The particle is everywhere at once. Superposition shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

2d-wave

The Wave Function

ψ(x,t) — the math of possibility. The Wave Function shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

2d-wave

Measurement

Looking is what makes things real. Measurement shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

double-slit

The Double Slit

One particle going through two slits. The Double Slit shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

double-slit

Wave-Particle Duality

Light is both — and so are you. Wave-Particle Duality shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

2d-wave

Uncertainty

Some things can't be known at the same time. Uncertainty shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

tunneling

Quantum Tunneling

Particles walk through walls. Quantum Tunneling shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

2d-wave

The Schrödinger Equation

The equation that runs the universe. The Schrödinger Equation shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

particle-in-box

Stationary States

Standing waves in a quantum world. Stationary States shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

particle-in-box

The Particle in a Box

What happens when you trap a wave. The Particle in a Box shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

hydrogen-orbital

Hydrogen

How an electron orbits without orbiting. Hydrogen shows that quantum objects are described by waves of possibility until measurement selects an outcome. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

bloch-sphere

Spin

Particles spin without spinning. Spin explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

stern-gerlach

The Stern-Gerlach Experiment

The experiment that found spin. The Stern-Gerlach Experiment explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

hydrogen-orbital

Pauli Exclusion

Why every atom has a shape. Pauli Exclusion explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

hydrogen-orbital

Multi-Electron Atoms

When electrons have to share a house. Multi-Electron Atoms explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

molecular-orbital

Molecular Orbitals

Two atoms, one shared cloud. Molecular Orbitals explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

molecular-orbital

Chemical Bonding

Why atoms stick together. Chemical Bonding explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

spectroscopy

Spectroscopy

How light tells you what something is. Spectroscopy explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

laser-emission

Lasers

Coherent light, plain and simple. Lasers explains how quantized states give atoms and molecules their shape, spectra, and chemical behavior. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

bloch-sphere

Bits and Qubits

Beyond zero and one. Bits and Qubits treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

bloch-sphere

The Bloch Sphere

Every quantum state is a point on a sphere. The Bloch Sphere treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

bloch-sphere

Single-Qubit Gates

Rotations of the Bloch sphere. Single-Qubit Gates treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

quantum-circuit

The CNOT Gate

When two qubits become one. The CNOT Gate treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

entanglement

Entanglement

Two particles, one shared destiny. Entanglement treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

entanglement

Bell States

Einstein was wrong about this one. Bell States treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

quantum-circuit

Quantum Teleportation

Quantum information at any distance. Quantum Teleportation treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

quantum-circuit

The No-Cloning Theorem

You can't copy a quantum state. The No-Cloning Theorem treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

bloch-sphere

POVMs

Measurement isn't always yes-or-no. POVMs treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

density-matrix

Density Matrices

Quantum states with imperfect information. Density Matrices treats quantum states as information that can be rotated, correlated, measured, and protected from careless copying. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

quantum-circuit

Quantum Circuits

Reading the circuit diagram. Quantum Circuits turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

quantum-circuit

Universal Quantum Gates

All quantum logic from a small set. Universal Quantum Gates turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

deutsch-jozsa

Deutsch-Jozsa

The first quantum advantage. Deutsch-Jozsa turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

grover

Grover Search

Searching faster than possible. Grover Search turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

qft

Quantum Fourier Transform

The quantum Fourier transform. Quantum Fourier Transform turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

shor

Shor's Algorithm

How quantum computers break encryption. Shor's Algorithm turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

vqe

Variational Quantum Eigensolver

Solving chemistry with quantum hardware. Variational Quantum Eigensolver turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

qaoa

QAOA

Approximating impossible optimizations. QAOA turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

qml

Quantum Machine Learning

When neural networks meet qubits. Quantum Machine Learning turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

quantum-circuit

NISQ Computing

What today's quantum computers can do. NISQ Computing turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

error-correction

Fault Tolerance

Building reliability from unreliability. Fault Tolerance turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

surface-code

Surface Codes

The error-correcting code that might win. Surface Codes turns quantum evolution into a computational operation with strengths and limits that classical circuits do not share. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

transmon

Superconducting Qubits

Qubits made of supercooled metal. Superconducting Qubits connects the abstract qubit to physical devices that must fight noise, heat, and unwanted coupling. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

trapped-ion

Trapped Ions

Qubits made of single floating atoms. Trapped Ions connects the abstract qubit to physical devices that must fight noise, heat, and unwanted coupling. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

photonic

Photonic Qubits

Qubits made of light. Photonic Qubits connects the abstract qubit to physical devices that must fight noise, heat, and unwanted coupling. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

topological

Topological Qubits

The qubit that's intrinsically protected. Topological Qubits connects the abstract qubit to physical devices that must fight noise, heat, and unwanted coupling. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

atom-array

Neutral Atoms

Qubits made of atoms held by lasers. Neutral Atoms connects the abstract qubit to physical devices that must fight noise, heat, and unwanted coupling. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

spin-qubit

Spin Qubits

Qubits inside silicon — the same stuff as your computer. Spin Qubits connects the abstract qubit to physical devices that must fight noise, heat, and unwanted coupling. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

decoherence

Decoherence

Why quantum computers have to be cold. Decoherence connects the abstract qubit to physical devices that must fight noise, heat, and unwanted coupling. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

atomic-clock

Atomic Clocks

The most accurate clocks in existence. Atomic Clocks uses fragile quantum phase as an instrument for measuring time, fields, motion, or gravity with extreme precision. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

nv-center

NV Centers

A defect in diamond that can sense a single electron. NV Centers uses fragile quantum phase as an instrument for measuring time, fields, motion, or gravity with extreme precision. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

gravity-sense

Quantum Gravity Sensing

Detecting the pull of a single grain of rice. Quantum Gravity Sensing uses fragile quantum phase as an instrument for measuring time, fields, motion, or gravity with extreme precision. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

ligo

LIGO

How LIGO detected colliding black holes. LIGO uses fragile quantum phase as an instrument for measuring time, fields, motion, or gravity with extreme precision. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

ghost-imaging

Quantum Imaging

Photographing things with light that never touched them. Quantum Imaging uses fragile quantum phase as an instrument for measuring time, fields, motion, or gravity with extreme precision. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

bb84

BB84

BB84 — the original quantum-secure key exchange. BB84 shows how security can rest on physical laws instead of computational inconvenience alone. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

e91

E91

Bell-state cryptography. E91 shows how security can rest on physical laws instead of computational inconvenience alone. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

qrng

Quantum Random Number Generation

True randomness from a quantum coin flip. Quantum Random Number Generation shows how security can rest on physical laws instead of computational inconvenience alone. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

vacuum

The Quantum Vacuum

Empty space is full of activity. The Quantum Vacuum replaces particles as tiny objects with fields whose excitations are the things we detect. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

qed

Quantum Electrodynamics

How light and matter actually interact. Quantum Electrodynamics replaces particles as tiny objects with fields whose excitations are the things we detect. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

feynman

Feynman Diagrams

Drawing the impossible. Feynman Diagrams replaces particles as tiny objects with fields whose excitations are the things we detect. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

path-integral

Path Integrals

All paths at once. Path Integrals replaces particles as tiny objects with fields whose excitations are the things we detect. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

standard-model

The Standard Model

What the universe is made of, plain and simple. The Standard Model replaces particles as tiny objects with fields whose excitations are the things we detect. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.

pilot-wave

Pilot Wave Theory

What if particles really do have positions?. Pilot Wave Theory asks what quantum theory is telling us about knowledge, measurement, and reality itself. The lesson starts from observation and then names the physics behind what the simulation or thought experiment reveals.