Tiny metajets could steer light sails for interstellar travel

Engineers at NASA's Jet Propulsion Laboratory have successfully tested larger rotor blades that spin faster than the speed of sound without breaking apart. The milestone, announced on Thursday, boosts lift capability by 30 percent for future Mars missions.

April 19, 2026 An Ruwaito ta hanyar AI

A team from Xidian University has developed a car-mounted microwave wireless power system that kept fixed-wing drones airborne for up to 3.1 hours. The system uses GPS positioning, dynamic tracking, and onboard flight controls to maintain alignment between the emitter and drone during flight. The findings were published on March 25 in the peer-reviewed journal Aeronautical Science & Technology.

Scientists at the University of Basel and ETH Zurich have reversed the polarity of a specialized ferromagnet with a focused laser beam, without heating the material. This achievement, detailed in Nature, combines electron interactions, topology, and dynamical control in a single experiment. The method hints at future light-based electronic circuits on chips.

February 17, 2026 An Ruwaito ta hanyar AI

Researchers led by Jun Ye at JILA in Boulder, Colorado, suggest placing an ultrastable laser in one of the moon's permanently shadowed craters to enhance navigation for lunar landers and rovers. The frigid, vibration-free environment near the lunar poles could enable unprecedented precision in timing and positioning. This setup might support activities from lunar timekeeping to satellite coordination.

An international team of researchers has achieved a milestone in quantum communication by teleporting the polarization state of a single photon between two separate quantum dots over a 270-meter open-air link. The experiment, conducted at Sapienza University of Rome, demonstrates the potential for quantum relays in future quantum networks. The findings were published in Nature Communications.

April 28, 2026 An Ruwaito ta hanyar AI

Researchers at MIT have discovered that chaotic laser light can self-organize into a highly focused pencil beam, enabling 3D imaging of the blood-brain barrier 25 times faster than current methods. The technique allows real-time observation of drugs entering brain cells without fluorescent tags. This breakthrough could speed up development of treatments for neurological diseases like Alzheimer's and ALS.