Module PHYS1122: FOUNDATIONS OF PHYSICS 1

Department: PHYSICS

PHYS1122: FOUNDATIONS OF PHYSICS 1

Prerequisites

• A-Level Physics and A-Level or AS-Level Mathematics.

Corequisites

• Either (MATH1561) Single Mathematics A and (MATH1571) Single Mathematics B or (MATH1012) Core Mathematics A or (MATH1551) Maths for Engineers and Scientists.

Excluded Combination of Modules

• Fundamental Physics A (PHYS1111), Fundamental Physics B (PHYS1131).

Aims

• This module is designed primarily for students studying Department of Physics or Natural Science degree programmes.
• It provides the minimum core physics required for progression to Level 2 physics modules and should be taken by all students intending to study physics beyond Level 1 [with certain exceptions: Fundamental Physics A (PHYS1111) may be substituted for Foundations of Physics 1 (PHYS1122) as one of the pre-requisites for Stars and Galaxies (PHYS2541), Laboratory Skills and Practice (PHYS2251), Electronic and Physics Laboratory (PHYS2561)].
• It provides courses in classical aspects of wave phenomena and electromagnetism, and introduces basic concepts in Newtonian mechanics, quantum mechanics, special relativity, phases of matter, optics, atomic, nuclear and particle physics.
• The module provides students with practice in key mathematical techniques and in the informal discussion of scientific ideas within a small group.

Content

• The syllabus contains:
• Introduction to Classical Mechanics: Velocity, acceleration, Newton's Laws, conservation of momentum and energy, friction, angular motion, centrifugal force, Coriolis force, angular momentum and torques, gyroscopes, central forces, Newton's Law of Gravity, satellite launching, Kepler's Laws, planetary orbits.
• Introduction to Special Relativity: Motion as seen by different observers. Setting up inertial frames of reference. The Michelson-Morley experiment. The universality of the speed of light. Lightning striking twice: the meaning of simultaneity. How time can get longer and lengths shorten, depending on speed. Ageing on the move: the twin paradox. How elementary particles can test these predictions to enormous precision. How co-ordinates for one observer are related to those for another, and how speeds add up. Some things never change: Lorentz invariants. Einstein's famous energy and mass relation, relativistic billiards and collisions: energy and momentum of elementary particles. Looking forward to General Relativity; what happens in accelerating frames?
• Wave Phenomena: Introduction to vibrations. Energy in SHM. Simple harmonic motion of mechanical, electrical and atomic oscillators. Damped harmonic motion. Introduction of the Q value, forced oscillations and resonance. Chaos, period doubling, attractors and the Madelbrot set. Introduction to transverse and longitudinal waves. Analysis of the wave equation. Properties of harmonic waves including sound waves, intensity and loudness. The Doppler effect. Superposition and interference of harmonic waves, including boundary conditions. Interference and beats. Standing waves. Waves in a dispersive medium, phase and group velocities. Pulses in a non-linear medium, Solitons. The nature and properties of light. The speed of light. The propagation of light, Huygens' principle and single slit diffraction and two slit interference. Applications of dispersion: fibre optics, prisms and rainbows.
• Electricity and Magnetism: Electrostatics: Electric charge, Coulomb's law, permittivity of vacuum, E, electric field lines, electric dipoles, continuous charge distributions, Gauss's law, calculation of E using Gauss's law, potential energy, electric potential, E = –grad V, equipotentials, capacitors, dielectrics, electric energy density, circulation of E, electromotive force. Magnetostatics: Currents in conductors, Ohm's law, circulation of E round circuit, electromotive force, B field, force on moving charge/current, Lorentz force, force on a current-carrying coil, magnetic dipole moment, Biot–Savart law, permeability of vacuum, magnetic field patterns due to current loop/bar magnet, Gauss's law for magnetism, magnetic monopoles, circulation of B, Ampere's law, calculation of B for current line, torus, solenoid. Time Variations: Faraday's law, E from dB/dt, induced emf, back emf, motional emf, inductance, magnetic energy density, displacement current, B from dE/dt, Maxwell's equations.
• Introduction to Optics: Reflection and refraction, Snell's Law and refractive index. Ray tracing. Optical systems with one or more lenses. Photography. The limits of imaging. Diffraction and interference. Polarisation.
• Phases of Matter: Atoms: The physical properties of atoms, mass size and density of atoms. Interatomic Interactions: Description of interatomic forces, interatomic potentials, types of bonding. Temperature and Thermodynamics: Relation between thermodynamics and thermal properties of matter, zero and first laws of thermodynamics, kinetic theory of gases. Properties of Gases: Thermal and mechanical properties of gases, equipartition theorem, specific heat capacity, mean free path, thermal conductivity. Properties of Solids: Structure of solids, heat capacity, mechanical proper-ties: compressibility, Young's modulus, tensile strength. Properties of Liquids: Mechanical and thermal properties, viscosity. Properties of Plasmas: Origin of plasmas, properties, influence of plasma on the solar system, applications of plasma. Electronic Properties of Matter: Relation between electrical and other properties, insulators, semiconductors, conductors, superconductivity. Quantum Effects: A look at unusual properties of matter based on quantum mechanics, new materials systems, atom engineering, future developments.
• Atoms, Nuclei and Particles: Structure of matter. Atoms, nuclei, quarks and leptons. The fundamental forces of nature. The Standard Model of particle physics. Rutherford Scattering, Bohr model, Sommerfeld model, Zeeman effect, electron spin, Stern-Gerlach experiment, Periodic Table, Pauli Exclusion Principle. Nuclear shell model, magic numbers, magnetic moments, nuclear magnetic resonance, fission, fusion, alpha-decay, beta-decay and the neutrino.
• Quantum Mechanics: Brief review of classical physics. Outstanding problems: black body radiation, photoelectric effect, stability of atoms. Discovery of Planck's constant. Quantization of energy. Particle nature of radiation. Compton effect. Rutherford model of the atom. Bohr model of the hydrogen atom. its successes and its limitations. Particle-wave dualism. Double slit experiment. quantum mechanical interpretation. Wave nature of matter. Uncertainty principle; worked examples. Schrodinger's non-relativistic wave equation. Separation of variables. Bound state and potential well problems: square wells of infinite and finite depth. The solution of Schroedinger's equation for the simple harmonic oscillator. Reflection and transmission of particle beams by potential steps and barriers. Quantum tunnelling and applications: Theory of alpha radioactivity, scanning tunnelling microscope, age of Sun, etc.

Learning Outcomes

• Students will have gained an introductory knowledge of Newtonian mechanics and applications to basic physical problems familiar from the everyday world, such as movement under constant acceleration, rotating wheels and pulleys and the motion of the planets.
• They will understand the concepts of inertial frames of reference and the universality of the speed of light, and will have a basic understanding of relativistic effects and Lorentz invariants.
• They will have knowledge of the physics of vibrations and waves in many different linear systems and of optical wave phenomena including light propagation, diffraction and interference.
• They will have a firm grounding in the classical aspects of electromagnetism, including the central ideas of electrostatics, magnetostatics and time variations.
• They will understand the fundamental importance of quantum mechanics to modern physics and will be able to perform simple quantum mechanical calculations.
• They will have an understanding of the structure of an atom in terms of a nucleus and electrons and of a nucleus in terms of protons and neutrons.
• They will have knowledge of the parameters used to describe atoms and nuclei, an ability to explain their properties in terms of simple physical models, and an appreciation of the applications of nuclear physics.
• They will have knowledge of the contemporary picture of elementary particle physics and the characteristics of the four fundamental interactions.
• They will be familiar with the nature and basic properties of solids, liquids, gases, and plasmas and with simple microscopic models to describe the behaviour of the different phases of matter.
• They will have knowledge of the principles that describe the propagation of light in free space, dielectric materials, and lens/mirror systems, will be familiar with the concepts of diffraction, polariasation and interference, and will have the ability to carry out calculations to determine thr properties of simple optical systems.

• In addition to the acquisition of subject knowledge, students will have developed problem-solving skills requiring the application of mathematical techniques and the basic principles of physics.
• They will know how to produce a well-structured solution, with clearly-explained reasoning and appropriate presentation.

Modes of Teaching, Learning and Assessment and how these contribute to the learning outcomes of the module

• Teaching will be lectures, supported by tutorials and mathematical skills workshops.
• The lectures will provide the means to give a concise, focused presentation of the subject matter of the module.
• The lecture material will be explicitly linked to the contents of a single recommended textbook for the module, thus making clear where students can begin their private study.
• When appropriate, the lectures will also be supported by the distribution of written material, or by information and relevant links on DUO.
• Students will be able to obtain further help in their studies by approaching their lecturers, either after lectures or at other mutually convenient times (the Department has a policy of encouraging such enquiries).
• The mathematics skills workshops will improve students' knowledge of key mathematical topics and techniques used in physics.
• Regular problem exercises will give students the chance to develop their theoretical understanding and problem-solving abilities.
• These problem exercises will form the basis for discussions in tutorial groups of typically six to eight students.
• The tutorials will also provide an informal environment for students to raise issues of interest or difficulty.
• Student performance will be summatively assessed through written examinations and problem exercises.
• The written examinations and problem exercises will provide the means for students to demonstrate their acquisition of subject knowledge and the development of their problem-solving skills.
• The problem exercises will also provide opportunities for feedback, for students to gauge their progress, and for staff to monitor progress throughout the duration of the module.

Teaching Methods and Learning Hours

Summative Assessment

Formative Assessment:

One 3-hour Collection Examination.

■ Attendance at all activities marked with this symbol will be monitored. Students who fail to attend these activities, or to complete the summative or formative assessment specified above, will be subject to the procedures defined in the University's General Regulation V, and may be required to leave the University