ICFO researchers, in an international collaboration, have used terahertz light to explore exotic phenomena within magic-angle twisted bilayer graphene. This approach reveals previously unseen behaviors and provides direct insights into the quantum geometry of electronic wavefunctions —the fundamental framework underlying these phenomena.

The NVIDIA Accelerated Quantum Research Center, or NVAQC, announced today at the NVIDIA GTC global AI conference, is where these developments will happen. With an NVIDIA GB200 NVL72 system and the NVIDIA Quantum-2 InfiniBand networking platform, the facility will house a supercomputer with 576 NVIDIA Blackwell GPUs dedicated to quantum computing research.

Researchers at the University of California San Diego have developed a new computational approach to accurately model and predict these complex spin structures using quantum mechanics calculations.

Rigetti, a pioneer in full-stack quantum-classical computing, announced the successful demonstration of real-time and low latency quantum error correction on a Rigetti quantum computer.

In work published in Science Advances, Hayato Goto from the RIKEN Center for Quantum Computing in Japan has proposed a new quantum error correction approach using what he calls “many-hypercube codes.” This approach, which turns out to have an elegant geometry, could help realize extremely efficient error corrections and contribute to highly parallel methods that will allow fault-tolerant quantum computing, the next stage in the evolution of quantum computers.

This research was propelled by Universal Quantum's vision to leverage the unique properties of trapped-ions, and enable them to be shuttled over long distances for two-qubit operations with minimal fidelity loss – contributing to refined connectivity and therefore facilitating scaling.

Riverlane, the global leader in quantum error correction technology, has released its groundbreaking three-year roadmap for its Quantum Error Correction Stack, Deltaflow, starting in 2024 and culminating in a system where quantum computers can run one million (Mega) error-free Quantum Operations (QuOps) by 2026.

Riverlane, the global leader in quantum error correction technology, is proud to announce the award of a £2.1m European Innovation Council (EIC) Transition grant funded by the Horizon Europe guarantee and backed by the Department for Science, Innovation & Technology (DSIT). Stemming from Riverlane’s foundational research in quantum error correction, this grant will propel the development of a quantum error decoder capable of supporting the real-time decoding of quantum operations – a crucial step to achieving quantum advantage.

A quantum computer will serve as an enhancement to advanced computing centers for dealing with advanced physical simulations and optimization problems, alongside CPUs and GPUs.