THE UNIVERSITY of EDINBURGH

DEGREE REGULATIONS & PROGRAMMES OF STUDY 2015/2016

University Homepage
DRPS Homepage
DRPS Search
DRPS Contact
DRPS : Course Catalogue : School of Physics and Astronomy : Undergraduate (School of Physics and Astronomy)

Undergraduate Course: Thermal Physics (PHYS09061)

Course Outline
SchoolSchool of Physics and Astronomy CollegeCollege of Science and Engineering
Credit level (Normal year taken)SCQF Level 9 (Year 3 Undergraduate) AvailabilityAvailable to all students
SCQF Credits20 ECTS Credits10
SummaryThis two-semester course covers thermal physics, the first semester contains an introduction to equilibrium thermodynamics. The First and Second laws of thermodynamics are introduced, along with the concepts of temperature, internal energy, heat, entropy and the thermodynamic potentials. Applications of thermodynamic concepts to topics such as heat engines, the expansion of gases and changes of phase are considered. The Third Law, and associated properties of entropy, complete this section.

The second semester provides an introduction to the microscopic formulation of thermal physics, generally known as statistical mechanics. We explore the general principles, from which emerge an understanding of the microscopic significance of entropy and temperature. We develop the machinery needed to form a practical tool linking microscopic models of many-particle systems with measurable quantities. We consider a range of applications to simple models of crystalline solids, classical gases, quantum gases and blackbody radiation.
Course description Thermodynamics (semester 1):
- Thermal equilibrium; equations of state and thermodynamic stability; PV diagrams; temperature scales.
- First law: heat and work; reversible and irreversible processes; heat capacities.
- Thermodynamic processes: reversible expansions (isothermal, adiabatic); irreversible expansions (Joule, Joule-Kelvin); illustration with ideal and van der Waals gases.
- Second law: entropy from a thermodynamic perspective (Clausius, Kelvin-Planck definitions).
- Cyclic processes: Carnot cycle, maximum efficiency.
- Thermodynamic potentials; Legendre transformations; Maxwell relations; applications to various thermodynamic processes.
- Introduction to Black Body radiation (treated more fully in Statistical Mechanics).
- Thermodynamic approach to phase transitions; van der Waals as example; continuous and discontinous transitions; critical point.
- Third law.
- Chemical potential and open systems.
- Superconductivity and superfluidity as concepts.

Statistical Mechanics (semester 2):
- Statistical description of many-body systems; formulation as a probability distribution over microstates; central limit theorem and macrostates.
- Statistical mechanical formulation of entropy.
- Minimisation of the free energy to find equilibrium.
- Derivation of the Boltzmann distribution from principle of equal a priori probabilities in extended system.
- Determination of free energy and macroscopic quantities from partition function; applications to simple systems (paramagnet, ideal gas, etc).
- Multi-particle systems: distinguishable and indistinguishable particles in a classical treatment; Entropy of mixing and the Gibbs paradox.
- Fermi-Dirac distribution; application to thermal properties of electrons in metals.
- Bose-Einstein distribution; application to the properties of black body radiation; Bose-Einstein condensation.
- Introduction to phase transitions and spontaneous ordering from a statistical mechanical viewpoint: illustration of complexity arising from interactions; simple-minded mean-field treatment of an interacting system (e.g., van der Waals gas, Ising model).
Entry Requirements (not applicable to Visiting Students)
Pre-requisites Students MUST have passed: Physics of Matter (PHYS08054) OR Physics of Fields and Matter (PHYS08046)
Co-requisites
Prohibited Combinations Students MUST NOT also be taking Thermodynamics (PHYS09021) OR Statistical Mechanics (PHYS09019)
Other requirements None
Additional Costs None
Information for Visiting Students
Pre-requisitesNone
High Demand Course? Yes
Course Delivery Information
Academic year 2015/16, Available to all students (SV1) Quota:  None
Course Start Full Year
Timetable Timetable
Learning and Teaching activities (Further Info) Total Hours: 200 ( Lecture Hours 44, Seminar/Tutorial Hours 44, Formative Assessment Hours 3, Revision Session Hours 1, Programme Level Learning and Teaching Hours 4, Directed Learning and Independent Learning Hours 104 )
Assessment (Further Info) Written Exam 80 %, Coursework 20 %, Practical Exam 0 %
Additional Information (Assessment) Coursework 20%
Examination 80%
Feedback Not entered
Exam Information
Exam Diet Paper Name Hours & Minutes
Main Exam Diet S2 (April/May)Thermal Physics (PHYS09061)3:00
Learning Outcomes
On completion of this course, the student will be able to:
  1. Show fluency and confidence in thermodynamics and statistical mechanics, and apply them to various physical systems
  2. Present a solution to a physics problem in a clear and logical written form
  3. Assess whether a solution to a given problem is physically reasonable
  4. Locate and use additional sources of information (to include discussion with peers where appropriate) to facilitate independent problem-solving
  5. Take responsibility for learning by attending lectures and workshops, and completing coursework
Reading List
Finn, Thermal Physics
Additional Information
Course URL www.ph.ed.ac.uk/~gja/thermo/
Graduate Attributes and Skills Not entered
Additional Class Delivery Information 2 lectures per week
1 tutorial (2 hours)
KeywordsThPh
Contacts
Course organiserDr Alexander Morozov
Tel: (0131 6)50 5289
Email:
Course secretaryMrs Siobhan Macinnes
Tel: (0131 6)51 3448
Email:
Navigation
Help & Information
Home
Introduction
Glossary
Search DPTs and Courses
Regulations
Regulations
Degree Programmes
Introduction
Browse DPTs
Courses
Introduction
Humanities and Social Science
Science and Engineering
Medicine and Veterinary Medicine
Other Information
Combined Course Timetable
Prospectuses
Important Information
 
© Copyright 2015 The University of Edinburgh - 21 October 2015 12:53 pm