Scientists at Monash University have created a tiny new circuit that can generate, direct, and read information carried by light, all within a single chip.The advance marks a significant milestone for a growing area of research known as "valleytronics," which could help drive future breakthroughs in faster computing, lower energy consumption, and quantum technologies.Developed by researchers from the Monash School of Physics and Astronomy, the new device combines advanced nanotechnology with cutting-edge materials to solve a challenge that has limited the field for years.For the first time, the team has built a fully integrated chip capable of producing specialized light signals, steering them along specific paths, and converting them into electrical signals within the same compact system.These signals store information using a quantum property called the "valley degree of freedom." Scientists believe this unique characteristic could provide entirely new ways to encode, transmit, and process data.Integrated Valleytronics Chip Solves Long-Standing ChallengeLead author Dr. Chi Li, whose team's findings were published in Nature Photonics, said the achievement addresses a major obstacle in valleytronics research."Until now, we could generate or detect these signals, but not do everything in one integrated device," Dr. Li said."What we've built is a complete on-chip system that can create, route and read this information with very high precision."The device relies on ultra-thin materials that are only a few atoms thick. These materials are paired with specially engineered nanostructures designed to precisely control light at extremely small scales.Dr. Kaijian Xing, co-first author of the study and a Research Fellow at Monash University, explained that the team developed a practical way to combine these components."We employ a straightforward stacking approach to integrate ultra-thin materials with metasurfaces, overcoming the technical challenges of direct material growt

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New Light-powered Chip Could Accelerate AI and Quantum Computing

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Entropy 2026 is the third edition of the International Conference on Entropy and Its Applications, taking place in Barcelona from July 1 to 3, 2026. The event focuses on the intersection of entropy, information theory, statistical physics, and quantum science, with a dedicated session on Quantum Information and Quantum Computing. Featuring keynotes from experts like Prof. Ariel Caticha on entropic quantum gravity and others on quantum chaos and NISQ systems, it offers a unique opportunity for in-depth discussions. Registration is open until June 15, 2026, for this fully in-person conference at the Barcelona School of Management. The post Entropy 2026: Exploring Quantum Information, Complexity, and the Foundations of the Quantum Future in Barcelona appeared first on The Qubit Report.

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Entropy 2026: Exploring Quantum Information, Complexity, and the Foundations of the Quantum Future in Barcelona

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Insider Brief The QScale project, led by VTT with Tampere University and Aalto University, has received funding from Business Finland to develop technologies aimed at improving the energy efficiency and scalability of quantum computers. Researchers will combine optical control, optical telecommunications technologies, and superconducting signal-generation systems to support large-scale quantum computing architectures. The three-year project will begin in September 2026 with a total budget of approximately €6.9 million, including €5.5 million from Business Finland. Photo from Pexels by Engin&nbsp;Akyurt. PRESS RELEASE — The QScale joint project coordinated by VTT with Tampere and Aalto Universities has received funding from Business Finland’s prestigious Rise to Challenge Programme. In the project, researchers are developing a radical improvement in the energy efficiency and scalability of quantum computers through optical control and ultra-precise signal technology based on quantum phenomena. The anticipated breakthrough of quantum technologies into societally impactful applications still requires major research openings such as QScale. In theory, quantum computers are known to be capable of calculations that are impossible for classical computers. This is why they are expected to enable breakthroughs in fields such as chemistry, bioscience and artificial intelligence. One of the most promising approaches – and the most significant one for Finland nationally – is the superconducting quantum computer. Industrial development of quantum computers is progressing rapidly, but current technology becomes difficult when scaling beyond 1,000 qubits and impossible if the goal is one million qubits. Yet that is the scale needed to fulfil the promises made for quantum computing. With current technology, the energy consumption of such a quantum computer would be comparable to the output of an entire nuclear reactor, making it practically impossible to implement. QScale combines 

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Finland Launches QScale Project to Advance Quantum Computing Scalability

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Quantum eMotion Reports Q1 2026 Financial Results: Entry into Early Commercialization and Strategic U.S. Cybersecurity Acquisition Quantum eMotion Corp. (NYSE: QNC; TSXV: QNC-V) has released its unaudited condensed interim consolidated financial statements for the first quarter ended March 31, 2026. The Montreal-based developer of hardware-agnostic Quantum Random Number Generators (QRNG) highlighted its first recorded commercial revenues and an expansion of its cryptographic portfolio. As noted by management, the company presents its financial statements in Canadian Dollars (CAD). To assist with industry-wide tracking, the table below provides the raw reported CAD figures alongside their corresponding values in United States Dollars (USD), based on the current exchange rate of $1.00 CAD = $0.72 USD. Amounts in $MQ1’2026 (CAD)Q1’2026 (USD)Q1’2025 (CAD)% Change (CAD)Revenue$0.011$0.008$0.000—Operating Expenses$3.88$2.79$3.34+16.2%Operating Loss($3.87)($2.79)($3.34)+15.9%Net Loss($3.59)($2.58)($3.35)+7.2%Cash and Short Term Investments$37.40$27.01$39.19 (12/31/2025)-4.6% Financial Overview and Commercial Inflection For the three months ended March 31, 2026, Quantum eMotion recognized its first early commercial revenue of $10,582 CAD ($7,619 USD), moving past its pure research-and-development phase. Operating expenses ticked up 16.2% to $3.88 million CAD, driven by an expansion of general corporate infrastructure required to support its recent listing transitions and target vertical captures. The GAAP Net Loss widened slightly to ($3.59) million CAD, or ($0.016) per share, compared to ($3.35) million CAD in Q1 2025. This loss was partially mitigated by a significant Net Financial Income swing of $298,879 CAD, generated by higher yield returns on the company’s capital deployment allocations. QeM’s total liquidity position remains exceptionally stable at $37.40 million CAD ($27.01 million USD) in combined cash and liquid short term investments. This cash cushion is a dire

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Quantum eMotion Reports Q1 2026 Financial Results: Entry into Early Commercialization and Strategic U.S. Cybersecurity Acquisition

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Spin-only dynamics of the multi-species nonreciprocal Dicke model, by Joseph Jachinowski, Peter B. Littlewood

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Entropy 2026: Exploring Quantum Information, Complexity, and the Foundations of the Quantum Future in Barcelona

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New Light-powered Chip Could Accelerate AI and Quantum Computing

Entropy 2026: Exploring Quantum Information, Complexity, and the Foundations of the Quantum Future in Barcelona

Finland Launches QScale Project to Advance Quantum Computing Scalability

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