Quantum Computing Could Crack Bitcoin in 9 Minutes, Google Research Reveals

Key Takeaways

Table of Contents

Toggle

• Key Takeaways

• The Challenge of Upgrading Bitcoin’s Security

• Elon Musk Responds to Quantum Threat

• New research from Google Quantum AI indicates a sophisticated quantum computer could break Bitcoin’s encryption within approximately nine minutes

• Since Bitcoin confirmation typically requires around 10 minutes, this creates a dangerously narrow one-minute safety margin

• Required qubit count has plummeted from millions to below 500,000 — representing a dramatic 20-fold decrease

• Google has accelerated its quantum computing development roadmap, now targeting 2029

• Elon Musk highlighted an unexpected benefit: quantum technology could eventually help recover access to crypto wallets with forgotten passwords

A groundbreaking whitepaper from Google’s research team demonstrates that a quantum computer utilizing architecture similar to their Willow chip could extract a Bitcoin private key from its corresponding public key in approximately nine minutes. Given that Bitcoin transactions typically require ten minutes for confirmation, this creates an alarmingly slim security margin of just sixty seconds.

Google Quantum AI released a white paper today warning that cracking 256-bit ECC, which is widely used in Bitcoin wallets, requires MUCH fewer resources than originally expected.

With under 500,000 physical qubits, any private key could theoretically be cracked in under 9… pic.twitter.com/cEpBox8pi0

— Jacob King (@JacobKinge) March 31, 2026

Within this critical time frame, a malicious actor could potentially capture an active transaction straight from the mempool — the staging area where unconfirmed transactions await processing — before it achieves finality. According to the research, the likelihood of executing such an attack successfully stands at nearly 41%.

The whitepaper originated from Google Quantum AI and specifically targeted the 256-bit Elliptic Curve Discrete Logarithm Problem (ECDLP), the actual cryptographic foundation that Bitcoin relies upon. Prior threat assessments had focused on RSA-2048, a different and older encryption methodology, which resulted in considerably more optimistic security timelines.

Perhaps the most alarming revelation concerns the dramatic reduction in computational resources needed. Previous studies indicated that compromising Bitcoin’s cryptographic protection would demand tens of millions of qubits. This latest research slashes that figure to under 500,000 — a stunning 20-fold reduction. The attack requires only 1,200 logical qubits operating at a 0.1% error threshold.

Google has reportedly advanced its internal quantum computing development schedule, now projecting capability by 2029.

An independent research collective named Oratomic has corroborated these findings through separate investigation. Employing neutral-atom hardware combined with an alternative technical methodology, they demonstrated that Shor’s algorithm — the quantum computational technique designed to defeat encryption — can function at cryptographically meaningful scales using between 10,000 and 22,000 qubits.

Two distinct research organizations. Two separate hardware platforms. Both arriving at remarkably similar conclusions.

The Challenge of Upgrading Bitcoin’s Security

Transitioning Bitcoin to post-quantum cryptographic standards presents significant technical and social obstacles. The process necessitates a hard fork, requiring widespread consensus throughout the Bitcoin community — a process historically characterized by prolonged debate and disagreement.

Post-quantum cryptographic signatures occupy substantially more data space compared to existing signatures, creating increased demands on network bandwidth, storage capacity, and computational resources throughout the entire ecosystem.

Even following successful consensus achievement, the actual network migration would span multiple months. Given Bitcoin’s present transaction processing capacity, transferring all existing coins to post-quantum-secure addresses — even if prioritized above all other network activity — would require several months to execute completely.

Security specialists caution that postponing action until a cryptographically capable quantum computer receives public confirmation — commonly referred to as “Q-Day” — would prove catastrophic. At that juncture, digital signature security may have already been fundamentally compromised.

Elon Musk Responds to Quantum Threat

Elon Musk addressed the Google security warnings through his account on X, where his audience exceeds 237 million followers. He observed that quantum computing’s ability to break Bitcoin encryption contained a “plus side”: individuals who had lost access to their wallet passwords might eventually recover their funds.

On the plus side, if you forgot the password to your wallet, it will be accessible in the future

— Elon Musk (@elonmusk) March 31, 2026

His observation highlights a genuine double-edged consequence — quantum computing sufficiently advanced to defeat encryption protocols could simultaneously provide access to wallets rendered inaccessible through lost credentials.

The complete title of Google’s research paper reads “Securing Elliptic Curve Cryptocurrencies against Quantum Vulnerabilities: Resource Estimates and Mitigations.”

Advertise Here