Latest news with #quantum
Yahoo
3 days ago
- Business
- Yahoo
ÉTS Announces the Creation of Its New Institute of Quantum Science and Engineering
MONTREAL, June 17, 2025 /CNW/ - For the launch of the QUANTUM NOW event, taking place in Montreal on June 18 and 19, the École de technologie supérieure (ÉTS) is announcing the creation of its new Institute of Quantum Science and Engineering, the Tensor Institute. This ambitious project benefits from $5 million in financial backing from Quebec's Ministère de l'Économie, de l'Innovation et de l'Énergie, with the aim of positioning the Institute as a world-class centre for applied quantum research and education and of supporting initiatives valued at $19.1 million. A major partnership already ÉTS is also proud to announce a strategic partnership with Finnish company QMill, a world leader in quantum algorithm development. This collaboration will provide the means to design, test and validate algorithms applicable to real-life industry scenarios, paving the way for the demonstration of a tangible quantum advantage. The Institute will be participating in QUANTUM NOW, Canada's first executive forum devoted entirely to the strategic and economic stakes involved in quantum technologies. Geared towards business, government and investment leaders, the event will give them the strategic intelligence and networking opportunities they need to thrive in the emerging quantum economy. Organized by Quantum Industry Canada, in partnership with DistriQ (the Quantum Innovation Zone of Sherbrooke), QUANTUM NOW is officially recognized as a global "Industry and Innovation" event of the United Nations International Year of Quantum Science and Technology. A defining vision for Quebec To support this vision, four applied research chairs will be created, two of which have already been awarded to Professor Jacob Biamonte, who is also the Institute's Scientific Director, and to Professor Claude Crépeau. These chairs will actively contribute to strengthening research capacities and enhancing expertise within the student, scientist and educator communities. They will also enable greater collaboration with industry by grounding research projects in concrete, strategic needs for Quebec's economy. In partnership with Quebec's rich quantum ecosystem, notably the Université de Sherbrooke's Institut quantique, ÉTS will develop a curriculum tailored to university students and to professionals already working in the field. Specialized programs will be put in place to meet growing demand for skills, particularly for programmers, engineers and technology experts. Thanks to a cooperative model and an approach focusing on applied research in close collaboration with industry, ÉTS is particularly well positioned to spur on the emergence of innovative technological solutions and support the growth of a competitive and enduring quantum industry. By helping to develop talent, the next generation, and key skills in research and innovation in a strategic sector such as quantum science, ÉTS's initiatives closely align with the objectives of the 2022-2027 Québec strategy to support research and investment in innovation. Quotes "Québec is establishing a strong global reputation for its excellence in quantum, thanks to the dynamism and quality of its research and innovation community, including the active involvement of ÉTS. We are extremely proud to support this new institute, which will bolster our expertise and foster the development of quantum talent, nurture the next generation, and cultivate essential skills in this promising field." Christopher Skeete, Minister Delegate for the Economy, Minister Responsible for the Fight Against Racism, and Minister Responsible for the Laval Region "The launch of our Quantum Institute marks a pivotal milestone for ÉTS and for Quebec's innovation ecosystem. ÉTS aims to play a strategic role in strengthening Quebec's position as a global leader in quantum technologies, notably through collaboration with key players in the field, including the Institut quantique at Université de Sherbrooke. By leveraging ÉTS's recognized excellence in applied research and engineering, and through strategic partnerships such as the one with QMill, we aim to create a unique environment that meets industry needs and accelerates the adoption of quantum technology solutions." Christian Casanova, Executive Director of Research and Partnerships, ÉTS "QMill is excited to enter the Canadian quantum ecosystem and make quantum computing practical and accessible for customers in energy, logistics and telecommunications industries already in the near term." Dr. Hannu Kauppinen, CEO and Co-Founder of QMill. "This is an amazing win-win partnership to demonstrate together emerging quantum-advantage algorithms. We are committed to disrupting the quantum-algorithm toolbox and a long-term effort." Prof. Mikko Möttönen, Chief Scientist and Co-Founder of QMill. SOURCE École de technologie supérieure View original content to download multimedia: Error in retrieving data Sign in to access your portfolio Error in retrieving data Error in retrieving data Error in retrieving data Error in retrieving data
Yahoo
4 days ago
- Business
- Yahoo
Entangled Networks Market Research Report 2026-2040 Featuring Tech Giants Such as IBM and Google, Alongside Specialized Startups like IonQ and Qunnect
Key players include tech giants like IBM and Google, alongside specialized startups like IonQ and Qunnect. As the field transitions from research to early commercial applications, government and venture capital investments are bolstering development. Notable strides are being made in quantum repeaters and quantum key distribution (QKD), crucial for expanding network reach and security. The market's promise includes applications in distributed quantum computing, secure communications, and the Quantum Internet of Things (QIoT), with forecast growth from 2026-2040. Key challenges include quantum fragility, regulatory complexities, and workforce shortages. However, anticipated technological breakthroughs and increased investment signal a dynamic future for entangled networks. Dublin, June 17, 2025 (GLOBE NEWSWIRE) -- The "The Global Entangled Networks Market 2026-2040" report has been added to offering. The Global Entangled Networks Market 2026-2040 represents the next frontier in quantum communication and computing infrastructure, with unprecedented growth opportunities driven by technological breakthroughs and increasing demand for ultra-secure communications. This comprehensive market research report provides in-depth analysis of the quantum networking ecosystem, featuring detailed forecasts, competitive intelligence, and strategic recommendations for stakeholders across the quantum technology value chain. The entangled networks market stands as one of the most transformative technological arenas of the 21st century, radically redefining how information systems achieve new heights in security, computational power, and precision through quantum mechanics. Although the Quantum Internet concept remains in its nascent stage with varying definitions, the market opportunity is taking shape around a vital architectural principle: networks where quantum nodes maintain entangled states via specialized interconnects, creating outcomes unattainable with classical networking technologies. Emerging from the synergy of quantum physics, advanced telecommunications, and cutting-edge computing architectures, the entangled networks market distinguishes itself by utilizing quantum mechanics for secure communication channels and enhanced computational capabilities. This evolution encompasses a diverse ecosystem, including tech giants like IBM and Google, specialized startups like Aliro Quantum and IonQ, and traditional telecom providers aiming to upgrade their infrastructure. Defense contractors, financial organizations, and research bodies converge in this space to push the boundaries of security and computational innovation. The market is moving from research and development to early commercial use, fueled by significant global investments. Countries like the United States, European Union, and China have pledged substantial funding, highlighting quantum networks' strategic importance for national security and economic competitiveness. Developing infrastructure for these networks involves quantum processors, repeaters, specialized photonic sources, quantum memories, and ultra-sensitive detectors. Technological challenges are notable, with quantum entanglement being highly fragile and susceptible to environmental disruptions. Overcoming these hurdles requires advanced error correction protocols, cryogenic cooling, and precisely controlled environments. With quantum repeater technology in large part still under development, satellite-based systems play a crucial role in long-distance communication, despite their own complexities. The development of quantum repeaters is a pivotal milestone, expected to shift long-distance communication from satellite reliance to terrestrial networks. This technological advancement is essential for achieving global reach and enhancing market infrastructure. Distributed quantum computing emerges as a significant near-term opportunity, allowing organizations to connect multiple quantum processors and tackle problems beyond the capabilities of single quantum computers. Early applications span optimization problems, cryptographic issues, drug discovery, and AI research. Quantum key distribution represents another critical market segment, offering theoretically unbreakable encryption. This tech is vital for government agencies, financial institutions, and entities requiring top-tier data security. The Quantum Internet of Things (QIoT) also presents transformative potential, promising unprecedented precision in various fields through quantum sensor networks. Geographically, the United States, China, and the European Union lead in both research investments and commercial development. Initiatives like the National Quantum Initiative Act, the EU's Quantum Technologies Flagship program, and China's extensive infrastructure projects illustrate the competitive global landscape. These efforts shape the market dynamics and highlight governmental collaboration to fortify their positions in quantum technology development. Despite the promising trajectory, the market faces significant barriers. Technical challenges demand precise environmental controls and robust protocols, translating into high infrastructure costs and complex operational needs. Regulatory issues, including national security considerations and technology transfer restrictions, add complexity to global market development. Additionally, the quantum field necessitates specialized skills, with workforce availability influencing growth and cost dynamics for market entrants. Investment influx from government funds, venture capital, and corporate R&D plays a crucial role, with government dollars particularly significant in fostering early-stage development. The market looks towards substantial growth in the next decade, driven by technological maturation, investment increases, and diverse applications. Forecasts suggest transitioning from research-centric to broad commercial deployment by the early 2030s, with quantum repeaters marking a pivotal expansion point. Overall, the entangled networks market presents vast opportunities. The evolution toward a Quantum Internet of Things—integrating quantum-enhanced sensing, communication, and computation—holds the potential to revolutionize various industries and applications, offering capabilities that exceed classical technological constraints. The future promises a dynamic landscape enriched by technological breakthroughs and demand for ultra-secure communications, shaping a new era in quantum communication and computing infrastructure. Key Market Insights and Analysis Market Size and Revenue Projections Market Value Growth: Comprehensive 15-year forecast spanning 2026-2040 with detailed revenue projections across multiple market segments Equipment Market Analysis: Breakdown of revenue generation by quantum networking equipment types including quantum computers, repeaters, and communication devices Network Reach Segmentation: Market analysis covering local area networks, metropolitan networks, and long-haul quantum communication systems Transmission Technology Assessment: Comparative analysis of fiber-optic, satellite-based, and free-space quantum communication methodologies Technology Development and Innovation Pipeline Quantum Repeater Evolution: Timeline and roadmap for commercial deployment of quantum repeaters enabling long-distance entanglement distribution Distributed Quantum Computing: Analysis of networked quantum computer architectures and their commercial applications Quantum Internet of Things (QIoT): Emerging applications in quantum sensor networks and metrology systems Protocol Standardization: Development status of quantum networking protocols and industry standards Application Sectors and Use Cases Secure Communications: Quantum key distribution (QKD) systems and ultra-secure communication networks for government and enterprise applications Financial Services: Quantum-safe cryptography and secure transaction processing systems Healthcare and Research: Quantum sensor networks for medical imaging and scientific research applications Defense and Government: National security applications and secure military communication systems Academic Research: University and research institution quantum networking testbeds and experimental platforms Competitive Landscape and Market Players Comprehensive profiles of 40 leading quantum networking companies and their product portfolios. Investment Analysis and Funding Landscape Government Funding: Multi-billion dollar government investment programs supporting quantum technology development Private Investment: Venture capital and private equity funding trends in quantum networking startups Corporate R&D: Technology company research and development spending on quantum networking technologies ROI Projections: Return on investment analysis for different quantum networking application sectors Market Challenges and Growth Barriers Market Scenarios Optimistic Growth Scenario: Accelerated technology development and widespread commercial adoption timeline Conservative Projections: Realistic market development considering technical and commercial challenges Disruptive Technology Impact: Potential breakthrough technologies that could reshape the quantum networking landscape Long-term Evolution: Market structure and competitive dynamics through 2040 Competitive Landscape: A Selection of Companies Mentioned in This Report Includes COMPANY PROFILES (43 company profiles) ACADEMIA AND RESEARCH 194 (25 profiles) Aliro Quantum AWS Center for Quantum Networking (CQN) Boeing BT Group Cisco Systems Covesion evolutionQ IBM Icarus Quantum ID Quantique Infleqtion IonQ Ki3 Photonics Technologies L3Harris levelQuantum LQUOM MagiQ Technologies memQ NanoQT Nippon Telegraph and Telephone Corporation (NTT) Nu Quantum Photonic PQSecure PQShield QphoX QTD Systems Quandela Quantum Bridge Technologies Quantum Corridor For more information about this report visit About is the world's leading source for international market research reports and market data. We provide you with the latest data on international and regional markets, key industries, the top companies, new products and the latest trends. CONTACT: CONTACT: Laura Wood,Senior Press Manager press@ For E.S.T Office Hours Call 1-917-300-0470 For U.S./ CAN Toll Free Call 1-800-526-8630 For GMT Office Hours Call +353-1-416-8900Error in retrieving data Sign in to access your portfolio Error in retrieving data Error in retrieving data Error in retrieving data Error in retrieving data
Yahoo
5 days ago
- Science
- Yahoo
Light Squeezed Out of Darkness in Surprising Quantum Simulation
A careful alignment of three powerful lasers could generate a mysterious fourth beam of light that is throttled out of the very darkness itself. What sounds like occult forces at work has been confirmed by a simulation of the kinds of quantum effects we might expect to emerge from a vacuum when ultra-high electromagnetic fields meet. A team of researchers from the University of Oxford in the UK and the University of Lisbon in Portugal used a semi-classical equation solver to simulate quantum phenomena in real time and in three dimensions, testing predictions on what ought to occur when incredibly intense laser pulses combine in empty space. "This is not just an academic curiosity – it is a major step toward experimental confirmation of quantum effects that until now have been mostly theoretical," says Oxford physicist Peter Norreys. Laser technology has come a long way since its invention a little over half a century ago. Focussing petawatts of power in mere instants of time, they're theorized to be capable of literally shaking matter out of the very fabric of reality itself. What we think of as empty space is – on a quantum level – an ocean of possibility. Fields representing all kinds of physical interactions hum with the promise of particles we'd recognize as the foundations of light and the building blocks of matter itself. These virtual particles essentially pop into and out of existence in fractions of a second. All it takes for them to manifest longer-term is the right kind of physical persuasion that discourages them from canceling one another out; the kind of persuasion a series of strong electromagnetic fields might provide when arranged in a suitable fashion, for example. To determine whether predictions on the power of lasers could indeed generate something from nothing, Norreys and his team ran computational models based on the mathematics underpinning electromagnetic fields in a vacuum. Plugging numbers into their solver revealed that blending three suitably strong laser beams and their electromagnetic fields can generate a level of polarization that forces virtual photons to part before they blur out of existence. Known as four-wave mixing, the scattered photons would appear as a fourth beam of light. This kind of photon-photon scattering has long been predicted as possible, yet attempts to observe it in reality have so far proven ineffective. "By applying our model to a three-beam scattering experiment, we were able to capture the full range of quantum signatures, along with detailed insights into the interaction region and key time scales," says the study's lead author, physicist Zixin Zhang at Oxford. While the findings are all numerical for now, they do provide a more physically realistic description of what to expect than previous models. We may not need to wait all that long for the results to be put to the ultimate test either. The Extreme Light Infrastructure project in Romania is currently home to the world's most advanced high-power laser infrastructure, already achieving averages of around 10 petawatts in ultrashort bursts of light. Meanwhile, the EP-OPAL project at the University of Rochester in the US has two 25-petawatt beams in the works, with photon-photon scattering experiments already being planned. The Shanghai High repetition rate X-ray Free Electron Laser and Extreme light facility in China also hopes to smash records this year, aiming for 100 petawatts using its free-electron technology. Using nothing but photons to generate the necessary electromagnetic fields, it's hoped the light being scattered out of the darkness won't be hidden in a fog of other particles, finally proving once and for all that it is possible in physics to squeeze something out of nothing. This research was published in Communications Physics. Physicists Actually Made The 'World's Smallest Violin' For a Serious Reason Spiral Magnetism Seen in Synthetic Crystal For The First Time We've Been Misreading a Major Law of Physics For Nearly 300 Years
Yahoo
09-06-2025
- Business
- Yahoo
Quantum Computing Inc. Hosts Ribbon-Cutting to Celebrate Grand Opening of Quantum Photonic Chip Foundry in Tempe, Arizona
Facility Accelerates Multi-Phase Growth Strategy in Quantum and Datacom Markets TEMPE, Ariz., May 13, 2025 /PRNewswire/ -- Quantum Computing Inc. ("QCi" or the "Company") (Nasdaq: QUBT), an innovative, integrated photonics and quantum optics technology company, celebrated the grand opening of its quantum photonic chip foundry located in Tempe, Arizona at a ribbon cutting ceremony on May 12, 2025. The event was attended by Tempe Mayor Corey Woods, along with multiple government officials and industry leaders, who gathered to mark this milestone and highlight the community and industry benefits of the new state-of-the-art facility. "The opening of this foundry by Quantum Computing Inc. represents the kind of forward-looking investment we want to attract to Tempe," said Mayor Corey Woods. "Not only does it bring high-tech jobs and economic development to our city, it also cements Tempe's growing reputation as a hub for innovation in quantum technologies and advanced manufacturing." The facility represents a milestone in QCi's strategic roadmap to meet growing global demand for thin-film lithium niobate (TFLN) photonic chips and accelerate the commercialization of its next-generation quantum machines. Construction of the foundry was completed in March 2025, followed shortly by the finalization of its upgraded ISO certification ahead of schedule. The state-of-the-art facility is now operational, fulfilling existing customer pre-orders, and is positioned to scale production capacity to address rising demand across datacom, telecom, advanced sensing, and quantum computing markets. The Tempe foundry is a specialized facility designed to serve customers seeking U.S.-based manufacturing of high-performance photonic chips, while laying the groundwork to supply critical components for QCi's proprietary quantum computing machines. "The opening of our quantum photonic chip foundry is a milestone achievement in QCi's growth strategy, strengthening our manufacturing capabilities, supporting near and long-term revenue growth, and positioning us to accelerate innovation in both quantum and nanophotonic markets," said Dr. Yuping Huang, Interim Chief Executive Officer of QCi. "By controlling our supply chain and scaling chip production domestically, we are uniquely positioned to deliver value to customers while advancing our own quantum hardware development. I'd like to thank outgoing CEO Dr. Bill McGann for his leadership and dedication in bringing this foundry to completion. It was a privilege to join him at the ribbon cutting ceremony to mark this achievement." QCi's Chief Revenue Officer, Dr. Pouya Dianat commented, "This grand opening is commercially significant to QCi. With the foundry operational, our near-term focus is to fulfill existing customer pre-orders and expand sales across datacom, telecom, and advanced sensing markets. We expect to see modest initial revenue from the fab this year, and as we scale and bring more customers online, we anticipate revenue growth starting to accelerate in 2026." The launch of the Tempe foundry is a cornerstone of QCi's broader multi-phase growth strategy, which includes scaling capacity to meet evolving customer needs, enhancing vertical integration to accelerate internal product development, and expanding into emerging quantum computing markets. About Quantum Computing Inc. Quantum Computing Inc. (Nasdaq: QUBT) is an innovative, integrated photonics and quantum optics technology company that provides accessible and affordable quantum machines and TFLN foundry services to the world today. QCi's products are designed to operate at room temperature and low power at an affordable cost. The Company's portfolio of core technologies and products offer unique capabilities in the areas of high-performance computing, artificial intelligence, and cybersecurity, as well as remote sensing applications. Company Contact: Rosalyn Christian/John Nesbett IMS Investor Relations qci@ Forward-Looking Statements This press release contains forward-looking statements as defined within Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended. These forward-looking statements, generally identified by terms such as "may," "will," "expect," "believe," "anticipate," "estimate," "intends," "goal," "objective," "seek," "attempt," "aim to," or variations of these or similar words, involve risks and uncertainties because they relate to events and depend on circumstances that will occur in the future. Those statements include statements regarding the intent, belief or current expectations of QCi and members of its management as well as the assumptions on which such statements are based. Prospective investors are cautioned that any such forward-looking statements are not guarantees of future performance and involve risks and uncertainties, including the growth rate of the market, timing of revenue recognition and our ability to innovate and deliver products, and that actual results may differ materially from those contemplated by such forward-looking statements. Except as required by federal securities law, QCi undertakes no obligation to update or revise forward-looking statements to reflect changed conditions. View original content to download multimedia: SOURCE Quantum Computing Inc.
Bloomberg
02-06-2025
- Business
- Bloomberg
Atos Gets Offer From French State for Strategic Computing Assets
Atos SE said it received an offer from the French state for the group's advanced computing assets, which values the unit deemed critical to the country's nuclear industry at €410 million ($467 million). The assets include high-performance computing, quantum and artificial intelligence divisions that are expected to generate revenue of about €800 million in 2025, according to a statement on Monday. Atos said it aims to sign a binding agreement in the coming weeks and close the transaction in 2026. The enterprise value includes €110 million in earn-outs based on profitability indicators.
