A new study has uncovered the universal dynamics far from equilibrium in randomly interacting spin models, thereby complementing the well-established universality in low-energy equilibrium physics. The study, recently published in Nature Physics, was the result of a collaborative effort involving the research group led by Prof. Du Jiangfeng and Prof. Peng Xinhua at the University of Science and Technology of China (USTC), along with the theoretical groups of Prof. Zhai Hui from Tsinghua University and Dr. Zhang Pengfei from Fudan University.

Researchers in the lab of UChicago Pritzker School of Molecular Engineering Prof. David Awschalom, including postdoctoral scholar Jonathan Marcks and graduate student Benjamin S. Soloway, have devised a new way to harness the defect spin to measure the behavior of other single electron defects in diamonds.

Q.ANT, the leading German startup for light-based data processing and quantum sensing, is unveiling the first prototypes of the Q.M 10, the next generation of its photonic quantum magnetic field sensor. This groundbreaking sensor redefines the way biosignals are captured and processed in medical technology by measuring the tiniest electric currents and magnetic fields in the human body with even greater precision than its predecessor, and without direct contact. By leveraging light as a natural carrier of information, the Q.M 10 gives researchers deeper insights into the body’s biosignals and promises to push the boundaries of medical technology. One example is mind-controlled prosthetics that function almost like natural limbs. In collaboration with the Fraunhofer Institute for Manufacturing Engineering and Automation (IPA), Q.ANT is developing an innovative prosthetic sensor module, showcasing it at this year’s COMPAMED international trade fair in Düsseldorf, taking place from November 11-14. Visitors can experience a live demonstration at Hall 8a, Booth G10, demonstrating how the Q.M 10 converts emulated muscle signals into precise commands for a hand prosthesis in milliseconds.

Researchers from IBEC and ICFO demonstrate the ability of atomic sensors to non-destructively monitor, measure and optimize nuclear spin hyperpolarization of some clinically relevant molecules in real-time. These features, reported in PNAS, could enhance and reduce costs of quality controls used in clinical magnetic resonance imaging.

The University of Sheffield has opened a new ultra-low temperature facility for dark matter and qubit research, providing a hub for students in the UK and expanding the scope of quantum technology research at the university. The University selected the ProteoxMX, a state-of-the-art dilution refrigerator and superconducting magnet manufactured by Oxford Instruments NanoScience for its facility.

The National Institute of Information and Communications Technology (NICT, President: TOKUDA Hideyuki, Ph.D.), NTT Corporation (NTT, President: Mr. SHIMADA Akira), Tohoku University (President: Dr. TOMINAGA Teiji) and the Tokai National Higher Education and Research System Nagoya University (President: Dr. SUGIYAMA Naoshi) succeeded in developing a new type of superconducting flux qubit that operates in zero magnetic field.

In a recent breakthrough, researchers at the U.S. Department of Energy’s (DOE) Argonne National Laboratory and Northern Illinois University discovered that they could use light to detect the spin state in a class of materials called perovskites (specifically in this research methylammonium lead iodide, or MAPbI3). Perovskites have many potential uses, from solar panels to quantum technology.

Scientists from Osaka Metropolitan University and the University of Tokyo have successfully used light to visualize tiny magnetic regions, known as magnetic domains, in a specialized quantum material. Moreover, they successfully manipulated these regions by the application of an electric field. Their findings offer new insights into the complex behavior of magnetic materials at the quantum level, paving the way for future technological advances.

erra Quantum, a global leader in quantum technology, today announced the successful demonstration of a new type of superconductivity – a significant breakthrough in physics and superconducting technology. “Type III” superconductors feature superconducting islands separated by non-superconducting regions, resulting in unique magnetic and electrical properties.

The strength of a coupling between nuclear spins depends on chirality, or handedness, of the molecule, according to a new study by researchers at UCLA, Arizona State University, Penn State, MIT and Technische Universität Dresden. The study also revealed that in chiral molecules of a given handedness – whether it is a left- or right-handed molecule – the nuclear spin tends to align in one specific direction. In molecules with the opposite chirality, such as right-handedness, the spin aligns in the opposite direction.