Quantum Leap Accelerates Concerns Over Bitcoin Security
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The quantum timeline is tightening. Researchers at the California Institute of Technology estimate that a usable quantum computer could emerge before 2030. Such a projection disrupts established forecasts and revives questions about the security of cryptographic systems, including blockchains. As technical advances accelerate, the prospect of a shift is no longer distant.
In brief
- A breakthrough by researchers at the California Institute of Technology suggests that a practical quantum computer could emerge before 2030.
- A new architecture significantly reduces technical requirements, dropping from millions to just 10,000 to 20,000 qubits.
- This technological advance comes with so-called “ultra-efficient” error correction, reshaping the sector’s outlook.
- At the same time, recent studies اشاره the potential of quantum computing to weaken Bitcoin’s network encryption.
A technological breakthrough that drastically reduces requirements
While quantum computing targets bitcoin and messaging applications, researchers at Caltech, in collaboration with the startup Oratomic, claim that a functional quantum computer could require only 10,000 to 20,000 qubits, compared to millions estimated before.
This breakthrough relies on a new approach to error correction. As John Preskill explains: “we are developing new architectures for neutral atom quantum processors that greatly reduce the resources required for error-tolerant quantum computing”. He adds: “this advance makes me optimistic that really useful quantum computing will soon become reality”.
This advance rests on several key innovations :
- The use of neutral atom systems to improve calculation stability ;
- The manipulation of qubits via lasers called “optical tweezers” ;
- An ability to connect qubits over long distances ;
- A drastic reduction in necessary resources thanks to a new architecture.
Manuel Endres, a physics professor at Caltech who recently created the largest qubit network ever assembled, notes: “unlike other quantum computing platforms, neutral atom qubits can be directly connected over long distances”.
He also highlights the unexpected efficiency of the device: “the level of efficiency is even surprising. This is what we call ultra-efficient error correction”. Practically, this method would allow building a logical qubit with about five physical qubits, compared to nearly a thousand with classical approaches.
Increased pressure on the security of bitcoin and other cryptos
This breakthrough comes in an already tense context for cryptography. A recent Google article mentions the possibility for a quantum computer to break the Bitcoin network encryption in just nine minutes, with resources well below past estimates. At the same time, the company urges developers to adopt post-quantum cryptography (PQC) solutions now, without waiting for the threat to become concrete.
Google has also set a clear horizon by announcing it aims for a transition to these standards by 2029, estimating that quantum boundaries may be closer than anticipated. This convergence between academic advances and industrial projections reinforces the idea that the adaptation window for blockchains, especially Bitcoin, could be shorter than expected.
As technological barriers fall, the question is no longer just whether quantum will pose a threat, but when. Between scientific optimism and strategic caution, the crypto ecosystem faces an imperative: to anticipate a profound mutation of its cryptographic foundations before theory becomes reality.
