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Lister says during this talent shortage, companies are going to need to meet the demands of workers, which will likely include a hybrid model.

Her research found that 56% of U.S. workers have a job that can be done at least partially remotely. She says allowing employees to shift their hours, which days they work, and even when they take a break can have a huge impact on retention.

Technology will have an outsized role in how companies implement their hybrid models. Lister says that within five years, employees may be able to meet via hologram instead of through a video call.

Continue reading “Hybrid work is here to stay. Activating your hologram may be the next way to enter a meeting” | >

Frogs briefly treated with a five-drug cocktail administered by a wearable bioreactor on the stump were able to regrow a functional, nearly complete limb.

For millions of patients who have lost limbs for reasons ranging from diabetes to trauma, the possibility of regaining function through natural regeneration remains out of reach. Regrowth of legs and arms remains the province of salamanders and superheroes.

But in a study published in the journal Science Advances, scientists at Tufts University and Harvard University’s Wyss Institute have brought us a step closer to the goal of regenerative medicine.

Continue reading “Scientists Regrow Frog’s Lost Leg With a Five-Drug Cocktail” | >

A newly created nano-architected material exhibits a property that previously was just theoretically possible: it can refract light backward, regardless of the angle at which the light strikes the material.

This property is known as negative refraction and it means that the refractive index—the speed that light can travel through a given material—is negative across a portion of the electromagnetic spectrum at all angles.

Refraction is a common property in materials; think of the way a straw in a glass of water appears shifted to the side, or the way lenses in eyeglasses focus light. But negative refraction does not just involve shifting light a few degrees to one side. Rather, the light is sent in an angle completely opposite from the one at which it entered the material. This has not been observed in nature but, beginning in the 1960s, was theorized to occur in so-called artificially periodic materials—that is, materials constructed to have a specific structural pattern. Only now have fabrication processes have caught up to theory to make a reality.

Continue reading “Nano-architected material refracts light backward; an important step toward creating photonic circuits” | >

New biodegradable straws developed in China are as cheap as plastic, stronger than paper, and made from edible materials — but can they make a difference in the global plastic waste problem?

Plastic everywhere: People produce 330 million tons of plastic every year. Less than 9% of it is recycled, and about 12% is incinerated — the rest ends up polluting our natural environment or languishing in landfills.

Continue reading “New biodegradable straws are made by bacteria” | >

All-polymer blend solar cells are expected to play an important role in the transition to clean energy technologies because they can be easily produced in large-scale flexible sheets. However, their performance has lagged behind that of more traditional silicon alternatives, as well as other organic solar cells.

All-polymer blend are formed by combining two polymer solutions that solidify into a film on an electrode with in the form of interpenetrating networks, a kind of “phase-separation.” The introduction of solvent additives to the polymer solution has been shown to increase the efficiency of all-polymer blend solar . However, the exact process underlying this improvement has not been fully understood. Now, in a study recently published in ACS Applied Polymer Materials, researchers from Nara Institute of Science and Technology have investigated the performance enhancement mechanism using photoconductive atomic force microscopy (PC-AFM). Their findings are expected to help accelerate the widespread application of polymer-based solar cells.

“The empirical nature of solvent additive-mediated efficiency enhancement has hindered the optimization of all-polymer blend solar cell performance, so there has been an urgent need for a greater understanding of the process,” explains senior author Hiroaki Benten. “To that end, we used PC-AFM to interrogate the nanoarchitecture that underpins the performance enhancement.”

Continue reading “Illuminating how solvent additives improve efficiency in polymer solar cells” | >

Time crystals. Microwaves. Diamonds. What do these three disparate things have in common?

Quantum computing. Unlike traditional computers that use bits, quantum computers use qubits to encode information as zeros or ones, or both at the same time. Coupled with a cocktail of forces from quantum physics, these refrigerator-sized machines can process a whole lot of information — but they’re far from flawless. Just like our regular computers, we need to have the right programming languages to properly compute on quantum computers.

Programming quantum computers requires awareness of something called “entanglement,” a computational multiplier for qubits of sorts, which translates to a lot of power. When two qubits are entangled, actions on one qubit can change the value of the other, even when they are physically separated, giving rise to Einstein’s characterization of “spooky action at a distance.” But that potency is equal parts a source of weakness. When programming, discarding one qubit without being mindful of its entanglement with another qubit can destroy the data stored in the other, jeopardizing the correctness of the program.

Continue reading “Twist: MIT’s New Programming Language for Quantum Computing” | >

New findings from the Curiosity Rover’s samples have given scientists another look at distinct carbon signatures found on Mars.

NASA’s Curiosity Rover continues to send back new information about the Red Planet on a frequent basis. The latest discovery brings news of an interesting carbon signature that we didn’t expect to see on Mars. Following analyzations of rock samples returned by the rover, NASA announced that several of the samples are rich in a carbon type that we see on Earth, too. The signature, NASA claims, is most often associated with biological processes, which could give more credence to the possibility of life on Mars.

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Of course, like many previous samples recovered from the Red Planet, these new ones continue to raise new questions. It’s worth noting that the existence of the carbon type on Mars isn’t necessarily proof of ancient life. A new study says that the signature could be proof of ancient life. However, it could also just be the result of an interaction between carbon dioxide and ultraviolet light. Additionally, it could be the remnants of carbon left behind after a major cosmic event that happened millions of years ago.

Continue reading “NASA may have discovered evidence of ancient life on Mars” | >

The ultimate goal, still years away, is to generate power the way the sun generates heat, by smooshing hydrogen atoms so close to each other that they combine into helium, which releases torrents of energy.

WATCH: Is alluring but elusive fusion energy possible in our lifetime?

A team of more than 100 scientists published the results of four experiments that achieved what is known as a burning plasma in Wednesday’s journal Nature. With those results, along with preliminary results announced last August from follow-up experiments, scientists say they are on the threshold of an even bigger advance: ignition. That’s when the fuel can continue to “burn” on its own and produce more energy than what’s needed to spark the initial reaction.

Continue reading “Burn, baby, burn: Nuclear scientists achieve major fusion feat” | >
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