A team of scientists from the University of Chicago, the University of California Berkeley, Argonne National Laboratory, and Lawrence Berkeley National Laboratory has developed molecular qubits that ...

A monolayer of copper-based molecular qubits assembled on graphene maintains strong one-dimensional antiferromagnetic coupling - the graphene itself may help strengthen that magnetic interaction.

Quantum computing, once only a theoretical possibility, promises to deliver faster, more energy-efficient computers—but only ...

Devices taking advantage of the collective quantum behavior of spin excitations in magnetic materials—known as magnons—have the potential to improve quantum computing devices. However, using magnons ...

The Nature Index 2025 Research Leaders — previously known as Annual Tables — reveal the leading institutions and countries/territories in the natural and health sciences, according to their output in ...

Novel Quantum Systems Accelerator (QSA) research shows that molecules could play a role in the future of quantum computing, particularly in specialized applications like quantum simulations and ...

Any project, supported or not by a committee, that is currently being worked on or is considered active, and will have an end date. Progress in the development of QIS platforms has been explosive, in ...

Researchers at Kumamoto University, in collaboration with colleagues in South Korea and Taiwan, have discovered that a unique cobalt-based molecule with metal–metal bonds can function as a spin ...

Biology and quantum physics often seem like they belong to separate worlds. Living cells function in warm, noisy environments, full of constant motion, while quantum technologies usually need ...

Biocompatible molecular spin sensors enable absolute thermometry in the cytoplasm and nucleus of living cancer cells. (Nanowerk News) Researchers at the National Institutes for Quantum Science and ...