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First curved data link side-steps key 6G wireless challenge
Next-generation wireless signals will no longer emanate indiscriminately from a base station as is the case now but will likely take the form of targeted directional beams. However, any physical interference ⎯ an object or a person passing nearby, for example ⎯ could interrupt the signal, posing a literal obstacle toward the implementation of ultrafast millimeter-wave and sub-terahertz wireless networks.
Researchers at Rice University and Brown University, however, have shown that data-laden curved beams can establish a link between base stations and users, effectively side-stepping intervening obstacles. In a study published in Communications Engineering, the researchers demonstrated a sub-terahertz beam that follows a curved trajectory ⎯ an achievement that could revolutionize wireless communications by making a future of wireless data networks running on sub-terahertz frequencies more feasible.
Rice lab finds better way to handle hard-to-recycle material
Glass fiber-reinforced plastic (GFRP), a strong and durable composite material, is widely used in everything from aircraft parts to windmill blades. Yet the very qualities that make it robust enough to be used in so many different applications make it difficult to dispose of ⎯ consequently, most GFRP waste is buried in a landfill once it reaches its end of life. According to a study published in Nature Sustainability, Rice University researchers and collaborators have developed a new, energy-efficient upcycling method to transform glass fiber-reinforced plastic (GFRP) into silicon carbide, widely used in semiconductors, sandpaper and other products.
This new process grinds up GFRP into a mixture of plastic and carbon and involves adding more carbon, when necessary, to make the mixture conductive. The researchers then apply high voltage to it using two electrodes, bringing its temperature up to 1,600-2,900 degrees Celsius (2,912-5,252 Fahrenheit).
While this initial study was a proof-of-concept test on a bench scale in the laboratory, Tour and colleagues are already working with outside companies to scale up the process for wider use. The operating costs to upcycle GFRP are less than $0.05 per kilogram, much cheaper than incineration or solvolysis ⎯ and more environmentally friendly.