Fast, Robust, and a Blast from the Past, Mechanical Memory Switch Outstrips Chip Technology
Nanomechanical memory cell could catapult efforts to improve data storage
There are no gears or levers involved, nor even, for those who remember such things, punch cards transported in oblong boxes. Yet research by a Boston University team led by physicist Pritiraj Mohanty does update a decidedly "old" technology in a bid to build better, faster data systems for today's computers.
Mohanty, an assistant professor in BU鈥檚 Department of 麻豆淫院ics, has carved tiny switches out of silicon, fabricating mechanical switches that are thousands of times smaller than a human hair.
When put through their paces as data storage tools, these nano-sized devices were capable of functioning at densities that far exceed the physical limitations of electromagnetic systems and could retrieve information at speeds that cruise in the megahertz and gigahertz ranges, millions and billions of cycles per second, respectively.
Mohanty also found that the switches operated on miniscule amounts of power, about a million-fold less than that demanded by current systems.
鈥淭his is a new ball game,鈥 say Mohanty. 鈥淏y taking a new look at old technology, we have produced memory cells that are faster and better than those currently used. This mechanical device is a completely new approach to improving data storage.鈥
The researchers used electron-beam lithography to produce the beam-and-pad design of the tiny devices, carving the switches from wafers made of single-crystal layers of silicon and silicon oxide. E-beam lithography, developed for use by the integrated circuit industry, has become a staple fabrication technique for microelectromechanical (MEMS) devices, the ultra-small sensors, switches, and gears integral to the microtechnology and nanotechnology industries.
To test the device鈥檚 capabilities, the researchers clamped the nanostructure on each end, effectively suspending the beam, then drove a megahertz-frequency current through an attached electrode. When driven strongly enough, the beam switched between two different and distinct states, the needed 鈥0鈥 and 鈥1鈥 conditions commonly used to describe the process for accessing stored data.
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The tiny dimensions of the device allowed it to vibrate quickly, achieving a millions-of-cycles-per-second frequency of 23.57 megahertz. This speed reflects the rate at which the device could 鈥渞ead鈥 stored information. As a comparison, the hard drives in current laptops can read at a speed of a few hundred kilohertz (thousands of cycles per second) in actual operation. The researchers speculate that even smaller beams could be produced and that such devices could achieve true read speeds in the gigahertz range 鈥 billions of cycles per second.
Other advantages of this tiny mechanical memory system include its angstrom-sized 鈥渞ange of motion,鈥 allowing it vibrate between states using only femtowatts of power, compared with the milliwatts or microwatts of power needed for read-write functions in current machines. The device also overcomes the superparamagnetic effect that limits contemporary systems, allowing the beams to be packed at densities that exceed the 100 gigabits per square inch that is the current ceiling. In addition, unlike conventional electronic or magneto-electronic storage systems, these nanomechanical memory cells are resilient in electrical and magnetic fields.
鈥淭hey are extremely robust,鈥 says Robert Badzey, a team member and graduate student in BU鈥檚 Department of 麻豆淫院ics. 鈥淣ot only can these mechanical switches withstand radiation disturbances, like solar flares, they also are tough enough to work even after being dropped.鈥
In addition to Mohanty and Badzey, the BU research team included Guiti Zolfagharkhani, a graduate student in physics, and Alexei Gaidarzhy, a graduate student in the College of Engineering鈥檚 Department of Aerospace and Mechanical Engineering. Their paper will appear in the October 18 issue of Applied 麻豆淫院ics Letters, a journal of the American Institute of 麻豆淫院ics. The research was supported by grants from the Nanoscale Exploratory Research program of the National Science Foundation and the Army Research Laboratory of the Department of Defense.
The 麻豆淫院ics Department at Boston University provides research opportunities in areas such as experimental high-energy physics and astrophysics, molecular biophysics, theoretical condensed-matter physics, and polymer physics. Research in the Department of Aerospace and Mechanical Engineering includes robotics, MEMS, and nanotechnology.
Boston University, with an enrollment of more than 29,000 in its 17 schools and colleges, is the fourth-largest independent university in the United States.
Source: BU