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University of Colorado Boulder

Foundations of Quantum Mechanics

Wounjhang Park

Instructor: Wounjhang Park

12,441 already enrolled

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Gain insight into a topic and learn the fundamentals.
4.4

(74 reviews)

Intermediate level

Recommended experience

Flexible schedule
Approx. 26 hours
Learn at your own pace
Build toward a degree
Gain insight into a topic and learn the fundamentals.
4.4

(74 reviews)

Intermediate level

Recommended experience

Flexible schedule
Approx. 26 hours
Learn at your own pace
Build toward a degree

What you'll learn

  • Understand the quantum mechanical meaning of wave-particle duality

  • Calculate probabilities and expectation values for physical observables

  • Use both Schrödinger and Heisenberg picture to solve for time evolution of quantum states

  • Describe fermions and bosons using multiparticle basis functions.

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Assessments

6 quizzes

Taught in English

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This course is part of the Quantum Mechanics for Engineers Specialization
When you enroll in this course, you'll also be enrolled in this Specialization.
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There are 6 modules in this course

In this module we will introduce the course and the Quantum Mechanics for Engineers specialization. In addition, we will discuss wave-particle duality, time-independent Schrödinger equation. one-dimensional infinite potential well problem, properties of eigensolutions and Hilbert space.

What's included

6 videos4 readings1 quiz2 discussion prompts

In this module, we will solve several one-dimensional potential problems. They include finite potential well, harmonic oscillator, potential step and potential barrier. We will discuss the physical meaning of the solutions and highlight any non-classical behaviors these problems exhibit.

What's included

4 videos3 readings1 quiz1 discussion prompt

This module covers the theory of measurements in quantum mechanics. We start our discussion by introducing Stern-Gerlach experiment and the difficulty in interpreting the results classically. We then develop mathematical tools required to properly describe the results and then apply them to the interpretation of Stern-Gerlach experiments.

What's included

5 videos3 readings1 quiz1 peer review1 discussion prompt

In this module we expand upon the discussion from the previous module and introduces Hamiltonian, position and momentum operators and the uncertainty principle that governs the relationship between the operators. We also discuss the general principle of change of basis and the specific example of position and momentum representations.

What's included

4 videos3 readings1 quiz1 peer review

This module discusses how to describe the time-evolution of a quantum system. There are two equivalent methods, Schrödinger and Heisenberg pictures, where the time evolution can be obtained by the time-dependent Schrödinger equation and Heisenberg equation of motion, respectively. We will discuss the specific example of harmonic oscillator and finally introduce the particle current.

What's included

5 videos3 readings1 quiz1 peer review

This module discusses how to deal with ensembles. We will first discuss the difference between pure and mixed states and how to use the density matrix to describes them. We then discuss indistinguishable particles and exchange interaction, which eventually lead us to the thermal distribution functions.

What's included

5 videos3 readings1 quiz1 discussion prompt

Instructor

Instructor ratings
4.1 (18 ratings)
Wounjhang Park
University of Colorado Boulder
6 Courses51,840 learners

Offered by

Recommended if you're interested in Electrical Engineering

Build toward a degree

This course is part of the following degree program(s) offered by University of Colorado Boulder. If you are admitted and enroll, your completed coursework may count toward your degree learning and your progress can transfer with you.¹

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4.4

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