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Dec 21, 2019
This company is building self-driving hotel rooms that could be a new, futuristic way to take road trips
Posted by Shailesh Prasad in categories: food, robotics/AI, space travel
The Autonomous Travel Suites will have built-in beds, private bathrooms with a toilet and sitting shower, a small kitchen, and entertaining space.
Dec 21, 2019
A near indestructible gel made of mostly air
Posted by Shailesh Prasad in category: futurism
Dec 21, 2019
What started as a small-scale project grew to become a âcyber suitâ, with life-changing potential.đŻ
Posted by Shailesh Prasad in category: futurism
Dec 21, 2019
AI creates âFlintstonesâ cartoons from text descriptions
Posted by Shailesh Prasad in category: robotics/AI
Dec 21, 2019
ESAâs CHEOPS Just Launched. Weâre About to Learn a LOT More About Exoplanets
Posted by Genevieve Klien in category: space
The CHEOPS mission is underway. On December 18th, the exoplanet-studying spacecraft launched from Europeâs Spaceport in Kourou, French Guiana aboard a Soyuz-Fregat rocket. Initial signals from CHEOPS show that the launch was a success.
CHEOPS stands for the Characterizing Exoplanet Satellite. Itâs a partnership between ESA and Switzerland, with 10 other EU states contributing. Its mission is not to find more exoplanets, but to study the ones we already know of.
Dec 21, 2019
The immune system listens in on bacteria signaling to each other
Posted by Genevieve Klien in category: biotech/medical
Dec 21, 2019
Space-time metasurface makes light reflect only in one direction
Posted by Quinn Sena in categories: physics, space travel
Light propagation is usually reciprocal, meaning that the trajectory of light travelling in one direction is identical to that of light travelling in the opposite direction. Breaking reciprocity can make light propagate only in one direction. Optical components that support such unidirectional flow of light, for example isolators and circulators, are indispensable building blocks in many modern laser and communication systems. They are currently almost exclusively based on the magneto-optic effect, making the devices bulky and difficult for integration. A magnetic-free route to achieve nonreciprocal light propagation in many optical applications is therefore in great demand.
Recently, scientists developed a new type of optical metasurface with which phase modulation in both space and time is imposed on the reflected light, leading to different paths for the forward and backward light propagation. For the first time, nonreciprocal light propagation in free space was realized experimentally at optical frequencies with an ultrathin component.
âThis is the first optical metasurface with controllable ultrafast time-varying properties that is capable of breaking optical reciprocity without a bulky magnet,â said Xingjie Ni, the Charles H. Fetter Assistant Professor in Department of Electrical Engineering at the Pennsylvania State University. The results were published this week in Light: Science and Applications.
