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1,000,000 Transactions on the Cellframe Mainnet! 🚀 By the end of last week, Cellframe hit a major milestone — 1 million transactions. We achieved this in just 870 days since the mainnet launch, outpacing many of the leaders in the blockchain industry. The first million transactions mark a key stage in the network’s growth — but we’re not stopping here. The best is yet to come. Thank you for your support! We are CELL! We are here! #cellframe_announcement #1MillionTransactions #MainnetMilestone

Why Quantum Computing Threatens Current Cryptography In modern digital security, everything from online banking to encrypted messages relies on mathematical problems that are easy to do in one direction, but hard to reverse without a key. Two main systems used today are: RSA (Rivest-Shamir-Adleman): Based on the difficulty of factoring large numbers. ECC (Elliptic Curve Cryptography): Based on the difficulty of solving elliptic curve discrete logarithms. These systems are currently secure against classical computers, but not against future quantum computers. 1. Breaking Encryption: Shor's Algorithm Quantum computers can efficiently run Shor's algorithm. This means: RSA and ECC would be broken. Digital signatures used to verify identity and transactions, can be forged. Key exchanges used to start a secure connection, can be intercepted. Confidential data, like login credentials and encrypted messages, can be decrypted. This would undermine the entire security layer of: - Mobile banking - E-commerce platforms - Fintech services - Cryptocurrencies and blockchain applications 2. Retroactive Risk: Harvest Now, Decrypt Later Even though quantum computers aren't breaking encryption today, attackers can store encrypted data now and decrypt it later when quantum computers become viable. This is known as the "store now, decrypt later" attack. What’s at risk: - Personal emails and private messages - Health records - Financial transactions - Corporate secrets - Government communications In short, anything encrypted with classical encryption today, can be compromised in the future. 3. Blockchain Vulnerability Blockchains like Bitcoin and Ethereum depend on ECC for wallet security and transaction validation: Each wallet is tied to an ECC keypair. To spend or transfer funds, you sign transaction messages with the private key. A sufficiently large quantum computer could: Derive private keys from public keys Forge digital signatures Steal funds directly from wallets Why PQC (Post-Quantum Cryptography) Matters PQC is a new set of cryptographic algorithms designed to be secure against quantum attacks. These algorithms are based on mathematical problems not vulnerable to known quantum algorithms. PQC is still being standardized and adopted, creating a dangerous window of vulnerability.