The Experiment

Fire particles at a barrier with two slits. Watch where they land.

Each dot is one particle hitting the detector. The pattern emerges statistically.

Photon: Quantum of light. Massless. Still produces interference. This behavior is not about what the particle is — it's about how quantum systems behave.

Observer OFF: No measurement → interference pattern → wave behavior.

Watch particles arrive one at a time

Turn the Observer ON — what changes?

Turn it OFF again — the pattern returns

What This Reveals

The Pattern Builds Statistically

Each particle lands randomly. The pattern only emerges after many hits. There's no wave on the screen — only accumulated probability.

Measurement Creates Reality

Knowing which slit the particle went through forces it to behave classically. The information itself matters.

Probability Waves Interfere

The particle's wavefunction passes through both slits and interferes with itself. The screen shows where it's likely to land.

This Works for Everything

Photons, electrons, atoms — even molecules. Quantum behavior isn't about size. It's about isolation from measurement.

Expectation vs Reality

SOURCE

2 SLITS

DETECTOR

CLASSICAL EXPECTATION

What you'd expect: two bands, one behind each slit

This Is the Same Phenomenon

Superposition

The wavefunction passes through both slits. The particle exists in multiple states until measured.

Measurement Collapse

Observation forces one outcome. Reading a qubit destroys its quantum state for the same reason.

Interference

Probability amplitudes add and cancel. Quantum algorithms exploit this to amplify correct answers.

A qubit is a system designed to stay in this strange state long enough to compute.

PreviousSanity Check NextQubits