The Quantum Exchange Library Materials

Total Materials: 241

• 1D Quantum States Applet
• 1D Quantum Transitions Applet
• 2D Circular Square Well Applet
• 2D Quantum Harmonic Oscillator Applet
• 2D Rectangular Square Well Applet
• 3D Quantum Harmonic Oscillator Applet
• 3Ms for Instruction: Reviews of Maple, Mathematica, and Matlab
• 5 1/2 Examples in Quantum Mechanics
• A computer-simulated Stern–Gerlach laboratory
• A Modern Approach to Quantum Mechanics
• A New Model Course in Applied Quantum Physics
• A New Model Course in Applied Quantum Physics: Examination Questions
• A Practical Guide to SPM: Scanning Probe Microscopy
• A Quantum Bouncing Ball
• A Radically Modern Approach to Introductory Physics
• AAPT New Faculty Workshop
• Advanced Visual Quantum Mechanics
• Aharonov-Bohm Effect
• An Introduction to the Basics of Dephasing
• An Open Source XML Framework for Authoring Curricular Material
• Applying Spectra and Energy Diagrams to Learn About Stars
• Atomic Dipole Transitions Applet
• Atomic Orbitals
• Band Structure - An Electron Lattice Example
• Central Force Motion Example: Hydrogen Atom
• Centre for Quantum Computation
• Circular Well Superposition Model
• Classical and Quantum Mechanical Waves
• Clebsch-o-matic
• Collaboration Bohmian Mechanics
• Complex Numbers
• Configuration Interaction and Coupled Cluster methods
• Creating an Energy Level to Model LEDs
• Delta Function Potential Example
• Determining Plank's Constant with LEDs
• Developing and Researching PhET simulations for Teaching Quantum Mechanics
• Diode Laser
• Discrete Energy Levels in Bound States: Numerical Solutions
• Double Slit Diffraction
• Dynamics of Student Modeling: A Theory, Algorithms, and Application to Quantum Mechanics
• Eigenstate Superposition Model
• Electrons in a 2D lattice: Energy contours and density of states
• Encyclopedia of Laser Physics and Technology
• Energy Band Creator
• Energy Diagram Explorer
• Essay Assignment System
• Everett's Relative-State Formulation of Quantum Mechanics
• Faculty Disagreement about the Teaching of Quantum Mechanics
• Falling - A Constant Force Example
• Fermi Surface Database
• Fluorescence Spectroscopy
• From Cbits to Qbits: Teaching computer scientists quantum mechanics
• From Einstein to Quantum Information
• Gas Lamp Absorption
• Gas Lamp Emission
• Graduate Quantum Mechanics Reform
• Helium Neon Laser
• How does Quantum Mechanics turn into Classical Mechanics?
• Hydrogen Atom Applet
• Hydrogen Spectroscopy
• Hydrogen Spectroscopy II
• HydrogenLab - Pictures of the Hydrogen Atom
• IBM Scientists Make Breakthrough in Nanoscale Imaging
• Identical Particles
• Illinois PER: Materials Used in Our Introductory Courses
• Infrared Detector Spectroscopy
• Infrared Detector: Card Model
• Institute for Quantum Information
• Interactive Quantum Mechanics Exercises for Just-in-Time Teaching
• Interference
• Interference with correlated photons: Five quantum mechanics experiments for undergraduates
• International Journal of Quantum Information
• Interpreting Wave Functions
• Introduction to PET Physics
• Introduction to Quantum Computing
• Introduction to Quantum Mechanics
• Introductory Quantum Mechanics
• Intuitive Quantum Physics
• Investigating Student Understanding of Quantum Physics: Spontaneous Models of Conductivity
• Investigation of Student Understanding of the Wave-Like Properties of Light and Matter
• KSU Virtual Quantum Mechanics: Single Slit Diffraction
• Laboratory-tutorial activities for teaching probability
• Laser Adventure
• Lectures on Quantum Computation
• LED Constructor
• LED Spectroscopy
• Light and Waves
• Magnetic Resonance of Spin One-Half Particles Model
• Maple, Mathematica, and Matlab: the 3M's without the Tape
• Matter Waves
• Modeling Light Emission by Fluorescent Lamps
• Modeling Light Emission to Explain Phosphorescence
• Models of dephasing at low temperatures
• Modern Physics Resource Packet
• Modern Undergraduate Quantum Mechanics Experiments
• Molecular Orbital Viewer
• Motion in a Potential
• Multiple Slit Diffraction Model
• Nanohub
• NARST 1999: Research on Teaching and Learning Quantum Mechanics
• Nine formulations of Quantum Mechanics
• Nine Formulations of Quantum Mechanics: Lecture
• Numerical Time Development in Quantum Mechanics Using a Reduced Hilbert Space Approach
• Observing the quantum behavior of light in an undergraduate laboratory
• On the Study of Student Use of Meta-Resources in Learning Quantum Mechanics
• Open Source and Open Access Resources for Quantum Physics Education
• Open Source Physics
• OSP Quantum Mechanics Worksheet: Measurement of Energy Eignestates
• OSP Quantum Mechanics Worksheet: Measurement of Two-State Superpositions
• OSP Quantum Mechanics Worksheet: Measurement of Wave Packets
• OSP QuILT Package
• OSP-based Programs for Quantum Mechanics: Time Evolution and ISW Revivals
• OSP: Quantum-mechanical Measurement
• Paradigms in Physics Quantum: Projection Operators
• Paradigms in Physics: Quantum Activities
• PET Essentials E-training
• Ph 125 Quantum Mechanics
• PH425: Spin and Quantum Measurement
• Phase Matters Package
• PhET Simulation: Band Structure
• PhET Simulation: Davisson-Germer: Electron Diffraction
• PhET Simulation: Double Wells and Covalent Bonds
• PhET Simulation: Fourier: Making Waves
• PhET Simulation: Lasers
• PhET Simulation: Neon Lights and Other Discharge Lamps
• PhET Simulation: Nuclear Fission
• PhET Simulation: Quantum Bound States
• PhET Simulation: Quantum Tunneling and Wave Packets
• PhET Simulation: Quantum Wave Interference
• PhET Simulation: Semiconductors
• PhET Simulation: The Photoelectric Effect
• PhET Simulation: Wave Interference
• PhET Simulations: Quantum Phenomena
• Phosphorescence
• Photon Quantum Mechanics
• Physics 2000
• Physics 219: Quantum Computation
• Physics Suite Sample Problems: Modern Physics
• Physics Virtual Bookshelf
• Physlet Problems Written or Adapted by Paul Zitzewitz
• Physlets for Quantum Mechanics
• Point Group Symmetry
• Probability Illustrator
• QM Carpet Program
• QM Energy Measurement Program
• QM Measurement Program
• QM Momentum Carpet Program
• QM Momentum Expectation Value Program
• QM Momentum Measurement Program
• QM Momentum Space Program
• QM Position Expectation Value Program
• QM Position Measurement Program
• QM Probability Program
• QM Superposition Program
• QM Superposition Program Distribution
• QM Wigner Program
• Quantiki
• Quantum Computation Lecture Notes
• Quantum Computer Simulator
• Quantum Holography
• Quantum Information Science Workshop
• Quantum Interactive Learning Tutorials
• Quantum Mechanical Models of Solids
• Quantum Mechanical Scattering
• Quantum Mechanics
• Quantum mechanics for everyone: Hands-on activities integrated with technology
• Quantum Mechanics Resource Packet
• Quantum Mechanics Tutorials
• Quantum Mechanics: Rigid Rotator Applet
• Quantum Mechanics: Sum over paths
• Quantum Microscopy and Quantum Systems Engineering: FAQ's
• Quantum Motion
• Quantum Optics and Quantum Information Laboratory
• Quantum Optics, Quantum Nanophysics, Quantum Information
• Quantum Physics Applets
• Quantum Physics made Relatively Simple: Three Lectures by Hans Bethe
• Quantum Physics Online
• Quantum Physics Online: Quantization in one dimension
• Quantum Physics Online: Quantization in three dimensions
• Quantum Physics Online: Quantum superposition in one dimension
• Quantum Physics Online: Quantum superposition in two dimensions
• Quantum Physics Online: Spin 1/2
• Quantum Physics Online: Wave Mechanics
• Quantum Physics: Introduction
• Quantum Tic-Tac-Toe
• Quantum Tic-Tac-Toe, Spooky-Coins, & Magic-Envelopes, as Metaphors for Relativistic Quantum Physics
• Quantum Tunneling
• QuantumLab
• Qwiki
• Resources Students Use to Understand Quantum Mechanical Operators
• RSPT Expansion
• Ruby Laser
• Simple Harmonic Motion - Example
• Single Slit Diffraction
• Solutions to the One-dimensional Time-independent Schrodinger Equation
• Special Functions Model
• Spectroscopy Lab Suite
• Spherical Harmonics YLM Explorer
• SPINS Java Homepage
• Square Wells - Example
• Stern-Gerlach
• Student Difficulties in Understanding Probability in Quantum Mechanics
• Student Difficulties with Energy in Quantum Mechanics
• Student Difficulties with Quantum Mechanics Formalism
• Student Difficulties with Wave Concepts
• Students’ Understanding of Stern Gerlach Experiment
• Symbolic Mathematics Documents for Physical Chemistry
• Symmetry and Degeneracy
• Teaching Physics: Figuring Out What Works
• Teaching Quantum Theory in the Introductory Course
• The Basics of MRI
• The double slit experiment and the collapse of the wavefunction
• The end of the certain world: The life and science of Max Born
• The Influence of Student Understanding of Classical Physics When Learning Quantum Mechanics
• The Many-Worlds Interpretation of Quantum Mechanics
• The Nobel Prize in Physics 1943 - Otto Stern
• The Particle in a Box
• The Stern-Gerlach Experiment
• The Teaching of Quantum Mechanics
• The University of Virginia Virtual Lab
• The Virtual Journal of Quantum Information
• Tunneling
• Two Dimensional Schrodinger Equation
• Two Source Interference
• Understanding How Students Learn
• Understanding Probabilistic Interpretations of Physical Systems: A Prerequisite to Learning Quantum Physics
• Upper-Division Quantum Mechanics I Transformed Course Materials
• Using a Computer-Rich Curriculum to Teach Quantum Mechanics
• Visual Quantum Mechanics
• Visual Quantum Mechanics
• Visual Schrödinger: A Visualizer-Solver Applet for the One-Dimensional Schrödinger Equation
• Visualizing Quantum Dynamics
• Visualizing Quantum Mechanical Revivals
• Wave Function Sketcher
• Wave Packet Explorer
• Wavepacket Tunneling through a Carbon Nanotube
• Waves: An Interactive Tutorial
• Web-based Quantum Mechanics I Course
• Web-based Quantum Mechanics II Course
• Who needs to learn physics in the 21st century and why?
• Wigner Quasi-probability Distribution for the Infinite Square Well: Energy Eigenstates and Time-dependent Wave Packets