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Mathematical ‘sum of zeros’ trick exposes topological magnetization in quantum materials

A new study addresses a foundational problem in the theory of driven quantum matter by extending the Středa formula to non-equilibrium regimes. It demonstrates that a superficially trivial “sum of zeros” encodes a universal, quantized magnetic response—one that is intrinsically topological and uniquely emergent under non-equilibrium driving conditions.

Imagine a strange material being rhythmically pushed—tapped again and again by invisible hands. These are periodically driven , or Floquet systems, where energy is no longer conserved in the usual sense. Instead, physicists speak of quasienergy—a looping spectrum with no clear start or end.

When scientists measure how such a system responds to a magnetic field, every single contribution seems to vanish—like adding an infinite list of zeros. And yet, the total stubbornly comes out finite, quantized, and very real.

Measuring the Unruh effect: Proposed approach could bridge gap between general relativity and quantum mechanics

Researchers at Hiroshima University have developed a realistic, highly sensitive method to detect the Unruh effect—a long-predicted phenomenon at the crossroads of relativity and quantum theory. Their novel approach opens new possibilities for exploring fundamental physics and for developing advanced technologies.

The work is published in Physical Review Letters on July 23, 2025.

The Fulling-Davies-Unruh effect, or simply the Unruh effect, is a striking theoretical prediction at the profound intersection of Albert Einstein’s Theory of Relativity and Quantum Theory.

Turbulence with a twist: New work shows fluid in a curved pipe can undergo discontinuous transition

Turbulence is everywhere, yet much about the nature of turbulence remains unknown. During the last decade, physicists have discovered how fluids in a pipe or similar geometry transition from a smooth, laminar state to a turbulent state as their speed increases.

Surprisingly, in the newly emerging consensus, the process could be understood using , not fluid mechanics, and was mathematically equivalent to the way in which water percolates down through a coffee filter.

In a new twist, UC San Diego researchers Guru K. Jayasingh and Nigel Goldenfeld have now predicted that if the pipe is sufficiently curved, the transition can become discontinuous, with the turbulent fraction undergoing a jump beyond a critical flow velocity. This jump is mathematically similar to the way in which water can suddenly and discontinuously turn into ice if cooled below the freezing temperature.

DNA cassette tapes could solve global data storage problems

Our increasingly digitized world has a data storage problem. Hard drives and other storage media are reaching their limits, and we are creating data faster than we can store it. Fortunately, we don’t have to look too far for a solution, because nature already has a powerful storage medium with DNA (deoxyribonucleic acid). It is this genetic material that Xingyu Jiang at the Southern University of Science and Technology in China and colleagues are using to create DNA storage cassettes.

Personalized brain stimulation shows benefit for depression

A more precise and personalized form of electric brain stimulation may be a more effective and faster treatment for people with moderate to major depression compared to other similar treatments, according to a UCLA Health study.

The study, published in JAMA Network Open, examined the effectiveness of a noninvasive brain stimulation treatment known as (HD-tDCS) in treating depression. Transcranial direct current stimulation uses electrodes placed on a patient’s scalp to deliver noninvasive, safe levels of electrical currents to targeted areas of the brain.

For depression, the treatment is used to target brain networks that regulate emotional processing and self-referential thoughts. TDCS has not been approved by the U.S. Food and Drug Administration as a treatment for depression, and into various forms of tDCS is ongoing.

Distinct psilocybin-induced oscillations observed in rat medial prefrontal cortex, with effects lasting days

Psychedelics, a class of psychoactive drugs that typically induce peculiar mental states and hallucinations, are still prohibited for recreational use in most countries worldwide. In recent years, some neuroscientists and medical researchers have been exploring the potential therapeutic effects of these drugs, focusing on the treatment of depression, anxiety and various substance use disorders.

Researchers at the University of Bristol, Compass Pathways plc and other institutes recently carried out a new study involving rats, exploring the effects of the psychedelic compound on the activity of neurons in the medial prefrontal cortex, a brain region that supports decision-making, attention and the regulation of emotions. Their paper, published in Molecular Psychiatry, outlines some of the associated with the intake of this compound, which had not yet been observed in human experiments.

“Psychedelic drugs like have profound effects on our brains and minds,” Matt Jones, Professor of Neuroscience at the University of Bristol and senior author of the paper, told Medical Xpress. “These effects are fascinating and—as a long history of psychedelic use and recent clinical trials attest—potentially beneficial. This study was driven by two interrelated questions. Firstly, how does a relatively simple, small molecule alter brain activity to completely change our mental model of the world? Secondly, can those effects be harnessed to help treat mental illness?”

Scientists reveal how the brain uses objects to find direction

We take our understanding of where we are for granted, until we lose it. When we get lost in nature or a new city, our eyes and brains kick into gear, seeking familiar objects that tell us where we are.

How our brains distinguish objects from background when finding direction, however, was largely a mystery. A new study provides valuable insight into this process, with possible implications for disorientation-causing conditions such as Alzheimer’s. The work is published in the journal Science.

The scientists, based at The Neuro (Montreal Neurological Institute-Hospital) of McGill University and the University Medical Center Göttingen, ran an experiment with mice using ultrasound imaging to measure and record brain activity. The mice were shown , either an object or a scrambled image showing no distinct object.

QROCODILE experiment advances search for dark matter using superconducting nanowire single-photon detectors

Over the past decades, many research teams worldwide have been trying to detect dark matter, an elusive type of matter that does not emit, reflect or absorb light, using a variety of highly sensitive detectors. Ultimately, these detectors should be able to pick up the very small signals that would indicate the presence of dark matter or its weak interactions with regular matter.

A new view of the proton and its excited states

The small but ubiquitous proton serves as a foundation for the bulk of the visible matter in the universe. It abides at the very heart of matter, giving rise to everything we see around us as it anchors the nuclei of atoms. Yet, its structure is amazingly complex, and the quest to understand these details has occupied theorists and experimenters alike since its discovery over a century ago.

“A large part of the visible matter in the universe is made of protons,” said Kyungseon Joo, a physics professor at the University of Connecticut. “And so, if you want to understand the universe, it is important to understand the .”

Currently, proton structure is only well understood in processes where they are probed at high energy and where a lot of momentum is transferred to the proton. In such cases, the probes interact with the quarks and gluons (together called “partons”) that form the proton so quickly that they react like a tightly set rack of billiard balls hit by a well-struck cue ball.

Nano-switch achieves first directed, gated flow of excitons

A new nanostructure acts like a wire and switch that can, for the first time, control and direct the flow of quantum quasiparticles called excitons at room temperature.

The transistor-like switch developed by University of Michigan engineers could speed up or even enable circuits that run on excitons instead of electricity—paving the way for a new class of devices.

Because they have no , excitons have the potential to move without the losses that come with moving electrically charged particles like electrons. These losses drive cell phones and computers to generate heat during use.

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