Scientists at Oak Ridge National Laboratory have developed the first all-in-one chip for quantum internet, integrating multiple quantum photonic functions. This innovation enables the generation of broadband entangled qubits compatible with existing fiber-optic networks, paving the way for a scalable and secure quantum internet.
Researchers have developed an innovative method to accelerate quantum measurements by utilizing a space-time trade-off. This approach, involving auxiliary qubits, significantly reduces measurement time while maintaining or improving accuracy, addressing critical challenges in quantum computing, such as error rates and qubit stability, essential for advancing emerging quantum technologies.
Aparna Thakur’s research introduces a transformative framework that combines AI with quantum-resistant cryptography to enhance financial transaction security. This innovative approach addresses vulnerabilities posed by quantum computing, improves payment reconciliation efficiency, and strengthens fraud detection, paving the way for a secure and scalable future in global finance.
The Department of Science and Technology has established four Thematic Hubs focused on key quantum computing technology areas across various Indian institutes. These hubs aim to foster collaboration among academic institutions and private industry, enhancing research and development in quantum technologies, including quantum communication and sensing.
A new superconducting state has been discovered, revealing a spatial modulation of the superconducting gap in iron-based materials. This breakthrough, achieved through advanced microscopy techniques, suggests that superconductivity may occur at atomic scales, potentially paving the way for room-temperature superconductors and advancements in quantum computing and energy technologies.
The Quantum Computing In Energy And Utility Market is set to achieve significant growth, with a projected compound annual growth rate of 4.34% from 2025 to 2034. This report provides insights into market dynamics, key players, and emerging trends, essential for stakeholders navigating this evolving industry landscape.
The National Institute of Standards and Technology has selected SandboxAQ’s Hamming Quasi-Cyclic algorithm as part of its post-quantum cryptography standards. This algorithm, designed for secure key exchange, offers robust protection against quantum attacks, ensuring the confidentiality of communications in critical sectors like finance and healthcare.
JPMorgan Chase and Quantinuum have showcased a groundbreaking application of quantum computing by generating certifiable randomness. This advancement is crucial for enhancing cybersecurity, ensuring unpredictability in cryptographic keys, and supporting various applications, including digital communication and data privacy. The findings highlight significant progress in quantum technology and its real-world implications.
Quantinuum, in collaboration with JPMorganChase and several national laboratories, has achieved true verifiable randomness through quantum computing, enhancing cybersecurity. This breakthrough allows for faster verification compared to classical methods, paving the way for new commercial products aimed at providing secure, certifiably random seeds for various enterprises.
The National Institute of Standards and Technology has selected Florida Atlantic University’s Hamming Quasi-Cyclic (HQC) for standardization in its Post-Quantum Cryptography project. HQC offers quantum-resistant security, ensuring secure key exchange and safeguarding digital communications against future threats posed by quantum computing. This marks a significant advancement in cryptographic standards.
