Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog

Category: energy

Megawatt structured light arrives with 3,070 optical vortices in one array

Optical vortices—light beams carrying orbital angular momentum (OAM)—are characterized by helical wavefronts and phase singularities. While they have been widely studied in recent decades, two fundamental limitations have restricted their broader impact: generating large numbers of vortices simultaneously and achieving high peak power in such configurations. Until now, large vortex arrays have been limited to low-power systems, whereas high-power demonstrations have typically involved only single vortices.

In a new paper published in Light: Science & Applications, a research team led by Professor Yoshiki Nakata at The University of Osaka reports the world’s first experimental realization of a megawatt-class large-scale optical vortex array comprising 3,070 phase-coherent vortices at a peak power of 58 megawatts. The result represents more than three orders of magnitude improvement in both vortex number and peak power compared with previous approaches.

Conventionally, Laguerre–Gaussian (LG) modes are expressed as the superposition of two Hermite–Gaussian (HG) modes with a π/2 phase shift. This constitutes the first revision of the HG–LG mode-conversion framework in three decades. The team reformulated this description into a three-mode representation that naturally integrates with multibeam interference geometry.

Leather gets a power upgrade with laser-written microsupercapacitors

Researchers have developed a simple and eco-friendly way to use a laser to turn natural leather into flexible and wearable energy devices. The new approach could lay the groundwork for more sustainable wearable electronics. In a paper in Optics Letters, the researchers demonstrate the new technique by creating microsupercapacitors on leather in various patterns, including a tiger, dragon and rabbit.

“Using a laser, we directly write conductive patterns onto vegetable-tanned leather to create microsupercapacitors that can store energy and help smooth electrical signals so that wearable electronics run more reliably,” said the research team leader Dong-Dong Han from Jilin University in China.

Unlike conventional devices that rely on synthetic materials and complex, chemical-heavy processes, our approach uses a natural, skin-friendly material and a one-step fabrication method. The microsupercapacitors are well-suited for flexible and comfortable wearable electronics because they are built on soft materials and can be shaped freely and integrated directly into products.

New hydrogen fuel cell design could unlock key clean energy technology

UNSW researchers have redesigned hydrogen fuel cells to solve a critical flaw, bringing clean energy for aviation, heavy transport and beyond closer to reality. Hydrogen fuel cells, using locally produced green hydrogen as the only fuel, have long been viewed as the ultimate clean energy source, but their commercialization has been difficult.

A multidisciplinary team from UNSW, led by Dr. Quentin Meyer and Professor Chuan Zhao from the School of Chemistry, has managed to make hydrogen fuel cells much more efficient, paving the way for their commercialization.

“Hydrogen fuel cells generate clean electricity with water as the only byproduct,” says Dr. Quentin Meyer, a Senior Research Fellow in Prof. Zhao’s team, and first author of the research published in the journal Applied Catalysis B: Environment and Energy.

Light-driven method enables sustainable production of porous semiconducting polymers

Researchers at Koç University have developed a light-driven method to produce porous semiconducting polymers under ambient conditions without the need for metal catalysts. The study, led by Prof. Dr. Önder Metin from the Department of Chemistry, in collaboration with Dr. Melek Sermin Özer, Dr. Zafer Eroğlu, and Prof. Dr. Sermet Koyuncu, was published in Nature Communications.

Porous semiconducting organic polymers have attracted growing attention due to their high thermal and chemical stability, as well as their tunable structures. With a high density of molecular-scale pores, these materials exhibit strong charge transport and light-harvesting capabilities, making them promising for applications ranging from gas storage and energy technologies to photocatalysis and optoelectronics.

However, conventional synthesis methods are often complex, costly, and difficult to scale. They typically require high temperatures, expensive metal catalysts, and multi-step reaction processes, limiting their broader applicability.

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.

/* */