? Credit Points : 20  ? SCQF Level : 8  ? Acronym : PHY-2-B

This course provides an introduction to the tools, concepts and phenomena associated with the physics of the microscopic world. The course incorporates an introductory module on experimental physics; it is supported by a programme of tutorial workshops.

? Pre-requisites : Prior attendance at Physics 2A: Forces, Fields & Potentials (PHY-2-A).

Home subject area

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

? Normal year taken : 2nd year

? Delivery Period : Semester 2 (Blocks 3-4)

? Contact Teaching Time : 8 hour(s) per week for 11 weeks

First Class Information

Date Start End Room Area Additional Information 07/01/2008 09:00 10:00 Lecture Theatre A, JCMB KB

All of the following classes

Type Day Start End Area Lecture Monday 09:00 09:50 KB Lecture Tuesday 09:00 09:50 KB Lecture Thursday 09:00 09:50 KB Lecture Friday 09:00 09:50 KB

1 of the following 4 classes

Type Day Start End Area Laboratory Mo 14:00 17:00 KB Laboratory Tu 14:00 17:00 KB Laboratory Th 14:00 17:00 KB Laboratory Fr 14:00 17:00 KB

? Additional Class Information : Tutorial workshops two hours per week, as arranged. Laboratory sessions three hours per week, as arranged.

At the end of the Experimental Physics unit you should:
1) have learned how to keep a lab notebook
2) be able to combine errors in individual measurements
3) be able to fit a straight line to experimental data using least-squares methods & hence obtain the gradient, y-axis intercept & their uncertainties
4) have learned how to write up your experimental work as a scientific report

At the end of this course of lectures you should:
5) be able to write down the wave equation for waves with constant velocity and apply it to different types of waves.
6) understand the dynamics of sound waves, electromagnetic waves, and mechanical waves in a variety of media
7) understand the concepts of reflection, interference, diffraction, phase and group velocity and energy transport by a wave
8) be familiar with the failures of classical physics & how they relate to the early motivation for quantum theory
9) be able to state and appreciate the consequences of the key paradigm-shifting notions of early quantum theory such as the deBroglie Hypothesis & the Heisenberg Uncertainty Principle
10) be able to discuss the early models of atomic structure & their relation to optical spectra
11) be able to write down the time-dependent & - independent Schrodinger wave eqn & state why the latter has the structure of an eigenvalue eqn
12) be able to apply formal wave mechanics (through the Schrodinger eqn) to a range of fundamental problems concerning scattering & bound states
13) be familiar with the gaseous, liquid & solid phases of matter.
14) appreciate the universality of the Maxwell-Boltzmann distribution for systems in thermal equilibrium
15) understand how quantities such as latent heat, critical temperature, surface tension, compressibility, elasticity & thermal expansion can be related to the parameters of the inter atomic/molecular potential
16) understand the zeroth & first laws of thermodynamics & the concepts of internal energy, heat & work

Weekly assignments, 15%
Experimental laboratory, 15%
Degree Examination, 70%

Exam times

Diet Diet Month Paper Code Paper Name Length 1ST May 1 - 2 hour(s) 2ND August 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 Malcolm McMahon
Tel : (0131 6)50 5956
Email : M.I.McMahon@ed.ac.uk

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

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