Researchers shed new light on G-quadruplexes, a type of secondary DNA structure that has attracted attention as a potential therapeutic target in cancer.

Researchers from the University of Science and Technology of China (USTC) have unveiled a planar optical device that ...

Electronic devices rely on materials whose electrical properties change with temperature, making them less stable in extreme ...

Scientists developed a new microscope based on Brillouin scattering -- a phenomenon where light interacts with naturally occurring thermal vibrations within materials, from which their mechanical ...

Instead, the crown goes to the new Black Badge version of the Rolls-Royce Spectre electric coupe. The legendary automaker has been using the Black Badge moniker to denote its high-performance ...

The new Black Badge Spectre is the most powerful production Rolls-Royce car ever. It peaks at 650bhp and 793lb ft, up from the 664bhp and 577lb ft outputs of the regular Spectre, the super-luxury ...

Rolls-Royce has unveiled the new Spectre Black Badge, which is their most powerful car. It has a dual-motor all-wheel drive system that can produce up to 650 hp and 793 lb-ft of torque.

Rolls-Royce Motor Cars, the ultra-luxury British subsidiary of BMW AG, says their new Black Badge Spectre, an all-electric two-door grand tourer, is their most powerful vehicle ever. Let's see if ...

Pass the Grey Poupon. Rolls-Royce has announced a Black Badge version of its all-electric Spectre, adding prestige and power by way of a new Infinity Mode. In the 2025 Spectre Black Badge ...

Rolls-Royce has introduced new levels of customisation with the Black Badge Spectre. One option enables ... which combines an array of high-end materials with digital screens and physical buttons.

“The result is Black Badge Spectre: the alter ego of our brand, amplified.” Oh it’s amplified alright, because this new Black Badge Spectre just happens to be the most powerful Rolls-Royce ...

Using single-molecule microscopy, they found that molecules primarily diffuse and adsorb around the outer edges, leaving the material’s center largely unused. Lydia Kisley. Image Credit: Case Western ...