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Engineers develop a magnetic transistor for more energy-efficient electronics

Transistors, the building blocks of modern electronics, are typically made of silicon. Because it’s a semiconductor, this material can control the flow of electricity in a circuit. But silicon has fundamental physical limits that restrict how compact and energy-efficient a transistor can be.

MIT researchers have now replaced silicon with a magnetic semiconductor, creating a magnetic transistor that could enable smaller, faster, and more energy-efficient circuits. The material’s magnetism strongly influences its electronic behavior, leading to more efficient control of the flow of electricity.

The team used a novel magnetic material and an optimization process that reduces the material’s defects, which boosts the transistor’s performance.

Device-independent method certifies genuinely entangled subspaces in photonic and superconducting systems

In a study published in Reports on Progress in Physics, researchers have achieved device-independent characterization of genuinely entangled subspaces (GESs) in both optical and superconducting quantum systems, completing the self-checking of the five-qubit error correction code space.

In quantum information, genuinely multipartite entangled states require the existence of entanglement correlations between any two subsystems within the system. The GES constituted by the states has application value especially in designing quantum error-correcting codes. By encoding in the subspace, it can prevent error propagation caused by local decoherence.

Scientists have constructed a new Bell inequality based on the stabilizer framework constructed, and the entangled subspace can be universally characterized by using it. Any quantum state (including mixed states) within this subspace could maximally violate this inequality, providing a theoretical basis for the self-testing of genuine entangled subspaces.

Ultrafast magnetization switching: Moving boundary challenges previous all-optical switching models

The field of ultrafast magnetism explores how flashes of light can manipulate a material’s magnetization in trillionths of a second. In the process called all-optical switching (AOS), a single laser pulse of several femtoseconds (≈10-15 seconds) duration flips tiny magnetic regions without the need for an externally applied magnetic field.

Enabling such an ultrafast control over magnetization, orders of magnitude faster than what can be achieved using a conventional magnet-based read/write head as in a magnetic hard drive, AOS is a promising candidate for novel spintronics devices that use magnetic spins with their associated as information carriers. Such devices typically consist of a stack of nanometer-thin materials, with the actual magnetic material being one of them.

Until now, the switching process was thought to happen uniformly in the magnetic material wherever the laser pulse deposits a sufficient amount of energy. In a study recently published in Nature Communications, researchers from the Max Born Institute together with collaborators from Berlin and Nancy revealed that this is not the case. Instead, there is an ultrafast propagation of a magnetization boundary into the depth of the material.

Self-locked microcomb on a chip tames Raman scattering to achieve broad spectrum and stable output

A research team has successfully developed a self-locked Raman-electro-optic (REO) microcomb on a single lithium niobate chip. By synergistically harnessing the electro-optic (EO), Kerr, and Raman effects within one microresonator, the microcomb has a spectral width exceeding 300 nm and a repetition rate of 26.03 GHz, without the need for external electronic feedback.

The research was published in the Nature Communications. The team was led by Prof. Dong Chunhua from the University of Science and Technology of China (USTC), in collaboration with Prof. Bo Fang’s group from Nankai University.

Optical frequency combs, light sources composed of equally spaced frequency lines, are essential tools in modern optical communications, , and fundamental physics research. While traditional are typically based on bulky mode-locked lasers, recent advances in integrated photonics have enabled chip-scale Kerr and EO combs.

Not Spiral. Not Elliptical. So What Exactly Is This Galaxy?

The Hubble Space Telescope has released a new Picture of the Week, and this time the spotlight is on a galaxy that refuses to fit neatly into any category. The subject, known as NGC 2,775, is located about 67 million light-years away in the constellation Cancer (The Crab). At its center lies a smooth, gas-free core that looks strikingly similar to an elliptical galaxy. Surrounding it, however, is a dusty ring sprinkled with uneven clusters of young stars, giving it the appearance of a spiral galaxy. So what is it exactly: spiral, elliptical — or something in between?

Because astronomers can only observe NGC 2,775 from a single perspective, its true nature remains uncertain. Some scientists argue that it should be considered a spiral galaxy due to its delicate ring of dust and stars. Others, however, classify it as a lenticular galaxy, a transitional type that shares characteristics of both spirals and ellipticals.

Astronomers Capture First-Ever Photo of a Baby Planet Being Born in Darkness

Astronomers have captured something extraordinary: the first-ever direct photo of a baby planet growing inside a dusty ring around a young star.

Using cutting-edge adaptive optics, the team detected the glowing hydrogen gas streaming onto the infant world, essentially catching it mid-birth.

First detection of a growing exoplanet.

A Simple Test Strip That Reveals the Invisible Nanoplastic Threat

Researchers at the University of Stuttgart have created an “optical sieve” capable of detecting minute nanoplastic particles. Functioning much like a test strip, this innovation is designed to provide a new analytical tool for environmental and health research. Researchers from the University of

Hidden Plant Stem Cells Could Hold the Key to Feeding the Future

Plant scientists discovered hidden stem cell regulators tied to growth and crop size. Their breakthrough could transform how we grow food, fuel, and resilient harvests.

Plant stem cells play a vital role in producing the world’s food, livestock feed, and renewable fuels. They are the foundation of plant growth, yet many aspects of how they work remain a mystery. Past studies have struggled to identify several of the key genes that govern stem cell activity.

Mapping the genetic regulators of growth.

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