Xanadu ETRI Partner on Fault-Tolerant Quantum Computing Software

Celebrating World Quantum Day 💫 What does it take to build the future of quantum communications? ORNL research scientist Joseph Chapman explains how quantum communications enables connections between quantum computers and sensors by preserving fragile properties like entanglement and superposition. At Oak Ridge National Laboratory, researchers are moving this technology beyond the lab, demonstrating quantum networking over real-world fiber infrastructure and expanding to include free-space links for longer-distance communication. Learn more https://lnkd.in/gvfmYYgS #WorldQuantumDay #BigScience #QuantumComputing

Happy World Quantum Day!⚛️ From quantum computing to quantum networking, Oak Ridge National Laboratory researchers are unlocking new ways to solve complex challenges in energy, materials, national security, and beyond. 🔗Decades of Quantum Innovation: https://bit.ly/4tMKcSB #WorldQuantumDay #QuantumComputing

Alice & Bob has secured a $3.9 million award from the U.S. Department of Energy’s ARPA-E QC3 program to develop fault-tolerant quantum algorithms for discovering rare-earth-free permanent magnets, in collaboration with Los Alamos National Laboratory, GE Vernova Advanced Research, and Professor Emanuel Gull. Led by co-founders Théau Peronnin and Raphaël Lescanne, Alice & Bob is building fault-tolerant quantum computers based on cat qubits, a hardware-efficient architecture designed to cut the resources needed for large-scale quantum computing. More at: https://lnkd.in/eW__6A_B #QuantumComputing #DeepTech #ClimateTech #EnergyTransition

Chinese Academy of Sciences Demonstrates Universal Gate Operation Exceeding Fault-Tolerance Threshold Researchers at the Chinese Academy of Sciences have designed a quantum bus, utilizing engineered virtual photons to connect spin and superconducting modules. This bus enables universal gate operation between modules in 40 nanoseconds, achieving 99.05% fidelity and surpassing the fault-tolerance threshold. #quantum #quantumcomputing #technology https://lnkd.in/ehPQU4hf

Today we announce a multi-year expansion of our partnership with the University of Maryland Quantum Lab (QLab), extending our joint efforts in quantum computing, quantum networking and workforce development. This next step in the ongoing collaboration deepens our integration with UMD researchers and students, positioning QLab as a leading testbed for next-generation quantum technologies, including quantum networking and memory systems – specifically, the first deployment of IonQ’s silicon vacancy (SiV)-based quantum memory node. Read the full announcement: https://lnkd.in/ernEs44S #WorldQuantumDay

An enhanced understanding of the laws of quantum mechanics is enabling a quantum revolution that promises to transform a vast range of technologies critical to American competitiveness. By hosting a multidisciplinary team of world-renowned researchers, Oak Ridge National Laboratory is empowering scientists to pursue quantum innovation via theoretical and experimental research efforts, from the merger of quantum and classical computing architectures to designing and deploying secure, next-generation networks to developing more precise sensors. Through the lab’s broad quantum expertise and the renewal of DOE’s Quantum Science Center, ORNL is enabling the quantum future and building the diverse quantum workforce of tomorrow. With diverse capabilities to support materials synthesis, fabrication, and characterization, ORNL researchers are exploring new approaches to storing, measuring, and transferring information via four primary capabilities: quantum computing, quantum materials, quantum networking, and quantum sensing. https://lnkd.in/eKb2x2JU

An enhanced understanding of the laws of quantum mechanics is enabling a quantum revolution that promises to transform a vast range of technologies critical to American competitiveness. By hosting a multidisciplinary team of world-renowned researchers, ORNL is empowering scientists to pursue quantum innovation via theoretical and experimental research efforts, from the merger of quantum and classical computing architectures to designing and deploying secure, next-generation networks to developing more precise sensors. Through the lab’s broad quantum expertise and the renewal of DOE’s Quantum Science Center, ORNL is enabling the quantum future and building the diverse quantum workforce of tomorrow. https://lnkd.in/eKb2x2JU

An enhanced understanding of the laws of quantum mechanics is enabling a quantum revolution that promises to transform a vast range of technologies critical to American competitiveness. By hosting a multidisciplinary team of world-renowned researchers, ORNL is empowering scientists to pursue quantum innovation via theoretical and experimental research efforts, from the merger of quantum and classical computing architectures to designing and deploying secure, next-generation networks to developing more precise sensors. Through the lab’s broad quantum expertise and the renewal of DOE’s Quantum Science Center, ORNL is enabling the quantum future and building the diverse quantum workforce of tomorrow. https://lnkd.in/efP6tZSb.

A 200-Year-Old Optical Trick Just Scaled Quantum Encryption Quantum Key Distribution (QKD) promises unhackable data transmission, but scaling it over long distances has been plagued by hardware instability and signal degradation. That just changed, thanks to a 200-year-old physics concept! Researchers have leveraged classic optical interference to stabilize quantum signals, allowing highly efficient QKD over existing commercial fiber-optic networks. This bridges the gap between theoretical quantum security and practical enterprise deployment. For global life sciences, this is a massive leap forward: Biotech consortiums and research hospitals can now establish unhackable, long-range networks to transmit massive genomic datasets and proprietary clinical trial data, ensuring absolute data sovereignty. 🔗 Read the details here: https://lnkd.in/eE6WR7sY

Soomin Moon, Ghazi Khan, Samuel T. Elkin, Christopher J. Ryu, Dong-Yeop Na, and Thomas Roth highlight the potential of quantum technologies to transform computing, communication, and sensing, while identifying hardware design as a key bottleneck. Computational quantum electromagnetics (CQEM) addresses this challenge through physics-based modeling, enabling efficient design and accelerating next-generation quantum systems. Read it at: https://lnkd.in/djgX49nz #ieeeaps #ieeeapm #electromagnetics #quantum #computational #hardware