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Saturn-ring-like laser emission from chiral polymeric microspheres

Controlling light within microscopic spaces is crucial for next-generation optical devices such as photonic integrated circuits and localized sensors. Microspheres formed of luminescent π-conjugated polymers act as optical resonators that confine and amplify light via whispering gallery modes (WGMs), and they are promising candidates for microscale organic lasers and photonic applications. However, conventional microsphere resonators are geometrically isotropic and emit isotropic light, making directional control of emissions challenging.

In a new study published in the Journal of the American Chemical Society, researchers from the University of Tsukuba show that microspheres formed through the self-assembly of chiral π-conjugated polymers possess a characteristic twisted bipolar molecular configuration, enabling angle-selective optical resonance and laser oscillation with distinct azimuthal directionality. Using polarization-dependent photoluminescence imaging, the research team directly visualized a vortex-like (swirling) arrangement formed by the polymer main chains on the spherical surface.

Furthermore, this vortex-like surface molecular orientation induces an azimuth-dependent refractive-index distribution along the light propagation path, resulting in angle-dependent WGM resonance wavelengths and spatially localized emission. Consequently, the microspheres exhibit directional laser oscillation, preferentially emitting amplified light along a specific azimuthal direction. The resulting emission pattern is analogous to Saturn’s rings.

Scientists discover new method of defense against solar storms to help protect Earth

A recent study is shedding light on how we handle geomagnetic storms, offering a way to reduce their severity.

Experts at Advancing Earth and Space Sciences (AGU) have dug into the essentials of solar storms and how they can affect our planet.

Solar storms occur when the sun creates an entangled mess of magnetic fields, similar to a messy head of hair after a long night of sleep.

NASA’s Hubble Reveals a Star-Spangled Stellar Masterpiece of 500,000 Ancient Stars

More than 500,000 stars glow in shades of red, white, and blue in a spectacular new image captured by NASA’s Hubble Space Telescope. Released in celebration of the United States’ 250th anniversary, the image features Messier 3 (M3), one of the Milky Way’s largest globular clusters. Globular clust

NASA’s Hubble Captures a Stunning Red, White, and Blue Stellar Nursery

NASA’s Hubble Space Telescope has captured a breathtaking view of the stellar nursery LH 95, where brilliant blue and white stars sparkle against glowing crimson clouds of gas, creating a scene that resembles fireworks fading into a smoky night sky. Located in the Large Magellanic Cloud, a dwarf

Tell Musk this is true human’s future

How will humanity power its interplanetary future?
In this cinematic documentary, we journey to the year 2,325, where humanity has finally achieved Type I civilization status. We explore the colossal engineering feats required to harvest the Sun’s energy from Mercury and beam it across the entire solar system.

▶A Film by: Scienshell.

In a universe where energy is the currency of survival, the diffused sunlight that has bathed our solar system for 5 billion years is no longer enough. To fuel a true interplanetary empire, humanity must harvest, concentrate, and transmit the immense power of our star. But harnessing such staggering amounts of energy requires pushing the absolute limits of physics and engineering.

As our energy needs grow, the line between theoretical physics and applied engineering begins to blur. For those who build the infrastructure of tomorrow, the solar system itself becomes a machine.

In this video, you’ll discover:
[00:00] Introduction.
[01:29] 2325: The Dawn of a Type I Civilization.
[02:15] Mining Mercury and the Solar Ring Construction.
[06:24] Photons: The Perfect Interplanetary Energy Carriers.
[08:12] The Beating Heart of the Energy Grid.
[11:02] Precursor Beams and Cosmic No-Fly Zones.
[13:01] The Danger of Runaway Gamma Beams.
[15:12] The Gamma Cascade: Converting Destructive Energy.
[17:34] Powering an Interplanetary Civilization.

▶ About This Video.

NASA testing advanced capabilities for moon, Mars rovers

On a bleak stretch of the Colorado Desert in Southern California, a compact four-wheeled rover recently trundled 16 miles (26 kilometers) with minimal intervention from the team of engineers trailing it. Called ERNEST (Exploration Rover for Navigating Extreme Sloped Terrain), this prototype is being used by NASA to advance both robotic autonomy and the ability to traverse challenging landscapes.

Developed at NASA’s Jet Propulsion Laboratory in Southern California, ERNEST is 4 feet (1.2 meters) long. Not only can it lift each of its mesh wheels to get past obstacles that would stymie Curiosity and Perseverance, NASA’s six-wheeled Mars rovers, but the prototype also has enhanced independent decision-making capabilities. These mobility and autonomy advances could be infused into future missions that will venture into previously inaccessible areas of the red planet or the moon.

In the field, ERNEST served as a testbed for a potential future lunar mission requiring higher speeds and much greater mileage than can be accomplished by current rovers. This technology could be used to inform future designs for exploration efforts on the moon and beyond.

New optical centrifuge unlocks the secrets of frictionless superfluids

Physicists have developed a new way to control the rotation of molecules inside tiny droplets of liquid helium, marking an important advance in the study of superfluids. By using a specially designed optical centrifuge, the team was able to precisely spin molecules suspended in liquid helium nano-droplets, giving scientists a powerful new tool for exploring these unusual frictionless materials.

The achievement represents the first successful demonstration of controlled molecular rotation inside a superfluid. Researchers can now directly adjust both the direction and speed of a molecule’s rotation, making it possible to investigate how molecules interact with their quantum surroundings at different rotational frequencies. The work, led by researchers at the University of British Columbia (UBC) in collaboration with the University of Freiburg, was published in Physical Review Letters.

“Controlling the rotation of a molecule dissolved in any fluid is a challenge,” said Dr. Valery Milner, associate professor with UBC Physics and Astronomy and author on the paper.

The Sun may not engulf Earth after all, scientists say

The Earth may not be engulfed by the expanding fireball of the dying sun, which has long been assumed to be our home planet’s ultimate fate, according to scientists.

Don’t worry: This is not expected to happen for another 5 billion years, long after all life on Earth has been wiped out.

When the sun burns through all of the hydrogen in its core, it will go through two immense expansion phases: first becoming a red giant, then, when its helium is spent, an “AGB” star.

Cliff Pickover (@pickover) on X

We aren’t the authors of our thoughts. We’re just the user interface. We look at the universe and see a solid reality. The universe looks at us and sees a line of code. We spend our lives trying to leave a mark on the surface of reality. Oblivious to the fact that our existence is being computed from beneath. We aren’t separate individuals. We’re just the localized tips of a single, massive mathematical architecture.👇

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