"Quantum Analogs"
POSTER
Abstract
The driving principle behind the Quantum Analogs apparatus from TeachSpin, Inc, is that there
is an analogy between the mathematical equations for the Schrodinger wave equation in quantum
mechanics and the wave equations for sound waves in air. This allows students to perform
experiments in which they measure acoustic analogs to the behavior of quantum mechanical
systems in 1-dimension and 3-dimensions. In so doing, they gain valuable insight, intuition, and
understanding about the predictions of quantum mechanics. The Quantum Analogs uses sound
waves in aluminum cylinders and spheres to model quantum states in semiconductors, hydrogen
atoms, and diatomic hydrogen molecules. Numerous investigations can be performed with this
apparatus, including experiments on standing waves in an air column, which is analogous to a 1-
dimensional particle in a box and illustrates the idea of band gaps in solids. Another set of
experiments involves standing waves in a spherical cavity, which has analogous behaviors to the
hydrogen atom. An additional set of experiments uses two spheres which is analogous to a
diatomic hydrogen molecule.
is an analogy between the mathematical equations for the Schrodinger wave equation in quantum
mechanics and the wave equations for sound waves in air. This allows students to perform
experiments in which they measure acoustic analogs to the behavior of quantum mechanical
systems in 1-dimension and 3-dimensions. In so doing, they gain valuable insight, intuition, and
understanding about the predictions of quantum mechanics. The Quantum Analogs uses sound
waves in aluminum cylinders and spheres to model quantum states in semiconductors, hydrogen
atoms, and diatomic hydrogen molecules. Numerous investigations can be performed with this
apparatus, including experiments on standing waves in an air column, which is analogous to a 1-
dimensional particle in a box and illustrates the idea of band gaps in solids. Another set of
experiments involves standing waves in a spherical cavity, which has analogous behaviors to the
hydrogen atom. An additional set of experiments uses two spheres which is analogous to a
diatomic hydrogen molecule.
Presenters
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Brandon Samuel
Francis Marion University
Authors
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Brandon Samuel
Francis Marion University
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Robert S Smith
Francis Marion University