Diamond storage breaks records by holding data for millions of years

The famous marketing slogan that diamonds are forever may be just a slight exaggeration for diamond-based systems that can store information for millions of years. Now, researchers have developed a system with a record-breaking storage density of 1.85 terabytes per cubic centimeter.

Previous technology used laser pulses to encode data onto diamond, but due to its higher storage density, a diamond optical disc with the same capacity as a standard Blu-ray could hold approximately 100 terabytes of data (Blu-ray). (equivalent to approximately 2,000 rays). It lasts much longer than the typical Blu-ray lifespan of just a few decades.

“Once the internal data storage structure is stabilized using our technology, diamond can achieve an extraordinary lifetime of millions of years of data retention at room temperature without requiring maintenance,” he says. Wang Ya at the University of Science and Technology of China in Hefei.

Wang and his colleagues conducted their research using tiny pieces of diamond, just a few millimeters long, but say future versions of the system could use rapidly spinning diamond discs. Their method used ultrafast laser pulses to knock some of diamond’s carbon atoms out of place, leaving single-atom-sized empty spaces, each exhibiting a stable brightness level.

By controlling the laser’s energy, the researchers were able to create multiple empty spaces at specific locations within the diamond, and the density of those spaces influenced the overall brightness of each site. . “The number of free spaces can be determined by looking at the brightness, so the stored information can be read,” Wang says.

The team then saved the images, including a colorful painting by artist Henri Matisse. cat with red fish And a series of photographs taken by Eadweard Muybridge in 1878, showing a rider on a galloping horse, maps the brightness of each pixel to the brightness level of a specific region within a diamond. The system stored this data with over 99% accuracy and completeness.

This preservation method is not yet commercially viable because it requires expensive lasers, high-speed fluorescence imaging cameras, and other devices, Wang said. But he and his colleagues hope that the diamond-based system can eventually be miniaturized to fit in a space the size of a microwave oven.

“In the short term, government agencies, research institutes, and libraries with a focus on archives and data preservation may be eager to adopt this technology,” he says.