美国国家科学院的研究人员使用纳米孔传感器创建了可重写的DNA硬盘, 推动了可持续的高密度数据存储. Atlas and imec teamed up to build scalable DNA storage chips, while MU researchers created a rewritable DNA hard drive using nanopore sensors, advancing sustainable, high-density data storage.

通过将阿特拉斯的DNA合成专业知识与imec的半导体技术结合起来, 创建一个高密度的芯片, 使得数百万个DNA合成站点可以同时被控制. Atlas Data Storage and imec have partnered to accelerate DNA-based data storage, combining Atlas’s DNA synthesis expertise with imec’s semiconductor technology to create a high-density silicon chip that enables millions of DNA synthesis sites to be controlled at once. 合作的目的是通过利用DNA的极端数据密度、长期稳定性和低功率使用来克服传统储存的可缩放性和能源挑战。 The collaboration aims to overcome scalability and energy challenges of traditional storage by leveraging DNA’s extreme data density, long-term stability, and low power use. 同时,密苏里大学研究人员开发了一个可重读的DNA硬盘,使用纳米波尔传感器来读和覆盖数据,使DNA储存可以重新使用,并更实用地用于日常使用。 Meanwhile, University of Missouri researchers have developed a rewritable DNA hard drive using a nanopore sensor to read and overwrite data, making DNA storage reusable and more practical for everyday use. 该系统通过电子信号将DNA序列转换成数字数据,其速度更快、效率更高,并且有可能缩到USB大小。 The system, which converts DNA sequences into digital data via electrical signals, is faster, more efficient, and potentially miniaturizable to USB size. 这些进步加在一起,代表着在为AI时代找到可持续的、高容量的数据储存解决方案方面取得的重大进展。 Together, these advances represent major progress toward sustainable, high-capacity data storage solutions for the AI era.