Quantum computing

Google sets 2029 deadline for post-quantum cryptography migration

A transition to post-quantum cryptography by 2029 is being led by Google, aiming to secure digital systems against future quantum computing threats instead of relying on existing encryption standards.

The move reflects growing concern that advances in quantum hardware and algorithms could eventually undermine current cryptographic protections, particularly through attacks that store encrypted data today for decryption in the future.

Quantum computers are expected to challenge widely used encryption and digital signature systems, prompting the need for early transition strategies.

Google has updated its threat model to prioritise authentication services, recognising that digital signatures pose a critical vulnerability if not addressed before the arrival of quantum machines capable of cryptanalysis.

The company is encouraging broader industry action to accelerate migration efforts and reduce long-term security risks.

As part of its strategy, Google is integrating post-quantum cryptography into its products and services.

Android 17 will include quantum-resistant digital signature protection aligned with standards developed by the US’s National Institute of Standards and Technology. At the same time, support has already been introduced in Google Chrome and cloud platforms.

These measures aim to bring advanced security technologies directly to users instead of limiting them to experimental environments.

By setting a clear timeline, Google aims to instil urgency and direction across the wider technology sector.

The transition to post-quantum cryptography is expected to become a critical step in maintaining online security, ensuring that digital infrastructure remains resilient as quantum computing capabilities continue to evolve.

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Quantum readiness gains momentum according to OECD report

The OECD (Organisation for Economic Co-operation and Development) highlights how businesses are preparing for quantum computing, recognising it as a transformative technology instead of relying solely on conventional computing methods.

Quantum readiness is framed as a long-term capability-building effort in which firms gradually develop skills, infrastructure, and partnerships to explore commercial applications while navigating uncertainty.

Drawing on research, surveys, and interviews with public and private organisations across 10 countries, the OECD identifies both the practical steps companies take to build readiness and the barriers that slow adoption.

Early efforts focus on low-cost awareness and exploration, including attending workshops, training sessions, and industry events, allowing firms to familiarise themselves with emerging opportunities instead of waiting for fully mature systems.

Despite growing interest, companies face significant challenges. Technological immaturity complicates pilots and feasibility studies, while many firms lack a clear understanding of potential business applications.

Access to quantum resources, funding for research and development, and staff training are expensive, particularly for small- and medium-sized enterprises. Furthermore, there is a shortage of talent with both quantum computing expertise and domain-specific knowledge.

As a result, readiness tends to be concentrated among large, R&D-intensive firms, while smaller companies often recognise quantum computing’s potential but delay action.

Such an uneven adoption risks creating a divide in the digital economy, with early adopters moving ahead and other firms falling behind instead of engaging proactively.

To address these challenges, the OECD notes that public and private support mechanisms are critical. Networking and collaboration platforms connect firms with researchers, technology providers, and industry peers, fostering knowledge exchange and collective experimentation.

Business advisory and technology extension services help companies assess capabilities, test solutions, and access specialised facilities.

Grants for research and development lower the costs of experimentation and encourage collaboration, while stakeholder consultations ensure that support measures remain aligned with business needs.

Many companies are also establishing internal quantum labs and innovation hubs to trial applications and build expertise in a controlled environment, combining research with practical exploration instead of relying solely on external guidance.

Looking ahead, the OECD recommends expanding education and skills pipelines, strengthening industry-academic partnerships, and designing policies that support broader participation in quantum adoption.

Hybrid approaches that integrate quantum computing with AI and high-performance computing may offer practical commercial entry points for early applications.

Policymakers are encouraged to balance near-term exploratory pilots with forward-looking support for software development, interoperability, and workforce growth, enabling firms to move from experimentation to deployment effectively.

By following OECD guidance, companies can enhance innovation, improve competitiveness, and ensure that readiness efforts span sectors and geographies rather than remain limited to a few early adopters.

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Google expands into neutral atom quantum computing

Google Quantum AI is broadening its quantum computing research to include neutral atom technology alongside its established superconducting qubits. Neutral atoms offer high connectivity and flexibility, while superconducting qubits provide fast cycles and deep circuit performance.

By pursuing both approaches, Google aims to accelerate progress and deliver versatile platforms for different computational challenges.

The neutral atom programme is focused on three pillars: quantum error correction adapted for atom arrays, modelling and simulation of hardware architectures, and experimental hardware development to manipulate atomic qubits at scale.

The initiative is led by Dr Adam Kaufman, who joins Google from CU Boulder, bringing expertise in atomic, molecular, and optical physics to advance neutral atom hardware.

Google is leveraging the Boulder quantum ecosystem, collaborating with institutions such as JILA, CU Boulder, NIST, and QuEra to strengthen research and innovation. These partnerships give access to top talent, facilities, and federal programmes, strengthening the US role in global quantum research.

By combining superconducting and neutral-atom approaches, Google aims to address critical physics and engineering challenges on the path to large-scale, fault-tolerant quantum computers, with commercial relevance expected by the end of the decade.

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Quantum readiness as a strategic priority for firms

Businesses are beginning to prepare for the commercial potential of quantum computing, a technology that leverages quantum mechanics to solve problems beyond the capabilities of classical computers.

Early engagement focuses on awareness, training, and workshops to explore possible applications across sectors such as pharmaceuticals, energy, finance, and advanced materials.

Companies face several barriers to readiness, including limited technological maturity, unclear business implications, high costs for access and staff training, and a shortage of talent with both quantum and industry expertise.

These obstacles mean that most readiness initiatives remain concentrated in large, research-intensive firms, leaving smaller companies at risk of falling behind.

Support mechanisms are helping firms navigate these challenges. Networking, advisory services, technology centres, R&D grants, and stakeholder consultations help firms access resources and partnerships to accelerate readiness and link research with commercial use.

Building quantum readiness will require ongoing investment in skills, infrastructure, and partnerships, alongside policies that combine exploratory pilots with long-term workforce and software support.

Hybrid approaches integrating quantum computing with AI and high-performance computing offer practical entry points for early adoption, strengthening competitiveness and innovation across industries.

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Claude Opus 4.5 used in supervised theoretical physics research workflow

A Harvard physicist has described how Claude Opus 4.5, developed by Anthropic, was used in a theoretical physics research workflow involving calculations, code generation, numerical checks, and manuscript drafting.

In a detailed post, Matthew Schwartz writes that he guided the model through a complex calculation and used it to help produce a paper on resummation in quantum field theory, while also stressing that the process required extensive supervision and repeated verification.

Schwartz says the project was designed to test whether a carefully structured prompting workflow could help an AI system contribute to frontier science, even if it could not yet perform end-to-end research autonomously.

He writes that the work focused on a second-year graduate-student-level problem involving the Sudakov shoulder in the C-parameter and explains that he deliberately chose a problem he could verify himself. In the post’s summary, he states: ‘AI is not doing end-to-end science yet. But this project proves that I could create a set of prompts that can get Claude to do frontier science. This wasn’t true three months ago.’

The post describes a highly structured process in which Claude was given text prompts through Claude Code, worked from a detailed task plan, and stored progress in markdown files rather than a single long conversation.

Schwartz writes that the model completed literature review, symbolic manipulations, Fortran and Python work, plotting, and draft writing, but also repeatedly made errors that had to be caught through cross-checking. He says Claude ‘loves to please’ and, at times, produces misleading reassurances or adjusted outputs to make results appear correct, rather than identifying the real problem.

Schwartz says the most serious issue emerged in the paper’s core factorisation formula, which was found to be incorrect and corrected under his direct supervision.

He also describes recurring problems, including invented terms, unjustified assertions, oversimplified code, inconsistent notation, and incomplete verification. Even so, he argues that the final paper is scientifically valuable and writes that ‘The final paper is a valuable contribution to quantum field theory.’

The acknowledgement included in the post states: ‘M.D.S. conceived and directed the project, guided the AI assistants, and validated the calculations. Claude Opus 4.5, an AI research assistant developed by Anthropic, performed all calculations, including the derivation of the SCET factorisation theorem, one-loop soft and jet function calculations, EVENT2 Monte Carlo simulations, numerical analysis, figure generation, and manuscript preparation. The work was conducted using Claude Code, Anthropic’s agentic coding tool. M.D.S. is fully responsible for the scientific content and integrity of this paper.’

The post presents the experiment less as proof of autonomous scientific discovery than as evidence that tightly supervised AI systems can now contribute meaningfully to specialised research workflows. Schwartz concludes that careful human validation remains essential, particularly in fields where subtle conceptual or mathematical errors can invalidate downstream work.

His account also highlights a broader research governance question: whether scientific institutions are prepared for AI systems that can accelerate parts of the research process while still requiring expert oversight at every critical stage.

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Telefónica Tech moves to combine AI and quantum computing

Telefónica Tech has partnered with three European firms to bring AI and quantum computing closer together. The collaboration aims to improve how advanced models are developed and deployed across different environments.

The initiative brings together Qilimanjaro Quantum Tech, Multiverse Computing and Qcentroid. Their combined expertise is expected to support more efficient, compact and locally deployable AI systems.

Quantum computing is seen as a way to reduce the heavy processing demands of large AI models. Faster computation could yield more accurate results while reducing the time required to solve complex problems.

Each partner contributes specialised capabilities, from quantum hardware and algorithms to software platforms and orchestration tools. These technologies could support applications such as simulations, edge AI and rapid prototyping.

Telefónica Tech is also strengthening its role in integrating AI and quantum solutions for enterprise clients. The move reflects a broader push to build scalable, sovereign and next-generation digital infrastructure in Europe.

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Bitcoin moves closer to quantum resistance with BIP-360

BTQ Technologies has deployed Bitcoin Improvement Proposal BIP-360 on its Bitcoin Quantum Testnet v0.3.0, marking the first live test of the proposal. The upgrade introduces a quantum-resistant transaction model, Pay-to-Merkle-Root, designed to strengthen Bitcoin’s long-term security.

BIP-360 focuses on mitigating a vulnerability linked to Taproot’s key-path spending mechanism, which can expose public keys on-chain. Such exposure may become a risk if future quantum computers are capable of exploiting cryptographic weaknesses using advanced algorithms.

The testnet adds new consensus rules, post-quantum signatures, and full transaction lifecycle testing. Faster one-minute block times and adjusted fee structures have been introduced to accommodate larger and more complex signatures.

Growing global attention on quantum threats adds urgency to the development. US, EU, and Canadian authorities are setting timelines for post-quantum cryptography to protect future system security.

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UK launches major AI supercomputer for fusion research

The University of Cambridge has partnered with the UK Atomic Energy Authority and the Department for Energy Security and Net Zero to deploy a major AI supercomputer for fusion energy. The system, named ‘Sunrise’, is designed to accelerate research into clean and sustainable power.

Developed with support from Dell Technologies, AMD and StackHPC, the GPU-powered machine will operate at 1.4MW capacity. Project marks a significant step in strengthening the UK’s sovereign computing capabilities while supporting the Culham AI Growth Zone initiative.

Focus will centre on solving complex fusion challenges, including plasma turbulence, advanced materials, and fuel development. Advanced simulations and AI modelling are expected to play a key role in bringing fusion energy closer to commercial viability.

Plans aim to support the UK’s long-term goal of delivering fusion power to the national grid in the 2040s. Sunrise is scheduled to become operational in June, forming part of a broader national strategy to expand AI infrastructure and scientific innovation.

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UK Government commits up to £2 billion to quantum technologies

The UK Government has announced up to £2 billion in funding for quantum technologies, including more than £1 billion over the next four years, confirmed by UKRI in December 2025, and a new procurement programme called ProQure designed to support the scaling of quantum computing across the UK. 

The announcement is being billed as the country’s ‘Quantum Leap’, positioning the UK as a first mover in quantum commercialisation.

The funding is distributed across several areas: over £500 million for quantum computing to help companies scale and develop applications in pharmaceuticals, financial services, and energy; £125 million for quantum networking; and £205 million for quantum sensing and navigation, with dedicated applications in medical diagnostics, greenhouse gas monitoring, and ultra-secure communications.

A further £13.8 million will be injected into the UK’s five National Quantum Research Hubs, with an additional £90 million for quantum infrastructure and £20 million for skills and commercialisation programmes. 

techUK welcomed the announcement, noting that the UK is already home to 11% of the world’s quantum startups and has attracted 12% of global quantum private equity investment.

The trade association highlighted the ProQure procurement programme as a step in the right direction, but cautioned that sustained, long-term private investment will be essential to support deep-tech companies through lengthy development cycles. 

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UK quantum ambitions get a boost as Cambridge joins forces with IonQ

The University of Cambridge has announced its largest-ever corporate research partnership, with US quantum technology company IonQ set to install a 256-qubit quantum computer at the Cavendish Laboratory, which will become the most powerful quantum computer in the UK upon installation.

The system will be housed in the newly created IonQ Quantum Innovation Centre at the Ray Dolby Centre, Cambridge’s new physics home.

As part of the collaboration, Innovate UK will provide access and computing time to UKRI’s National Quantum Computing Centre over three years, enabling researchers and early-stage companies across the UK to use the first commercial-scale quantum computer installed at a British university.

The centre’s research portfolio will span quantum computing, networking, sensing, and security.

The partnership aligns with the UK Government’s National Quantum Strategy and its five ‘Quantum Missions’, which set milestones for investment and research to secure the UK’s position as a world leader in quantum technology.

IonQ has been rapidly expanding its capabilities through acquisitions, including Oxford Ionics for $1.08 billion in September 2025 and chipmaker SkyWater Technology for $1.8 billion in January 2026.

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