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# Quantum Objects

## When things get small, things get weird.

The principles of quantum mechanics came from investigating microscopic phenomena; the bizarre behavior of quantum objects like atoms and elementary particles that often appear to contradict classical mechanics and probability.

In this course you'll explore experiments of quantum objects and use them to construct new equations of motion, new laws of physics, and a new system of measurement based not on numbers, but on algebras. By the end, you’ll gain a new appreciation for how the physics of the small enables lasers, transistors and other modern technologies that define our world. Then you'll be ready to dive into the ongoing revolution of quantum information and computing.

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1. 1

### Spin Class

Get to know the rules of quantum objects by exploring the strange behavior of spinning particles.

1. #### Why Quantum?

Tiny objects don't just bounce off walls, and even after you sort them they still end up mixed up.

2. #### Classical Expectations

With a couple magnets and a source of neutrons, you can observe the most quantum property of all: spin.

3. #### Quantum Surprises

The Stern-Gerlach experiment reveals that subatomic particles are spinning like tops — or are they?

4. #### Observables

Observing a quantum object isn't gentle: sometimes change is inevitable.

2. 2

### Mathematical Foundations

Build up the mathematical formalism for manipulating quantum states by playing with quantum spin.

1. Included with

#### Color Space

The best way to learn vector spaces is through color spaces.

2. Included with

#### Bras and Kets

All the information you'll ever need about a quantum object is contained in a ket.

3. Included with

#### Playing with Basis Sets

There's more than one way to represent a quantum state.

4. Included with

#### Unavoidable Complexity

You can simplify quantum calculations by using vectors, but you can't avoid complex numbers.

3. 3

### Quantum Mechanics

A journey of discovery through the classical underpinnings of Quantum Mechanics, and where they fail.

1. Included with

#### The Photon Catastrophe

Explore the quantum nature of light with some help from Einstein and Compton.

2. Included with

#### Particles and Waves

Maxwell's wave equations are flexible — they can describe light as a wave or a collection of photons.

3. Included with

#### Wide Open Spaces

Learn how to bridge the gap between bras and kets and continuous functions.

4. Included with

#### Squeezing Measurements

There's a limit to how accurately you can measure a particle's position and momentum.

4. 4

### Particles Unboxed

Explore the behavior of quantum particles in boxes and learn why grass is green and why semiconductors conduct.

Coming Soon
5. 5

### Quantum in the Wild

Use your newfound understanding of quantum objects to tackle real-world systems like qubits, neutrinos and MRI.

Coming Soon
6. 6

### Quantum Logic

Everything you've been afraid to ask about so far: The spooky world of multiparticle states.

Coming Soon