Base Molecular Resonance Technologies (BMRT), the leading pioneer in quantum physics-driven security/medical/military solutions, today announced a $15 million investment initiative to accelerate the launch and deployment of BMRT Security, Inc. This follows BMRT Security, Inc.'s independently validated $1.8 billion U.S. IP licensing valuation, affirming the company's leadership in next-generation security technology.

A low-energy challenger to the quantum computer that also works at room temperature may be the result of research at the University of Gothenburg. The researchers have shown that information can be transmitted using magnetic wave motion in complex networks.

A collaborative research team led by Prof. HUANG Xingjiu from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences (CAS) and Prof. LI Lina from the Shanghai Institute of Applied Physics of CAS, has developed a method to detect harmful heavy metals through a selective catalytic double metal single atom in redox reactions.

Electrons oscillate around the nucleus of an atom on extremely short timescales, typically completing a cycle in just a few hundred attoseconds (one attosecond is a quintillionth of a second). Because of their ultrafast motions, directly observing electron behavior in molecules has been challenging. Now researchers from UC San Diego’s Department of Chemistry and Biochemistry have suggested a new method to make visualizing electron motion a reality.

Long at the vanguard of international efforts to answer questions like these, ORNL’s contributions remain strong today. David Radford, head of the lab’s Fundamental Nuclear and Particle Physics section, is an internationally renowned expert in the field who has had an indelible impact on the development of germanium detectors. Vital experimentation tools at the forefront of fundamental physics research, germanium detectors are large, single crystals of germanium — a metallic element — used to detect radiation and enable incredibly precise energy measurements.

The measurement breaks the “nanometer barrier,” allowing researchers to observe ultrafast collective electronic motion on a new class of ultra-small particles, valued for their ability to trap and manipulate light.

Superconducting circuits are being used at TU Wien and ISTA to create new types of quantum systems that are much easier to control and much more tunable than natural quantum systems like atoms.

In a new study published in Physical Review Letters, JILA Fellow and University of Colorado Boulder physics professor Cindy Regal, along with former JILA Associate Fellow Jose D’Incao (currently an assistant professor of physics at the University of Massachusetts, Boston) and their teams developed new experimental and theoretical techniques for studying the rates at which light-assisted collisions occur in the presence of small atomic energy splittings. Their results rely upon optical tweezers—focused lasers capable of trapping individual atoms—that the team used to isolate and study the products of individual pairs of atoms.

Researchers from CQT and University of New South Wales (UNSW) Sydney have proven fundamentally that a spinning atomic nucleus really is a quantum resource. The teams were led respectively by CQT Deputy Director and Principal Investigator Valerio Scarani and Scientia Professor Andrea Morello from UNSW Engineering. The paper was published in Newton on 14 February 2025.

The Quantum Economic Development Consortium (QED-C) today announced the results of a research and development (R&D) program that focused on using cryogenic technologies to advance innovation in quantum technology.