PLAIN ENGLISH
This is a live animation of how quantum particles behave — they exist as waves of possibility until you measure them, then they 'collapse' into a definite answer. Think of it like a coin spinning in the air (all possibilities) until it lands (one answer).
This is a live animation of how quantum particles behave — they exist as waves of possibility until you measure them, then they 'collapse' into a definite answer. Think of it like a coin spinning in the air (all possibilities) until it lands (one answer).
ψ Wave Function Collapse
|ψ⟩
State
0.00
P(collapse)
0.00π
Phase
PLAIN ENGLISH
Two particles get 'linked' so that measuring one instantly tells you about the other, no matter how far apart. Like two magic dice that always roll the same number. UNA verified this works with 99%+ accuracy across multiple quantum computers.
Two particles get 'linked' so that measuring one instantly tells you about the other, no matter how far apart. Like two magic dice that always roll the same number. UNA verified this works with 99%+ accuracy across multiple quantum computers.
∞ Quantum Entanglement Pairs
0
Active Pairs
0.000
Bell Fidelity
0.000
Concurrence
PLAIN ENGLISH
This is a simulated grid of 64 quantum bits (qubits). Each one can be 0, 1, or BOTH at once. The colors show their current state — cyan=0, purple=1, pink=superposition (both), green=entangled (linked to another). They're constantly changing as quantum operations run.
This is a simulated grid of 64 quantum bits (qubits). Each one can be 0, 1, or BOTH at once. The colors show their current state — cyan=0, purple=1, pink=superposition (both), green=entangled (linked to another). They're constantly changing as quantum operations run.
■ 64-Qubit Quantum Register
0.000
Coherence
0.000
Error Rate
0
Gate Ops/s
PLAIN ENGLISH
The most famous quantum experiment ever. Fire particles one at a time through two slits — they build up a striped pattern that proves particles also behave like waves. Each yellow bar is where a particle landed. The stripes = wave interference. This shouldn't work if particles were just tiny balls, but it does.
The most famous quantum experiment ever. Fire particles one at a time through two slits — they build up a striped pattern that proves particles also behave like waves. Each yellow bar is where a particle landed. The stripes = wave interference. This shouldn't work if particles were just tiny balls, but it does.
◑ Double-Slit Interference
0
Photons
0 nm
Wavelength
0.000
Visibility
PLAIN ENGLISH
All the fundamental building blocks of reality. Everything in the universe — you, stars, your phone — is made of combinations of these particles. UNA studies their properties to understand quantum field theory.
All the fundamental building blocks of reality. Everything in the universe — you, stars, your phone — is made of combinations of these particles. UNA studies their properties to understand quantum field theory.
⚛ Standard Model Explorer
e⁻Electron0.511 MeV
μ⁻Muon105.7 MeV
τ⁻Tau1,777 MeV
uUp Quark2.2 MeV
dDown Quark4.7 MeV
γPhoton0 MeV
gGluon0 MeV
HHiggs125,100 MeV
PLAIN ENGLISH
Live results from the last experiment run. Each backend ran the same quantum circuits. 'Pass' means the quantum computer did what physics predicts. 'Skip' means a technical issue prevented the test. Zero failures = all machines agree with quantum theory.
Live results from the last experiment run. Each backend ran the same quantum circuits. 'Pass' means the quantum computer did what physics predicts. 'Skip' means a technical issue prevented the test. Zero failures = all machines agree with quantum theory.
⚡ Live Backend Results
⬡ IBM Qiskit
Bell: |00⟩=485 |11⟩=539
GHZ: 10q ✓ pass
QFT: 6q · 64 states ✓
GHZ: 10q ✓ pass
QFT: 6q · 64 states ✓
◎ Google Cirq
Bell: |00⟩≈|11⟩ ✓
GHZ: 10q ✓ pass
QFT: 5q ✓ pass
GHZ: 10q ✓ pass
QFT: 5q ✓ pass
⬡ PennyLane
Bell: ⟨ZZ⟩=-1.000 ✓
GHZ: 12q ✓ pass
VQC: ⟨Z⟩=0.995 ✓
GHZ: 12q ✓ pass
VQC: ⟨Z⟩=0.995 ✓
◆ IonQ
Bell: |00⟩=500 |11⟩=524 ✓
GHZ: 5q ✓ pass
GHZ: 5q ✓ pass
☁ AWS Braket
Devices: 10 backends ✓
Status: acct verified ✓
Status: acct verified ✓
PLAIN ENGLISH
This is a live log showing every quantum operation UNA performs — measurements, entanglement creation, gate operations, and error corrections. It updates in real-time so you can watch the lab in action.
This is a live log showing every quantum operation UNA performs — measurements, entanglement creation, gate operations, and error corrections. It updates in real-time so you can watch the lab in action.
⚙ Quantum Experiment Log