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Archive for the ‘particle physics’ category: Page 24

Oct 12, 2024

Unique Particles — With Stickiness of Gecko Feet — Formed by Harnessing Chaos

Posted by in categories: chemistry, engineering, food, nanotechnology, particle physics

New research from North Carolina State University shows that unique materials with distinct properties akin to those of gecko feet – the ability to stick to just about any surface – can be created by harnessing liquid-driven chaos to produce soft polymer microparticles with hierarchical branching on the micro-and nanoscale.

The findings, published today (October 14, 2019) in the journal Nature Materials, hold the potential for advances in gels, pastes, foods, nonwovens, and coatings, among other formulations.

The soft dendritic particle materials with unique adhesive and structure-building properties can be created from a variety of polymers precipitated from solutions under special conditions, says Orlin Velev, S. Frank and Doris Culberson Distinguished Professor of Chemical and Biomolecular Engineering at NC State and corresponding author of the paper.

Oct 12, 2024

Soft dendritic microparticles with unusual adhesion and structuring properties

Posted by in categories: materials, particle physics

Polymer precipitation under turbulent flows generates soft microparticles with branched dendritic coronas and high adhesive properties.

Oct 12, 2024

Twenty years after its discovery, graphene is finally living up to the hype

Posted by in categories: computing, particle physics, space

Manchester, England— On a rare sunny day in northern England, the National Graphene Institute (NGI) here gleams like a five-story block of obsidian. Squeezed into the University of Manchester’s sprawling downtown campus, the research center is clad in almost 2000 lustrous black panels with small hexagonal perforations—an architectural nod to the structure of the atom-thin sheet of carbon that gives the building its name.

NGI exists because graphene was first isolated a short walk away in a University of Manchester lab. Andre Geim and Konstantin Novoselov presented it to the world 20 years ago this month and later won a Nobel Prize for the work. Since its unveiling, billions of dollars of R&D funding have flowed to graphene, in a global race to exploit its peerless properties. It is better at carrying electricity than any metal, a superb heat conductor, and hundreds of times stronger than steel—selling points trumpeted in the marketing materials of universities and companies alike.

Early on, researchers were not shy about promising graphene breakthroughs, with predictions that it would enable superthin rollable TVs and space elevators, and even supplant silicon in computer chips. “Expectations were very, very high,” Geim says. “The companies I was involved in were mostly based on hype.”

Oct 12, 2024

Timekeeping Innovation: Quantum Entanglement Unlocks Unprecedented Precision

Posted by in categories: computing, particle physics, quantum physics

Quantum physicists have developed a new type of optical atomic clock, using quantum entanglement among strontium atoms to achieve unprecedented precision.

This breakthrough could significantly impact quantum computing and precision sensing, although it currently operates effectively for only milliseconds.

Quantum Advances in Timekeeping.

Oct 11, 2024

On-chip zero-index metamaterials

Posted by in categories: computing, particle physics

This chip has speed that defies the light speed barrier while maintaining cool temperatures using a special metamaterial that allows the light particles to go infinitely fast.


Most metamaterial experiments occur in bulk transmission geometries. Here researchers demonstrate integrated in-plane zero-index metamaterials.

Oct 11, 2024

Physicists reveal nonlinear transport induced by quantum geometry in planar altermagnets

Posted by in categories: particle physics, quantum physics

In the quantum world, materials called “altermagnets” behave in unique ways that could pave the way for new technologies.


This unique magnetism makes altermagnets highly promising for the development of new spintronic and . It also opens new possibilities for the study of topological materials (i.e., systems with unique electronic properties originating from their electronic structure’s topology).

Researchers at Stony Brook University carried out a study aimed at better understanding the nonlinear response of planar altermagnets. Their paper, published in Physical Review Letters, reports the observation of a non-linear response in these materials derived from their quantum geometry.

Continue reading “Physicists reveal nonlinear transport induced by quantum geometry in planar altermagnets” »

Oct 11, 2024

Watching electrons in motion at 1 quintillionth of a second

Posted by in categories: materials, particle physics

Imagine being able to see electrons — the tiny particles that buzz around atoms — in action, darting and swirling in their frenetic dance. This isn’t science fiction anymore.

Scientists have recently developed a state-of-the-art microscope that allows us to observe these elusive particles moving at unimaginable speeds, revealing the intricate behaviors and interactions that occur at the atomic level.

This innovative technology opens up new frontiers for research in physics and materials science, providing unprecedented insights into the fundamental building blocks of matter.

Oct 10, 2024

This toothpaste-based transistor could be the future of edible electronics

Posted by in categories: computing, food, particle physics

The edible transistor is based on an existing transistor architecture, utilizing CuPc as the active material. The key component, the electrolyte-gated OFET (EGOFET), operates at low voltages (1 V) and can function stably for more than a year. The transistor showed good reproducibility, with performance characteristics that pave the way for integrating these devices into more complex edible circuits.

The circuits are constructed on a derivative of cellulose with electrical contacts being printed using inkjet technology and a solution of gold particles (which are also commonly used in the food industry for decoration). The transistor “gate” is also food-grade. This component controls the flow of electrical current between the source and drain terminals, effectively acting as a switch or amplifier. This gate is made from a gel based on chitosan another food-grade ingredient used as a gelling agent.

The research team also explored the optical and morphological properties of CuPc thin films. They found that the thickness of the CuPc layer played a crucial role in the transistor’s performance. Thinner films displayed better charge transport properties, which are essential for creating high-performing, low-voltage devices. This detailed understanding of the material’s properties allowed the team to optimize the transistor’s design for use in real-world applications.

Oct 9, 2024

The Sun Unleashed a Huge Solar Flare at Earth, And We’re on Aurora Alert

Posted by in categories: particle physics, space

The Sun has started spooky season with a bang, letting loose on October 1 with a colossal flare and coronal mass ejection headed right for Earth.

The flare clocked in at X7.1 – the second most powerful flare of the current solar cycle, and one of the most powerful solar flares ever measured, sitting within the top 30 flares over the last 30 years.

We’re not in any danger, but the NOAA’s Space Weather Prediction Center has forecast minor to strong geomagnetic storms over the next few days, from 3 to 5 October, as we await the gust of solar particles as the coronal mass ejection blasts through the Solar System.

Oct 9, 2024

Physicists Simulated a Black Hole in The Lab, And Then It Began to Glow

Posted by in categories: cosmology, mathematics, particle physics, quantum physics

A black hole analog could tell us a thing or two about an elusive radiation theoretically emitted by the real thing.

Using a chain of atoms in single-file to simulate the event horizon of a black hole, a team of physicists in 2022 observed the equivalent of what we call Hawking radiation – particles born from disturbances in the quantum fluctuations caused by the black hole’s break in spacetime.

This, they say, could help resolve the tension between two currently irreconcilable frameworks for describing the Universe: the general theory of relativity, which describes the behavior of gravity as a continuous field known as spacetime; and quantum mechanics, which describes the behavior of discrete particles using the mathematics of probability.

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