? Credit Points : 10  ? SCQF Level : 9  ? Acronym : PHY-3-VThermo

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 the course.

? This course is only available to part year visiting students.

? This course is a variant of the following course : U01359

? Pre-requisites : Year 2 Physics and Mathematics.

Home subject area

Undergraduate (School of Physics and Astronomy), (School of Physics and Astronomy, Schedule Q)

? Normal year taken : 3rd year

? Delivery Period : Semester 1 (Blocks 1-2)

? Contact Teaching Time : 3 hour(s) per week for 11 weeks

First Class Information

Date Start End Room Area Additional Information 22/09/2008 10:00 11:00 Lecture Theatre C, JCMB KB

All of the following classes

Type Day Start End Area Lecture Monday 10:00 10:50 KB Lecture Thursday 10:00 10:50 KB

? Additional Class Information : Workshop/tutorial sessions, as arranged.

Upon successful completion of this course it is intended that a student will be able to:
1)State the Zeroth, First, Second and Third Laws of thermodynamics, if appropriate in different but equivalent forms and demonstrate their equivalence
2)Understand all the concepts needed to state the laws of thermodynamics, such as 'thermodynamic equilibrium', 'exact' and 'inexact' differentials and 'reversible' and 'irreversible' processes
3)Use the laws of thermodynamics (particularly the first and second laws) to solve a variety of problems, such as the expansion of gases and the efficiency of heat engines
4)Understand the meaning and significance of state variables in general, and of the variables P; V; T;U; S in particular, especially in the context of a simple fluid, and to manipulate these variables to solve a variety of thermodynamic problems
5)Define the enthalpy H, Helmholtz function F and the Gibbs function G and state their roles in determining equilibrium under different constraints
6)Manipulate (using suitable results from the theory of functions of many variables) a variety of thermodynamic derivatives, including a number of 'material properties' such as heat capacity, thermal expansivity and compressibility, and solve problems in which such derivatives appear
7)Sketch the phase diagram of a simple substance in various representations and understand the concept of an 'equation of state' (as exemplified by the van der Waals' equation for a fluid) and the basic thermodynamics of phase transitions
8)Demonstrate a grasp of the orders of magnitudes of the various central quantities involved

Coursework, 20%
Degree Examination, 80%

Exam times

Diet Diet Month Paper Code Paper Name Length 1ST December 1 - 2 hour(s)

The Course Secretary should be the first point of contact for all enquiries.

Course Secretary

Mrs Linda Grieve
Tel : (0131 6)50 5254
Email : linda.grieve@ed.ac.uk

Course Organiser

Prof Andrew Huxley
Tel : (0131 6)51 7053
Email : a.huxley@ed.ac.uk

School Website : http://www.ph.ed.ac.uk/

College Website : http://www.scieng.ed.ac.uk/