Table of Contents

Central Forces

The Central Forces Paradigm presents, in sequence, a classical and quantum mechanical treatment of the problem of two bodies moving under the influence of a mutual central force. The course begins with identifying this central force problem and reformulating the two-body problem in terms of a reduced mass. The classical part of this course asks the students to consider planetary orbits, emphasizing the use of energy and angular momentum conservation and an analysis of the effective potential. The quantum portion of course asks the students to find the analytic solution of the unperturbed hydrogen atom, which also includes an effective potential. This solution is built from simpler examples (a particle confined to a ring and a particle confined to a spherical shell) that introduce students to the relevant special functions needed for the full hydrogen atom solution.

The course also uses the paradigmatic example of a central force to introduce students to techniques for dealing with coupled differential equations, in particular breaking up a problem in several dimensions into problems involving one dimension at a time. In the classical part of the course, students use conserved quantities to break up a vector-valued ordinary differential equation into its spherical coordinate components. In the quantum part of the course, students use separation of variables to break the partial differential equation (Schrodinger's equation) up into single-coordinate eigenvalue equations.

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Student Learning Outcomes

At the end of the course, students will be able to:

Textbook: Quantum Mechanics: A Paradigms Approach—-a textbook that follows the paradigms approach. The chapters that are relevant to the Central Forces course are: Ch 7: Angular Momentum and Ch 8:Hydrogen Atom

Sample Syllabus: Winter 2008

Course Contents

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Unit: Math Bits - Power Series Solutions to ODEs

Hour 1: Math Bits - Series Solutions
  • Summation Notation and Derivatives
  • Solving a Differential Equation with Power Series
Hour 2: Math Bits - Change of Variables
  • Changing Independent Variables
  • Changing Dependent Variables
  • Optional: Solving the Hermite Equation
Hour 3: Math Bits - Legendre's Equation
  • Solving Legendre's Equation
  • Introduction to Special Functions

Unit: Classical Central Forces

Hour 4: Systems of Particles
  • Center of Mass
    • Kinesthetic Activity: Survivor Outer Space
  • Reduced Mass
Hour 5: Classical Angular Momentum
  • Introduction to Angular Momentum
    • Small Whiteboard Activity: Air Table
Hour 6: Kinematics in Polar Coordinates
  • Polar Coordinates
  • Vectors

    • Small Group Activity: Velocity and Acceleration in Polar Coordinates FIXME Add this activity

  • Kepler's Second Law FIXME CAM added the next two bullets
  • Angular Momentum and Kinetic Energy in Polar Coordinates
Hour 7: Conic Sections and Kepler's First Law
  • Conic Sections
    • Mathematica Activity: Plotting Conic Sections FIXME CAM moved this activity
  • Equations of Motion
Hour 8: Energy and Angular Momentum Conservation
  • QUIZ
  • Conservation and Orbital Shape
Hours 9-10: Effective Potentials & Orbital Motion
  • Effective Potentials
    • Kinesthetic Activity: Interpreting Effective Potential Plots
  • Trajectories
Hours 11-12: Scattering
  • What Is Scattering?
  • Cross-section Geometry
  • Differential Cross Sections
    • Small Group Activity: Hard Sphere

Unit: Quantum Central Forces in One Dimension (The Ring Problem)

Hour 13: Separation of Variables in Spherical Coordinates
  • Review of Hamiltonians
  • Separation of Variables
Hours 14-15: QM States on a Ring
  • QUIZ
  • Energy Eigenstates for the Ring
  • Angular Momentum for the Ring
    • Small Group Activity: The Ring
Hour 16: Time Dependence on a Ring
  • Energy Eigenstates, Superpositions, and Time Dependence
    • Mathematica Activity: Visualizing Time Dependence

Unit: Math Bits - Boundary Value Problems

Hours 17-18: Math Bits - Particle in a 2-D Box
  • PDE Solution with 2 Space and 1 Time Variables
  • Applying Boundary Conditions to PDE Solutions
    • Small Group Activity: Infinite Square Well Squared
  • Degenerate Solutions to PDEs
Hours 19-20: Math Bits - Legendre Polynomials
  • Properties of Legendre Polynomials
    • Mathematica Activity: Legendre Polynomial Expansions
  • Finding Legendre Series Coefficients

Unit: The Quantum Rigid Rotor

Hour 21: QM Rigid Rotor Intro, Associated Legendre Polynomials
  • FIXME This topic needs more content
Hour 22: Holiday
Hour 23: Spherical Harmonics
  • Spherical Harmonics
    • Kinesthetic Activity : Visualizing Spherical Harmonics
Hour 24-25: QM States for Rigid Rotor
  • Spherical Harmonic Series
    • Mathematica Activity : Plotting Spherical Harmonic Superpositions
Hour 26: Time Dependence for Rigid Rotor
  • FIXME This topic needs new activities
Hour 27: Angular Momentum Commutation Relations
  • Review of Commutation
  • Angular Momentum Operators
Hour 28: Raising and Lowering Operators

Unit: The Hydrogen Atom

Hour 29: The Radial Equation
  • QUIZ
  • Solving the Radial Wave Function
    • Mathematica Activity: Visualizing Radial Wave Functions
Hours 30-31: The Hydrogen Atom
  • The Full Solution
    • Mathematica Activity: Visualizing Probability Density
  • Quantum Calculations
Hour 32: The Classical Limit
  • FIXME This topic needs more content
Hours 33-34: Applications of Hydrogen Atom States
  • Where Is the Electron?
  • FIXME This topic needs more content
Hour 35: Review

Activities Included