A review of major developments across quantum computing, communications, sensing, industry investment and policy through 2025, including technical milestones, standardization efforts and the shifting landscape from laboratory research to early commercial deployments.
A journalistic survey of major developments, scientific context and technological breakthroughs in quantum science and technology through 2025, with analysis, data and expert perspectives.
UNESCO's designation of an International Year of Quantum Science and Technology aims to spotlight advances in quantum research and accelerate international coordination on policy, funding and education. This article examines the scientific landscape, economic projections, national programs, ethical and security considerations, and the challenges ahead.
As the International Year of Quantum Science and Technology prompts quizzes and conversations in outlets such as Physics World, scientists and policymakers reflect on achievements, remaining hurdles and the need for public engagement to steer the field responsibly.
The University of Colorado Boulder research center announced a five-year plan to advance quantum technologies across computing, sensing and networking, emphasizing infrastructure, partnerships and workforce development while building on the institution's long-standing strengths in atomic, molecular and optical physics.
Researchers report methods to convert optically inactive 'dark' light-matter states into emissive modes, a development that could extend coherence times and enable new quantum photonic devices.
An analytical review of topics and trends reflected in the American Institute of Physics' weekly coverage for Oct 20, 2025, placing that coverage in historical and policy context and assessing implications for research, technology and science policy.
In a landmark advancement for quantum computing, scientists have achieved stable control over spin qubits at temperatures close to absolute zero. This development drastically improves the feasibility of scalable, reliable quantum machines, setting a foundation for powerful computational systems of the future.
On June 24, 2025, IBM and Japan’s RIKEN launched the first IBM Quantum System Two outside the U.S., featuring a powerful 156-qubit Heron processor. This system represents a major leap toward scalable quantum computing, offering enhanced error correction and performance for hybrid quantum-classical workloads.
In a major breakthrough, researchers at the University of Osaka have introduced a cutting-edge "zero-level magic state distillation" method. This innovation dramatically lowers noise and resource requirements in quantum systems, paving the way for more stable and scalable fault-tolerant quantum computers.
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