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Physicists confirm elusive quantum spin liquid in new study

An international team of scientists led by Rice University’s Pengcheng Dai has confirmed the existence of emergent photons and fractionalized spin excitations in a rare quantum spin liquid. Published in Nature Physics on June 19, their findings identify the crystalline compound cerium zirconium oxide (Ce₂Zr₂O₇) as a clear 3D realization of this exotic state of matter.

Long a subject of theoretical intrigue, quantum spin liquids offer promise for revolutionary technologies, including and dissipationless energy transmission. By refusing to conform to traditional magnetic behavior, these materials realize emergent quantum electrodynamics via highly quantum-entangled motions of magnetic moments at temperatures near absolute zero.

“We’ve answered a major open question by directly detecting these excitations,” said Dai, the Sam and Helen Worden Professor of Physics and Astronomy. “This confirms that Ce₂Zr₂O₇ behaves as a true quantum spin ice, a special class of quantum spin liquids in three dimensions.”

Near-perfect defects in 2D material could serve as quantum bits

Scientists across the world are working to make quantum technologies viable at scale—an achievement that requires a reliable way to generate qubits, or quantum bits, which are the fundamental units of information in quantum computing.

The task has so far remained elusive, but one of the materials that has garnered a lot of attention as a possible qubit platform is (h-BN), a 2D material that can host solid-state single-photon emitters (SPEs). Like the name indicates, SPEs are atomic structures in solid materials that can produce individual photons.

In a new study published in Science Advances, researchers at Rice University and collaborators at Oak Ridge National Laboratory and the University of Technology, Sydney report the first demonstration of low noise, room-temperature quantum emitters in h-BN made through a scalable growth technique.

Topological insulators boost ultra-thin magnet strength by 20% for next-gen electronics

A team of international researchers led by the University of Ottawa has made a breakthrough in the development of ultra-thin magnets—a discovery that could lead to faster, more energy-efficient electronics, quantum computers, and advanced communication systems.

The study, led by Hang Chi, Canada Research Chair in Quantum Electronic Devices and Circuits, & Assistant Professor of Physics at uOttawa’s Faculty of Science, demonstrates a new way to strengthen magnetism in materials just a few atoms thick. This is a critical step toward making these practical for real-world technologies.

The paper is published in the journal Reports on Progress in Physics.

Universal embezzlers naturally emerge in critical fermion systems, study finds

Embezzlement of entanglement is an exotic phenomenon in quantum information science, describing the possibility of extracting entanglement from a resource system without changing its quantum state. In this context, the resource systems play the role of a catalyst, enabling a state transition that would otherwise be impossible, without being consumed in the process. For embezzlement of entanglement to be possible, the resource state needs to be highly entangled.

The term “universal embezzler” refers to the idea of a bipartite quantum system where every state is sufficiently entangled to make possible. So far, it seemed highly questionable that physical systems exhibiting such strong entanglement properties could exist in the first place.

Yet researchers at Leibniz University Hannover have now shown that universal embezzlement emerges in all critical fermion chains, meaning one-dimensional fermion systems at quantum phase transitions. While their paper, published in Nature Physics, is merely theoretical, it could open new possibilities for the study of many-body physics and for the development of quantum technologies.

Vacuum fluctuations in optical cavities reveal hidden properties of embedded materials

Researchers at the Max Planck Institute for the Structure and Dynamics of Matter (MPSD) have theoretically demonstrated that photons trapped inside an optical cavity carry detailed information about a material placed within it. By measuring the properties of the photons leaking out of the cavity, researchers can probe how an optical cavity modifies the properties of the embedded materials.

This insight opens new possibilities for experimental techniques to explore entangled light-matter systems. Their work has been published in Physical Review Letters.

According to basic quantum mechanics, empty space is not truly empty—it’s filled with particles that constantly pop in and out of existence, a phenomenon known as vacuum fluctuations. This process is somewhat analogous to atoms at the surface of boiling water, which continually jump in and out of the liquid.

Scientists create ‘universal translator’ for quantum tech

Scientists at UBC have devised a chip-based device that acts as a “universal translator” for quantum computers, converting delicate microwave signals to optical ones and back with minimal loss and noise. This innovation preserves crucial quantum entanglement and works both ways, making it a potential backbone for a future quantum internet. By exploiting engineered flaws in silicon and using superconducting components, the device achieves near-perfect signal translation with extremely low power use and it all fits on a chip. If realized, this could transform secure communication, navigation, and even drug discovery.

Photons collide in the void: Quantum simulation creates light out of nothing

Using advanced computational modelling, a research team led by the University of Oxford, working in partnership with the Instituto Superior Técnico in the University of Lisbon, has achieved the first-ever real-time, three-dimensional simulations of how intense laser beams alter the ‘quantum vacuum’ — a state once assumed to be empty, but which quantum physics predicts is full of virtual electron-positron pairs.

Teleportation Becomes a Scientific Reality

When we think about the future of our communications, we rarely imagine that it could be hidden in the intricacies of the infinitely small. Yet, it is there, among frisky photons, that the next digital revolution could take shape. A simple photon, teleported from one point to another across the globe via the Internet, opens up dizzying horizons. Who would have thought that the key to our future exchanges would lie in an elementary particle, capable of challenging everything we thought we knew about information transmission?

Researchers at Northwestern University have recently achieved a major milestone in the field of quantum physics. They have succeeded in teleporting a photon over a distance of 30.2 km through an Internet network. This feat, once confined to the realm of science fiction novels, represents a significant advance in exploring the possibilities offered by quantum entanglement. With this accomplishment, the foundations of a future global quantum network seem to be rapidly approaching.