Mathematica examples from the LC undergraduate physics curriculum

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Mathematica examples from the LC undergraduate physics curriculum John Eric Goff Lynchburg College Lynchburg,

Mathematica examples from the LC undergraduate physics curriculum John Eric Goff Lynchburg College Lynchburg, VA 24501 CS-AAPT Fall 2007 – Radford University Radford, VA 24142 November 3, 2007

LC Physics • • Small number of physics faculty (2 or 3). We need

LC Physics • • Small number of physics faculty (2 or 3). We need a niche! We have a computational emphasis. Computational Physics joins theory and experiment to form the new triumvirate in physics. • Some form of computation permeates all our courses.

What do we do? • Intro: Excel (Euler method in second lab), some Mathematica,

What do we do? • Intro: Excel (Euler method in second lab), some Mathematica, simulations (Kinetic Books and Physlets) • Intermediate: Mathematica (especially Classical Mechanics in 4 th semester) • Advanced: Mathematica and Full Programming (Computational Physics Course)

Intro Example (1 st Semester) • “Curtain of Death” problem (HRW 4 -68)

Intro Example (1 st Semester) • “Curtain of Death” problem (HRW 4 -68)

What is typically done? Excel Plot

What is typically done? Excel Plot

Use Mathematica!

Use Mathematica!

Intro Lab – Kirchhoff’s Rules PASCO Six equations in six unknowns (currents)! How do

Intro Lab – Kirchhoff’s Rules PASCO Six equations in six unknowns (currents)! How do students compare with theory without spending most of “lab” doing algebra? ? ?

Use Mathematica! • Make sure students write down the six equations in six unknowns.

Use Mathematica! • Make sure students write down the six equations in six unknowns. Do not skip the physics! Students evaluate “sol” with their own V and R values.

Classical Mechanics • • Taken by sophomores in spring semester. Mathematica is used throughout

Classical Mechanics • • Taken by sophomores in spring semester. Mathematica is used throughout course. One week of class devoted to Mathematica. Homework and exam questions require numerical solutions.

Velocity-Dependent Forces • Thornton and Marion 2 -18 (worked fully in class) • Softball

Velocity-Dependent Forces • Thornton and Marion 2 -18 (worked fully in class) • Softball problem uses quadratic air drag. • Problem cannot be solved analytically!

Phase Plots • Thornton and Marion 3 -15 • Underdamped Oscillator

Phase Plots • Thornton and Marion 3 -15 • Underdamped Oscillator

Noninertial Reference Frames • Thornton and Marion Example 10. 2 • Hockey Puck on

Noninertial Reference Frames • Thornton and Marion Example 10. 2 • Hockey Puck on a Merry-Go-Round

Electromagnetism • Griffith’s 3 -25 • Cylinder (radius R) with charge density σ( )

Electromagnetism • Griffith’s 3 -25 • Cylinder (radius R) with charge density σ( ) = k sin(5 ) • Answer:

Visualize with Mathematica!

Visualize with Mathematica!

Quantum Mechanics • Griffiths 2. 17 (1 st ed. ) • Time evolution of

Quantum Mechanics • Griffiths 2. 17 (1 st ed. ) • Time evolution of particle in even mixture of ground- and first-excited states of harmonic oscillator potential.

Animate with Mathematica!

Animate with Mathematica!

Quantum Mechanics - Project See Stuart Farrell’s Spring 2005 CS-AAPT talk.

Quantum Mechanics - Project See Stuart Farrell’s Spring 2005 CS-AAPT talk.

Optics Fringe patterns on a holographic plate.

Optics Fringe patterns on a holographic plate.

Optics – Final Exam Question Diffraction intensity for a rectangular aperture.

Optics – Final Exam Question Diffraction intensity for a rectangular aperture.

Computational Physics • Giordano and Nakanishi “Cream in the Coffee” Problem • Animation is

Computational Physics • Giordano and Nakanishi “Cream in the Coffee” Problem • Animation is a must!

Cream in the Coffee Show the entropy’s progression toward a constant value.

Cream in the Coffee Show the entropy’s progression toward a constant value.

Fluid Mechanics Project Velocity field of fluid moving around rectangular obstruction.

Fluid Mechanics Project Velocity field of fluid moving around rectangular obstruction.

Fluid Mechanics Project Stream function of fluid moving around rectangular obstruction.

Fluid Mechanics Project Stream function of fluid moving around rectangular obstruction.

Fluid Mechanics Project Vorticity of fluid moving around rectangular obstruction.

Fluid Mechanics Project Vorticity of fluid moving around rectangular obstruction.