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Category: energy

New detector triples the speed of electron camera, enabling higher sensitivity

An instrument that uses high-energy electrons to take “snapshots” of ultrafast chemical processes at the atomic and molecular level just got a major upgrade. Researchers have conducted the first experiment using a new detector, installed in the megaelectronvolt ultrafast electron diffraction (MeV-UED) instrument, at the Linac Coherent Light Source (LCLS) at the Department of Energy’s SLAC National Accelerator Laboratory.

This detector is the first to keep pace with the MeV-UED’s maximum electron production rate of 1,080 electron pulses per second. Compared to the previous detector’s maximum rate, the new detector collects three times more data over the same time span, drastically improving the instrument’s efficiency and sensitivity.

“With this new detector, we’re able to read out each individual pulse of electrons from the instrument,” said Alexander Reid, MeV-UED facility director. “That gives us a much more powerful way of examining the experimental data to answer our science questions.”

Physicists Found Something That Can Move Faster Than Light: The Darkness Inside It

For the first time, physicists have observed that ‘holes’ in light can move faster than the light itself.

They’re known as phase singularities or optical vortices, and since the 1970s, scientists have predicted that, just as eddies in a river can move faster than the flowing water around them, so too can whirlpools in a wave of light outrun the light they’re embedded within.

This does not break relativity, which states that nothing can travel faster than the speed of light. That’s because the vortices carry no mass, energy, or information, and their motion is based on the evolving geometry of the wave pattern rather than any physical motion through space.

We Are As Gods: Steven Kotler on Our Godlike Power, Stone Age Minds

Do we have godlike responsibility to match?

In this third conversation with Steven Kotler — our first in 14 years — we dig into his latest book, We Are As Gods: A Survival Guide for the Age of Abundance, co-written with Peter Diamandis. And while the book makes a powerful case for abundance, I came prepared to challenge it.

Because abundance without purpose, as Kotler himself argues, is not salvation. It is a different kind of crisis.

Two’s company: Scientists identify new class of star remnants

In about 5 to 8 billion years, our sun is expected to evolve into a white dwarf—an extremely dense, Earth-sized stellar remnant that has exhausted its fuel and shed its outer layer. But while our sun is a solitary star, research over the past 15 years has demonstrated that binary or multi-star systems are far more common than astronomers once thought. When a dense and compact remnant like a white dwarf is involved in a binary system, it often “snatches away” material from its companion star. This process, called accretion, usually emits X-rays in what is considered a “signature” signal.

Now, scientists from the group of Ilaria Caiazzo, assistant professor at the Institute of Science and Technology Austria (ISTA), confirm the detection of an X-ray signal in not just one, but two isolated objects called Gandalf and Moon-Sized. Highly magnetic and rapidly rotating, these two objects are called “merger remnants” as they each formed as a result of a violent cosmic collision. By emitting X-rays in the absence of a companion, they now form a new class of their own.

Breaking fuel cell barriers: New platinum catalyst brings high-efficiency hydrogen vehicles closer to commercialization

A research team has developed a next-generation platinum-based catalyst that improves both activity and durability in hydrogen fuel cells. The study is published in Advanced Materials. The team was led by Professor Sang Uck Lee of the School of Chemical Engineering at Sungkyunkwan University, with Ph.D. candidate Jun Ho Seok as a co-first author and Dr. Sung Chan Cho, in collaboration with Professor Kwangyeol Lee’s team at Korea University and Dr. Sung Jong Yoo’s team at the Korea Institute of Science and Technology (KIST).

Hydrogen fuel cells generate electricity through the electrochemical reaction of hydrogen and oxygen and are considered a promising clean energy technology. However, their broader commercialization has been hindered by the sluggish oxygen reduction reaction (ORR) at the cathode and by catalyst degradation during long-term operation.

Conventional platinum-based intermetallic catalysts are known for their structural stability, but their atomic composition and arrangement are difficult to tune precisely. This has limited efforts to optimize their electronic structure and has made it challenging to achieve both high catalytic activity and long-term durability under demanding operating conditions, such as those required for hydrogen-powered vehicles.

Stretching metals can tune catalysis: A new method predicts energy shifts

Heterogeneous catalysis—in which catalysts and reactants are of different phases, e.g., solid and gas—is important to many industrial processes and often involves solid metal as the catalyst. Ammonia synthesis, catalytic converters for automobile exhaust, methanol synthesis, carbon dioxide reduction, and hydrogen production are examples of such metal-catalyzed heterogeneous catalysis.

The electronic structure of metal surfaces governs the adsorption of reactants and intermediates, and thus the catalytic activity. For this reason, strain engineering —which tunes the electronic structure of a metal catalyst by stretching or compressing its crystal lattice—has emerged as an important strategy for enhancing catalytic performance. Unfortunately, scientists have not been able to quantify how metal strain influences adsorption energies and reaction barriers across different metal catalysts, thereby limiting the rational design of catalysts with desired properties.

To address this challenge, a research team from the Lanzhou Institute of Chemical Physics (LICP) of the Chinese Academy of Sciences has developed a method to predict how strain modifies adsorption energies and reaction barriers across diverse metal systems. The study is published in the journal Cell Reports Physical Science.

Helical liquid crystals can flip light’s chirality under ultralow electric fields

The direction in which the electromagnetic field of circularly polarized light rotates can be easily reversed by applying a voltage, RIKEN researchers have demonstrated. This could enable a new generation of optical devices based on circularly polarized light. The work is published in two papers in the journal Advanced Materials.

Polarized sunglasses produce light that is polarized along a single direction. But some special devices can generate light with a polarization that rotates as the light propagates. Such circularly polarized light is useful for many applications, including spectroscopy, satellite communications, stereoscopy and microscopy.

For some applications, it would be useful to switch between clockwise and anticlockwise circularly polarized light. However, this handedness is locked into the molecular structure. Known as the material’s chirality, it is used to produce the circularly polarized light. And reversing that requires a lot of energy.

New EvilTokens service fuels Microsoft device code phishing attacks

A new malicious kit called EvilTokens integrates device code phishing capabilities, allowing attackers to hijack Microsoft accounts and provide advanced features for business email compromise attacks.

The kit is sold to cybercriminals over Telegram and is under continuous development, its author stating that they plan to extend support for Gmail and Okta phishing pages.

Device code phishing attacks abuse the OAuth 2.0 device authorization flow, in which attackers gain access to a victim account by tricking the owner into authorizing a malicious device.

Shaping Dance with Physics

A physics grad student waltzed away with the top prize in the 2026 Dance Your PhD contest.

Dance is the art of human movement. It combines motion and spin, energy and balance, synchronization and cadence. Many of these concepts are familiar to physicists—even those who might panic at the mere thought of being on a dance floor. Sofia Papa can give a lesson or two on the connections between physics and dance. A physics graduate student and professional dancer, Papa won the top prize this month in the annual Dance Your PhD contest, run by the journal Science. In the winning video, she and six other dancers mimic the internal workings of a piezoelectric, a type of material that turns atomic movement into electricity.

Papa has always loved dancing. “It was my first way to express myself,” she says. For several years now, she has complemented her physics education with dance training. While the dancing has served as a break from the rigors of studying, she has also used it as a way to work through difficult physical concepts. “I’ve always needed something creative to help understand complex ideas,” she says.

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