Dual Quantum Sources

QUANTUM GENERATED PASSWORD

SILICONIC-based Hadamard gate & Born rule measurement using ANU quantum hardware to measure photonic fluctuations via homodyne detection, producing super-positioned random number assignment for secure application processing.

Qubit Circuit Simulator

State-vector quantum simulation. Hadamard gates create superposition; measurement collapses via Born rule probabilities (|amplitude|²). Real quantum math — not pseudo-random.

Ready — runs locally

ANU Quantum Hardware

Australian National University's quantum vacuum RNG. Homodyne detection of electromagnetic zero-point energy fluctuations. Real photonic quantum noise from lab hardware.

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SECURE MODE — AIR-GAPPED GENERATION

  • Zero network calls — fully offline, no API requests
  • 32-qubit quantum circuit runs entirely in your browser
  • No data leaves your device — nothing transmitted, nothing logged
  • Auto-wipes from memory 60 seconds after generation
  • History disabled — no trace retained

Quantum Circuit

OpenQASM 3.0

Output Format
Range (Integer mode)
to
Shots (measurements per run)
Results to Generate
Quantum Measurement Result
Ready

History

No quantum measurements yet
Qubit Simulator: State-vector math — Hadamard (H) gate puts |0⟩ into (|0⟩+|1⟩)/√2 superposition. Measurement collapses via Born rule.
ANU Hardware: Quantum vacuum fluctuations measured by homodyne detection of electromagnetic zero-point energy.
Combined Mode: XORs bits from both sources — provably at least as random as the strongest source.