Jul 29, 2025
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Groundbreaking research led by Dr. Maciej Dąbrowski at the University of Exeter has developed ultrafast, laser-driven magnetic domain mem...
Groundbreaking research led by Dr. Maciej Dąbrowski at the University of Exeter has developed ultrafast, laser-driven magnetic domain memories using 2D van der Waals materials. By leveraging their unique properties—low thermal conductivity and anisotropic heat dissipation—the team manipulated magnetism with sub-picosecond precision using laser pulses, turning heat management into an advantage. Controlling magnetic layer thickness enhanced heat dissipation and recovery, paving the way for efficient, non-volatile memory devices without external magnetic fields. Published in Nature, this study promises faster, smaller data storage solutions and advances in quantum technologies.
PCB of the Day! SPI Non-Volatile FRAM Breakout - 2 Mbit / 256 KBytes - MB85RS2MTA 🔌🛠️💾
Similar to Dynamic random-access memory, only with a ferroelectric layer instead of a dielectric layer. This gives it stable handling (the bytes you write are non-volatile) with dynamic responsiveness (you can write them very fast!). With our SPI FRAM breakout board, you can add FRAM storage to your next DIY project. FRAM allows for lower power usage and a faster write performance. It's excellent for low-power or inconsistent-power data logging or data buffering, where you want to stream data fast while keeping the data when there's no power. Unlike Flash or EEPROM, there are no pages to worry about. Each byte can be read/written 10,000,000,000,000 times, so you don't have to worry too much about wear leveling.
FRAM, or Ferroelectric Ram, is the coolest new data storage method that all the fashion magazines are talking about. Oh wait, no t
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A well-maintained set of data tape drives allows for dependable long-term storage. Many digital tapes can retain data for 30 years or more without regular maintenance.
Nowadays digital data is a very important part of our life. Data storage devices like SSDs, flash memory devices and SD cards are some of the well-known storage units we are using since long & every day. DNA will be the next big thing for digital data storage in the future. Yes, Data storage in DNA is now a reality: http://bit.ly/DNA_Data_Storage
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University of California, Irvine scientists recently discovered a one-dimensional nanoscale material whose color changes as temperature chan
The optical thermometers can also potentially measure the temperatures and assess the efficiencies of micro- and nano-electronics, including circuits and data storage devices. Industries already have optical thermometers they use when fabricating computer components, but the team’s new material is “at least an order of magnitude more sensitive.
Researchers at the University of Chicago Pritzker School of Molecular Engineering (PME) have made unexpected progress toward developing a ne
Researchers at the University of Chicago Pritzker School of Molecular Engineering (PME) have made unexpected progress toward developing a new optical memory that can quickly and energy-efficiently store and access computational data. While studying a complex material composed of manganese, bismuth and tellurium (MnBi2Te4), the researchers realized that the material’s magnetic properties changed quickly and easily in response to light. This means that a laser could be used to encode information within the magnetic states of MnBi2Te4.