Researchers at the University of Bristol and the UK Atomic Energy Authority have jointly developed a Carbon-14-based diamond battery with a lifespan of 5,700 years. This battery utilizes the radioactive decay of carbon-14 to generate low levels of power, by capturing fast-moving electrons from within the diamond structure. This diamond battery could revolutionize the energy sector with potential use in the medical, space, or tracking sectors.
This Nuclear-powered diamond battery lasts for thousands of years
This new type of battery has the potential to power devices for thousands of years
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The strongest silver ever
Promising new class of super-strong and conducting materials.
Scientists have created the strongest silver ever, 42% stronger than the previous record. They also discovered a way to strengthen metals at the nanoscale while preserving electrical conductivity. This breakthrough could lead to a new class of industrial materials that combine high strength with efficient electricity flow
Meet CORLEO: Kawasaki’s Robotic Horse of the Future
Revolutionizing adventure with four legs, hydrogen power, and next-level terrain agility
Kawasaki introduces CORLEO, a trailblazing robotic horse built for off-road thrill-seekers. With four agile robotic legs, a hydrogen-powered engine, and adaptive terrain hooves, CORLEO delivers a smooth, responsive ride over mountains, rubble, and rocky trails. Riders can control it using intuitive weight shifts and handlebars. Enhanced by shock absorption, a high-tech dashboard, and illuminated night navigation. Designed to merge sustainability with performance, CORLEO is more than a machine—it’s a bold step into the future of mobility. Saddle up and explore the wild like never before.
Breakthrough in Quantum Phase Transitions Advances Quantum Technologies
EPFL Researchers Observe First- and Second-Order Dissipative Phase Transitions
EPFL researchers have experimentally observed both first- and second-order dissipative phase transitions (DPTs) in a superconducting Kerr resonator. By introducing a two-photon drive, they precisely controlled quantum state transitions, revealing phenomena like squeezing, hysteresis, and critical slowing down. Their findings confirm theoretical predictions and enhance understanding of quantum systems. This breakthrough could lead to improved quantum computing error correction and ultra-sensitive quantum sensors. The study highlights the power of interdisciplinary collaboration, merging experimental physics, theory, and engineering to push the boundaries of quantum science.
Ultra-Compact Optical Amplifier Revolutionizes Data Transmission
Gallium Phosphide-Based TWPA Achieves Unprecedented Broadband Gain
Researchers from EPFL and IBM have developed a groundbreaking photonic-chip-based traveling-wave parametric amplifier (TWPA) that offers ultra-broadband optical signal amplification in a compact form. Using gallium phosphide-on-silicon dioxide technology, the amplifier delivers over 10 dB gain across 140 nm—three times the bandwidth of conventional EDFAs. Its strong optical nonlinearity boosts signals efficiently while minimizing noise. This innovation enhances optical networks, AI data centers, and precision sensing applications, marking a major step forward in high-speed data transmission and next-generation photonics.
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