A squishy material made of thin layers might help make your future devices faster and more energy efficient. This new hybrid ...

Electronic devices power everyday life, from smartphones to medical sensors. Yet, as these gadgets grow in number, so does the mounting challenge of electronic waste, or e-waste. Physically ...

Materials with high magnetoelectric coupling could be useful in novel devices such as magnetic computer memories, chemical sensors and quantum computers.

Magnetoresistive random-access memory, or MRAM, promises to make computers more efficient and powerful, but a few hurdles still need to be cleared.

Computer memory could one day withstand the blazing temperatures in fusion reactors, jet engines, geothermal wells and sweltering planets using a new solid-state memory device developed by a team ...

Organic transistor memory devices integrate organic semiconducting materials with field‐effect transistor architectures to achieve nonvolatile data storage. These devices harness charge trapping ...

Kioxia's UFS 4.1 memory devices are developed to meet the demands of next-generation mobile applications, including smartphones with on-device AI.

Researchers have demonstrated that the layered multiferroic material nickel iodide (NiI2) may be the best candidate yet for devices such as magnetic computer memory that are extremely fast and ...

Newly discovered role of phase separation can help develop memory devices for energy-efficient AI computing.

How does computer memory work? To truly understand how computer memory works, we must first examine the basic building blocks that make it possible: transistors and logic gates.