China aims to achieve breakthroughs in key brain-computer interface technologies and accelerate their application in industrial manufacturing, healthcare and consumer spending by 2027, according to a guideline released this week.
Category: computing
New physical model aims to boost energy storage research
Engineers rely on computational tools to develop new energy storage technologies, which are critical for capitalizing on sustainable energy sources and powering electric vehicles and other devices. Researchers have now developed a new classical physics model that captures one of the most complex aspects of energy storage research—the dynamic nonequilibrium processes that throw chemical, mechanical and physical aspects of energy storage materials out of balance when they are charging or discharging energy.
The new Chen-Huang Nonequilibrium Phasex Transformation (NExT) Model was developed by Hongjiang Chen, a former Ph.D. student at NC State, in conjunction with his advisor, Hsiao-Ying Shadow Huang, who is an associate professor of mechanical and aerospace engineering at the university. A paper on the work, “Energy Change Pathways in Electrodes during Nonequilibrium Processes,” is published in The Journal of Physical Chemistry C.
But what are “nonequilibrium processes”? Why are they important? And why would you want to translate those processes into mathematical formulae? We talked with Huang to learn more.
The Quantum Frontier with Brian Greene and John Preskill
Renowned Caltech physicist John Preskill joins Brian Greene for an in-depth discussion of quantum mechanics, focusing on where we are and where we’re headed with quantum computing.
This program is part of the Big Ideas series, supported by the John Templeton Foundation.
Participant: John Preskill.
Moderator: Brian Greene.
0:00:00 — Introduction.
0:01:33 — Are There Still Quantum Mysteries?
0:03:32 — Three Pillars of Quantum Mechanics.
0:05:25 — Einstein and Quantum Entanglement.
0:14:51 — Quantum Weirdness and Relativity.
0:17:46 — The Measurement Problem.
0:28:29 — Intro to Quantum Computing.
0:40:28 — Why Preskill Switched Fields.
1:00:51 — What is Quantum Error Correction?
1:15:30 — Quantum Supremacy.
1:23:07 — Can Quantum Systems Impact Society?
1:27:19 — The Black Hole Diary Thought Experiment.
1:31:14 — The Black Hole Bet with Stephen Hawking.
1:38:44 — What We Still Don’t Understand About Black Holes.
1:41:03 — From Baseball Cards to Quantum Physics.
1:45:12 — Credits.
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Organic molecule achieves both strong light emission and absorption for displays and imaging
Researchers at Kyushu University have developed a novel organic molecule that simultaneously exhibits two highly sought-after properties: efficient light emission suitable for advanced displays and strong light absorption for deep-tissue bioimaging. This breakthrough addresses a long-standing challenge in molecular design, paving the way for next-generation multifunctional materials.
Their study, published online in the journal Advanced Materials on July 29, 2025, was conducted in collaboration with the National Taipei University of Technology and the National Central University.
Organic light-emitting diodes (OLEDs) are at the forefront of modern display and lighting technologies, powering nearly everything from smartphone screens to large televisions and monitors. A key phenomenon that is actively being researched to enhance OLED efficiency is thermally activated delayed fluorescence (TADF).
Could Metasurfaces Be The Next Quantum Information Processors?
In the race toward practical quantum computers and networks, photons — fundamental particles of light — hold intriguing possibilities as fast carriers of information at room temperature. Photons are typically controlled and coaxed into quantum states via waveguides on extended microchips, or through bulky devices built from lenses, mirrors, and beam splitters. The photons become entangled – enabling them to encode and process quantum information in parallel – through complex networks of these optical components. But such systems are notoriously difficult to scale up due to the large numbers and imperfections of parts required to do any meaningful computation or networking.
Could all those optical components could be collapsed into a single, flat, ultra-thin array of subwavelength elements that control light in the exact same way, but with far fewer fabricated parts?
Optics researchers in the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) did just that. The research team led by Federico Capasso, the Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering, created specially designed metasurfaces — flat devices etched with nanoscale light-manipulating patterns — to act as ultra-thin upgrades for quantum-optical chips and setups.
Researchers blend theoretical insight and precision experiments to entangle photons on an ultra-thin chip.
Scientists map the genes behind diet and dementia risk
Concordance was high between imputed and sequenced APOE genotypes. Moreover, the researchers replicated known GWAS associations with diet-related biomarkers.
The authors also noted several limitations to provide context for future research. These include that the study population was predominantly of European ancestry, which may limit the generalizability of findings, and that the specific participant criteria (e.g., overweight, family history of dementia) mean the resource is not representative of the general population. They also advise that potential batch effects from specimen type and study site should be accounted for in future analyses.
This genetic resource enables analyses of genetic contributions to variability in cognitive responses to the MIND diet, supporting integrative analysis with other data types to delineate underlying biological mechanisms. The data will be made available to other researchers via The National Institute on Aging Genetics of Alzheimer’s Disease Data Storage Site (NIAGADS).
New work achieves a pure quantum state without the need for cooling
Three nano-glass spheres cling to one another. They form a tower-like cluster, similar to when you pile three scoops of ice cream on top of one another—only much smaller. The diameter of the nano cluster is ten times smaller than that of a human hair.
With the help of an optical device and laser beams, researchers at ETH Zurich have succeeded in keeping such objects almost completely motionless in levitation. This is significant when it comes to the future development of quantum sensors, which, together with quantum computers, constitute the most promising applications of quantum research.
The team’s work appears in Nature Physics.