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A clear roadmap for engineering combs of light

Optical frequency combs—laser sources that emit evenly spaced colors of light—are foundational, ubiquitous tools for precision measurement, found in optical clocks, gas-sensing spectrometers, and instruments that detect the light signatures of exoplanets. Traditionally, frequency combs are produced by large, fiber-laser systems ranging from the size of a shoebox to a refrigerator.

Engineers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) are at the forefront of shrinking these powerful laser sources onto photonic chips to make “microcombs” at millimeter to micron scales, useful not only for their smaller size, but in next-generation telecommunications applications, such as generating multiple data carriers over a single optical fiber.

New research led by Marko Lončar, the Tiantsai Lin Professor of Electrical Engineering and Applied Physics, describes a new, generalized model for how to design so-called resonant electro-optic microcombs on thin-film lithium niobate, a material featuring a strong electro-optic effect, or the ability to efficiently mix electronic signals with optical ones.

Not just spin—electron orbitals can provide new method for controlling magnetism

Research is actively underway to develop a “dream memory” that can reduce heat generation in smartphones and laptops while delivering faster performance and lower power consumption. Korean researchers propose a new possibility for controlling magnetism using the exchange interaction of electron orbitals—the motion of electrons orbiting around an atomic nucleus—rather than relying on the conventional exchange interaction of electron spin, the rotational property of electrons inside semiconductors.

A joint research team led by Professor Kyung-Jin Lee of the Department of Physics at KAIST and Professor Kyoung-Whan Kim of the Department of Physics at Yonsei University has established, for the first time in the world, a new theoretical framework enabling magnetism to be freely controlled through orbital exchange interaction, surpassing the limitations of conventional technologies that control magnetism using electric currents. The study is published in the journal Nature Communications.

Until now, next-generation memory research has mainly focused on the spin of electrons. Spin refers to the property of electrons that rotate on their own axis like tiny spinning tops, and information can be stored by using the direction of this rotation. However, electrons simultaneously move around the atomic nucleus along paths known as orbitals.

New microscope offers sharper view into momentum space

Electrons are tiny and constantly in motion. How they behave in a crystal lattice determines key material properties: electrical conductivity, magnetism, or novel quantum effects. Anyone aiming to develop the information technologies of tomorrow must understand what electrons do. At Forschungszentrum Jülich, a new tool is now available for this purpose: a momentum microscope that was fully developed and built on site. “Internationally, we are currently seeing rapidly growing interest in this method,” explains Dr. Christian Tusche from Forschungszentrum Jülich.

Dr. Christian Tusche already played a key role in advancing momentum microscopy during his time at the Max Planck Institute of Microstructure Physics in Halle. Since moving to Jülich in 2015, he has continued to drive its development forward. His work has been recognized with several awards, including the Kai Siegbahn Prize in 2018 and the Innovation Award on Synchrotron Radiation in 2016. Most recently, he published a review article on the method in the journal Applied Physics Letters.

In recent years, numerous instruments have been commissioned at synchrotron facilities and X-ray lasers around the world. “The new device we built together with the Mechanical Workshop is a real innovation. There is currently nothing like it available from any specialist company,” says Dr. Tusche.

Key transistor for next-generation 3D stacked semiconductors operates without current leakage

A research team led by Professor Jae Eun Jang and Dr. Goeun Pyo from the Department of Electrical Engineering and Computer Science at DGIST has developed “dual-modulated vertically stacked transistors” that operate stably without current leakage even in two-dimensional nanoscale channel structures. A study on this work is published in the journal Advanced Science.

In recent years, the semiconductor industry has faced physical limitations as the demand to integrate more devices within limited space continues to grow. To overcome these constraints, “vertically stacked transistors,” in which current-carrying channels are vertically layered, have emerged as a promising alternative for next-generation 3D semiconductors. However, conventional vertically stacked transistors suffer from a critical drawback in which gate electric signals are not delivered uniformly into the channel interior due to their electrode structure, consequently leading to current leakage or unstable device operation as the channel length becomes shorter.

To address this issue, the research team proposed a “dual-modulation structure” in which two gates—positioned above and below—control the channel through different mechanisms. This represents an innovative approach in which current flows in a sandwich-like configuration, with the upper and lower electrodes facing each other across the channel.

Asteroid Spaceships: Turning Rocks into Interstellar Vehicles

Asteroids could be the ultimate spacecraft. Explore how space rocks become starships, habitats, and interstellar vessels.

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Credits:
Using Asteroids As Spaceships.
Science & Futurism with Isaac Arthur.
Episode 379, January 26, 2023
Written, Produced & Narrated by Isaac Arthur.

Editors:
Briana Brownell.
David McFarlane.
Donagh B.

Graphics by:
Fishy Tree.
Jeremy Jozwik.
Ken York.
Sergio Botero.
Udo Schroeter.

Music Courtesy of Epidemic Sound http://epidemicsound.com/creator.

Continue reading “Asteroid Spaceships: Turning Rocks into Interstellar Vehicles” | >

Orbital Farms

As humanity expands into space, we’ll need new ways to grow food. Explore how orbital farms could sustain billions—on Earth, Mars, and beyond.

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Watch my exclusive video Autonomous Space Industry: https://nebula.tv/videos/isaacarthur–
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SFIA Discord Server: / discord.
Credits:
Orbital Farms — Extended Edition.
Episode 471a; November 1, 2024
Produced, Narrated & Written: Isaac Arthur.
Graphics:
Jarred Eagley.
Jeremy Jozwik.
Katie Byrne.
Ken York YD Visual.
Udo Schroeter.
Select imagery/video supplied by Getty Images.
Music Courtesy of Epidemic Sound http://epidemicsound.com/creator

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A new class of molten planet stores abundant sulfur in a perpetual magma ocean

A study led by the University of Oxford has identified a new type of planet beyond our solar system—one that stores large amounts of sulfur deep within a permanent ocean of magma. The findings have been published in Nature Astronomy.

The exoplanet (a planet that orbits a star outside the solar system), known as L 98–59 d, orbits a small red star about 35 light-years from Earth. Recent observations from the James Webb Space Telescope (JWST) and ground-based observatories suggest something unusual: the planet has an especially low density, given its size (which is about 1.6 times that of Earth) and contains significant amounts of hydrogen sulfide in its atmosphere.

Until now, astronomers would have placed a planet like this into one of two familiar categories, either a rocky “gas-dwarf” with an atmosphere of hydrogen, or a water-rich world made of deep oceans and ice. But these new findings reveal that L 98–59 d fits neither description—instead, it appears to belong to an entirely different class of planet containing heavy sulfur molecules.

Robot dogs are protecting data centers. Operators are seeing payoffs

As companies pour billions into sprawling industrial campuses for cloud and AI computing, some data center operators are experimenting with four-legged bots — about the size of large dogs — that can patrol fences, inspect equipment, and flag any issues before they turn into costly outages.

“I was literally at a data center this week,” Merry Frayne, senior director of product management at Boston Dynamics, the maker of Spot, told Business Insider. “We’ve seen a huge, huge uptick in interest from data centers in the last year, I’d say, which is probably not surprising given the investment in that space.”

Robot dogs have already been deployed by first responders, the military, and in other industrial sectors such as oil and mining. But the rapid pace of data center buildouts is creating another niche for the mechanical quadrupeds.

Something strange is happening in the Milky Way’s magnetic field

A stunning new map of the Milky Way reveals a dramatic magnetic flip hiding in plain sight. Deep inside the Milky Way, an invisible force is quietly holding everything together — its magnetic field. Now, researchers have created one of the most detailed maps ever of this hidden structure, revealing surprising twists in how it flows through our galaxy.

For generations, scientists have studied the stars and planets to better understand how our galaxy works. Now, Dr. Jo-Anne Brown, PhD, is focused on charting something we cannot see at all: the Milky Way’s magnetic field.

“Without a magnetic field, the galaxy would collapse in on itself due to gravity,” says Brown, a professor in the Department of Physics and Astronomy at the University of Calgary.

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