3.1. Partition function.
3.2. Ideal systems
3.3. Energy degeneration
3.4. The ideal monoatomic gas in a potential
3.5. Equipartition of energy theorem
3.6. Discrete systems
4. Magnetic systems
4.1. Thermodynamics of magnetic systems
4.2. Classical paramagnetism
4.3. Spin Paramagnetism 1/2. Microcanonical and canonical treatments
4.4. Adiabatic demagnetization
5. Phase transitions
5.1. Classification. P-V, P-µ and P-T diagrams. Clapeyron equation
5.2. Vapor-condensed phase equilibrium
5.3. The critical point
5.4. Ehrenfest classification of phase transitions
5.5. Second order phase transitions.
6. Ising model
6.1. One-dimensional chain
6.2. One-dimensional open chain
6.3. Meanfield approximation
7. Real gases
7.1. Compressibility factor. Virial expansion
7.2. Interaction potential. Configuration partition function
7.3. Second coefficient of the virial. Van der Waals equation
7.4. Reticular gas
7.5. Corresponding State Law
7.6. Joule and Joule-Kelvin expansions
8. Photons
8.1. Statistics of bosons and fermions
8.2 Energy density. Degeneration of states
8.3. Planck distribution
8.4. Equations of state of a photon gas
9. Macrocanonical collectivity
9.1. Partition function
9.2. Connection with thermodynamics
9.3. Discrete systems
9.4. Fluctuations
9.5. Ideal systems. The ideal monoatomic gas
9.6. Solid-vapor equilibrium
METHODOLOGY
Classroom activities
1 Teaching lectures
The lectures will be taught by the theory teacher where the concepts, developments and basic principles of the subject will be presented.
2 Teaching Problems
The problem's teacher will solve in class some of the problems of the collection that previously the student will have had to try to solve. We will try to make use of dynamical discussions of alternative results.
3 Tutorial activities
In case of virtual teaching along the seasons of tutorial activites questions of theory and practical will be solved in class
Authonomous activities
1 Troubleshooting
The teacher of problems will deliver (will also be posted on the virtual campus) a list of problems and computer practices that each student must solve individually and deliver it on the established date
2 Study
We have counted that the student must dedicate 2 hours of study for each hour of master class.
SURVEYS
It is planned to leave 15 minutes at the end of class when the institutional surveys need to be answered
Annotation: Within the schedule set by the centre or degree programme, 15 minutes of one class will be reserved for students to evaluate their lecturers and their courses or modules through questionnaires.
Title | Hours | ECTS | Learning Outcomes |
---|---|---|---|
Type: Directed | |||
Problems | 30 | 1.2 | |
Teaching lectures | 45 | 1.8 | |
Type: Autonomous | |||
Problems solving | 49 | 1.96 | |
Study | 92 | 3.68 |
Partial exams and final exam
There will be two partial exams. The first one will evaluate the first part of the course while the second will evaluate the rest. in case the mean of the qualifications is less than 4 the student must do the final exam. To be examined in the final exam is compulsery to be examend in the first and second partial exams.
Remedial exam
Those who have been evaluated in the partial exams obtaining a qualification lower than 4 (compulsory) or those who want to improve their marks (optional) may do the remedial exam. In the latter case, the final mark will be the best of the marks obtained from the remidial and partials examams
Homework
The homowork problems will be evaluated and their solutions will be published at the virtual campus. This part cannot be remedied
Final mark
The finals mark will be calculated from the specific weights only if the student has passed the partials or the final exam. The final mark will be the 70% of the fianl exam/mean of partials plus the 30% of the homework if the final exam mark is equal or higher than 4. Otherwise, the studend does not pass
Unique assessment
Students who have accepted the single assessment modality will have to take a final test which will consist of a problem-based exam. When the student has finished, he/she will hand in the assignments corresponding to the first semester and the simulation work of the second semester which will be published on the virtual campus and which will be the same as for the rest of the students.
These tests will take place on the same day, time and place as the tests of the second part of the continuous assessment modality.
The final grade will be 70% of the test plus 30% of the delivered problems including the simulation work if the final exam grade is greater than or equal to 4.0. If the grade of the test is lower than 4.0 or if the final grade previously calculated does not reach 5, the student has another opportunity to pass the subject through the make-up exam that will be held on the date set by the coordination of the degree. The final grade will be calculated again as before, i.e. if the retake exam grade is greater than or equal to 4.0 then the final grade will be 70% of the test plus 30% of the delivered problems including the work of simulation
Title | Weighting | Hours | ECTS | Learning Outcomes |
---|---|---|---|---|
Final exam | 70% | 3 | 0.12 | 1, 2, 3, 5, 4, 8, 7, 9, 10, 11, 12, 13, 15, 6, 18, 16, 17 |
First part exam | 35% | 3 | 0.12 | 3, 4, 8, 7, 9, 11, 12, 13, 15, 6, 16 |
Homework | 30% | 0 | 0 | 14, 18 |
Second part exam | 35% | 3 | 0.12 | 1, 2, 5, 10, 11 |
Modern texts
Classical texts
We shall make use of Python for the simulations activities along the second semester