A USC computer scientist wants to produce quantum materials at scale, with help from Argonne supercomputers.

QunaSys Inc., a leading innovator in quantum computing technology, is appointing Erik H. Stangerup as the new Head of European Business and CEO of QunaSys Denmark ApS. Elena Yndurain, who led the launch of the European business, will remain as the company’s Executive Advisor.

The University of Texas at Austin is boosting its commitment to research and education in quantum science and engineering by establishing the Texas Quantum Institute.

A research team led by Chinese scientists has provided the first experimental evidence hinting at the existence of gravitons, theoretical particles believed to mediate the force of gravity, according to the South China Morning Post (SCMP).

Traceable microscopy could improve the reliability of quantum information technologies, biological imaging, and more.

Winbond Electronics Corporation, a leading global supplier of semiconductor memory solutions, today unveils the latest extension of TrustME® Secure Flash W77Q family with 256Mb, 512Mb and 1Gb devices. These ground-breaking secure flash devices are the first in the market implementing Leighton–Micali Signature (LMS) algorithm for PQC (Post Quantum Cryptography), a critical enhancement for securing connected IoT edge devices used in commercial, industrial and server segments.

NTT Research, Inc., a division of NTT (TYO:9432), today announced that scientists from its Physics & Informatics (PHI) Lab have achieved quantum control of exciton wavefunctions in two-dimensional (2D) semiconductors. In an article published in Science Advances, a team lead by PHI Lab Research Scientist Thibault Chervy and ETH Zurich Professor Puneet Murthy documented their success in trapping excitons in various geometries, including quantum dots, and controlling them to achieve independent energy tunability over scalable arrays.

Quobly, a leader in silicon spin qubit-based quantum computing, is proud to announce its partnership with Nanoacademic Technologies, a renowned provider of digital simulation & modeling tools for quantum technologies. This announcement marks a major milestone in the development of silicon spin qubit technologies for quantum computing.

Researchers at the University of Waterloo’s Institute for Quantum Computing (IQC) have brought together two Nobel prize winning research concepts to advance the field of quantum communication.

A group of physicists from ARQUE Systems and ParityQC present a version of the ParityQC Architecture specifically for quantum computers based on sparse grids of spin qubits. This quantum computing architecture represents an important step forward for the advancement of spin qubits as a quantum computing platform, efficiently harnessing their advantages such as fast timescales and small size.