Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog

Category: materials

A solution to injuries from slips and falls may be found underfoot — literally. The footpads of geckos have hydrophilic (water-loving) mechanisms that allow the little animals to easily move over moist, slick surfaces. Researchers in ACS Applied Materials & Interfaces report using silicone rubber enhanced with zirconia nanoparticles to create a gecko-inspired slip-resistant polymer. They say the material, which sticks to ice, could be incorporated into shoe soles to reduce injuries in humans.

Slips and falls account for more than 38 million injuries and 684,000 deaths every year, according to the World Health Organization. And nearly half of these incidents happen on ice. Current anti-slip shoe soles rely on materials such as natural rubber that repel the layer of liquid water that sits atop pavement on a rainy day. On frozen walkways, however, shoe soles with these materials can cause ice to melt because of pressure from the wearer, creating the slippery surface the shoes are supposed to protect against.

Previous studies of gecko feet have led to new ideas for developing more effective anti-slip polymers. Those works found that their footpad’s stickiness comes from hydrophilic capillary-enhanced adhesion: The force of water being drawn into narrow grooves in the footpad creates suction that helps the lizard navigate slippery surfaces. Vipin Richhariya, Ashis Tripathy, Md Julker Nine and colleagues aimed to develop a polymer with capillary-enhanced adhesion that works on rainy sidewalks and frozen surfaces.

Read more | >

All we are made of comes from dying stars, those rare supernovae and other cosmic death throes that forge those scarce heavier elements, but could we learn true alchemy and mass manufacture those materials ourselves, and even others not found in nature?

Start Forging New Worlds: https://www.worldanvil.com/isaac-arthur.
Join this channel to get access to perks:
/ @isaacarthursfia.
Visit our Website: http://www.isaacarthur.net.
Join Nebula: https://go.nebula.tv/isaacarthur.
Support us on Patreon: / isaacarthur.
Support us on Subscribestar: https://www.subscribestar.com/isaac-a… Group: / 1,583,992,725,237,264 Reddit: / isaacarthur Twitter: / isaac_a_arthur on Twitter and RT our future content. SFIA Discord Server: / discord Credits: Nuclear Transmutation Science & Futurism with Isaac Arthur Episode 332, March 3, 2022 Written, Produced & Narrated by Isaac Arthur Editors: Jason Burbank Mark Warburton Yamagishi Cover Art: Jakub Grygier https://www.artstation.com/jakub_grygier Graphics: Jeremy Jozwik https://www.artstation.com/zeuxis_of_… Ken York / ydvisual Sergio Botero https://www.artstation.com/sboterod?f… Udo Schroeter Music by: Markus Junnikkala, https://markusjunnikkala.com “Mobilize the Fleets” “We Roam the Stars” Stellardrone, https://stellardrone.bandcamp.com “The Earth is Blue” “A Moment of Stillness” Aerium, https://aeriumambient.bandcamp.com “Fifth Star of Aldebaran” Miguel Johnson, https://migueljohnson.bandcamp.com “Strange New World“
Facebook Group: / 1583992725237264
Reddit: / isaacarthur.
Twitter: / isaac_a_arthur on Twitter and RT our future content.
SFIA Discord Server: / discord.

Credits:
Nuclear Transmutation.
Science & Futurism with Isaac Arthur.
Episode 332, March 3, 2022
Written, Produced & Narrated by Isaac Arthur.

Editors:

Continue reading “Nuclear Transmutation & Alchemy” | >

Share on Facebook: http://on.fb.me/13K5GUw.

What if you could fax someone a real, three-dimensional object? The solution might come in the form of programmable matter — a material that takes on predetermined shapes and can change its configuration on demand. We’re already seeing early prototypes coming from Carnegie Mellon and Intel in the form of “claytronics.” So what’s in store for this technology, and why should we be excited about it?

If you had a vat of claytronic atoms in front of you, what’s the first thing you’d build with it? Let us know in the comments below!

https://www.youtube.com/subscription_center?add_user=fwthinking.

Continue reading “Create Anything You Want With Programmable Matter” | >

A research team from Skoltech and ITMO university has obtained tunable polariton emission at room temperature on CsPbBr3 perovskite crystals as a promising platform for integration into lateral microchips—a new concept for the integrated all-optical logic that Skoltech researchers are working on.

The research results are presented in the Advanced Optical Materials journal.

Exciton-polaritons are hybridized states of light and matter, which are formed as a result of strong interaction of optical modes of microcavity—photons—with elementary excitations of a material—excitons.

Read more | >

Link :

Researchers have developed a new electrically active biomaterial that can be transplanted into the body to improve recovery following central nervous system injuries. The material acts as a scaffold that also provides electrical stimulation.

Read more | >

Superionic materials are a class of materials that simultaneously present properties that are characteristic of solids and liquids. Essentially, a set of ions in these materials exhibits liquid-like mobility, even if the materials’ underlying atomic structure maintains a solid-like order.

Due to their unique ionic conductivity patterns, superionic materials could be promising for developing . These are batteries that contain electrolytes based on solid materials instead of liquid electrolytes.

While various past studies have explored the potential of superionic materials as solid-state electrolytes, the physics underpinning their rapid ionic diffusion is not yet fully understood. Specifically, it is unclear whether this property results from liquid-like motion in the material or from the conventional lattice phonons (i.e., atom vibrations) in the material.

Read more | >

Half-metals are unique magnetic compounds that have been attracting interest in the development of mass-storage technologies. Some of the materials in the family of Heusler alloys were predicted to have a half-metallic nature, but their half-metallic electronic structure varies with their composition ratio and atomic ordered structure.

One property, , is fundamental to the material’s half-metallic properties. Spin polarization ratio is a physical property that indicates how polarized the number of electrons with spin in the up and down directions is.

Because spin polarization is influenced by the elemental composition of the Heusler alloy, it’s important to characterize and optimize the atomic composition of Heusler alloys to achieve the highest spin polarization. But current methods for determining the spin polarization of half-metals are either time-consuming or only provide an indirect measure.

Read more | >

Researchers from Oakland University have made a significant breakthrough in the field of optical materials, unveiling the exceptional capabilities of Ba₃(ZnB₅O₁₀)PO₄ (BZBP). Although this transparent crystal closely resembles ordinary window glass, it exhibits extraordinary properties that set it apart from others.

Already renowned for its exceptional qualities, such as excellent heat dissipation, minimal uneven expansion when exposed to temperature changes, and the ability to transmit (a type of light that comes from the sun and other sources like special lamps, but it’s invisible to the human eye), BZBP has emerged as an ideal choice for laser systems operating in deep ultraviolet ranges. These systems are crucial in fields such as medical diagnostics, semiconductor production, and cutting-edge scientific research.

In a study recently published in Advanced Functional Materials, researchers explored how BZBP performs under .

Read more | >

A research team has discovered that by using a new method of “atomic spray painting,” they can tweak the atomic structure of lead-free potassium niobate in order to enhance its ferroelectric properties.

The study, created by a team led by Penn State researchers, explains how molecular beam epitaxy can be employed to deposit atomic layers onto a substrate to create thin films, as a report by SciTechDaily explained.

Using a technique called strain tuning, the researchers adjusted how successive layers are aligned to modify a material’s properties by stretching or compressing the atoms that make up its crystal structure.

Read more | >