🛡️ Post-advanced cryptography Lab

Defend against secure computer attacks! See how secure computers can break today's encryption and learn how next-generation algorithms protect us. Interactive simulations make complex cryptography easy to understand.

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secure Threat Timeline

Q-Day estimated: 2035-2040 • Time to prepare: 10-15 years

🤔 What Is Post-Quantum Cryptography?

Think of your passwords protected by a lock that quantum computers can pick in seconds — today's encryption relies on math problems that classical computers can't solve, but quantum machines will crack them effortlessly. Post-quantum cryptography builds entirely new locks based on lattice math that even quantum computers find impossible.

Why does this matter? "Harvest now, decrypt later" attacks are already happening — adversaries store encrypted data today to crack it when quantum computers arrive. NIST finalized new PQC standards in 2024. In this simulator, you'll watch quantum attacks break RSA encryption and deploy next-generation lattice-based defenses.

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Banking

Protect $5T daily transactions

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Healthcare

Secure patient records

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Government

National security data

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Infrastructure

Power grids & utilities

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Automotive

Connected vehicle security

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Personal

Your private messages

🚀 Quick Demos

🎛️ Algorithm Selection

🔓 RSA-2048 (Current)

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8 hrs

secure Break Time

20M

Qubits Needed

2048

Key Size (bits)

❌

future proof

🔒 Kyber-1024 (PQC)

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∞

secure Break Time

N/A

Qubits Needed

1568

Key Size (bytes)

✅

future proof

Next-Generation Defense Mechanisms

Encryption result will appear here...

2026 (Now)

Start Assessment

Inventory current encryption systems

2026-2027

Testing Phase

Test PQC algorithms in sandbox environments

2028-2030

Hybrid Deployment

Run classical and PQC in parallel

2030-2035

Full Migration

Complete transition to future-proof systems

2035+

secure Era

Protected against secure attacks