Silicon nanowires upgrade data-storage technology
Scientists at the National Institute of Standards and Technology, along with colleagues at George Mason University and Kwangwoon University in Korea, have fabricated a memory device that combines silicon nanowires with a more traditional type of data-storage. Their hybrid structure may be more reliable than other nanowire-based memory devices recently built and more easily integrated into commercial applications.
As reported in a recent paper, the device is a type of 鈥渘on-volatile鈥 memory, meaning stored information is not lost when the device is without power. So-called 鈥渇lash鈥 memory (used in digital camera memory cards, USB memory sticks, etc.) is a well-known example of electronic non-volatile memory.
In this new device, nanowires are integrated with a higher-end type of non-volatile memory that is similar to flash, a layered structure known as semiconductor-oxide-nitride-oxide-semiconductor (SONOS) technology. The nanowires are positioned using a hands-off self-alignment technique, which could allow the production cost鈥攁nd therefore the overall cost鈥攐f large-scale viable devices to be lower than flash memory cards, which require more complicated fabrication methods.
The researchers grew the nanowires onto a layered oxide-nitride-oxide substrate. Applying a positive voltage across the wires causes electrons in the wires to tunnel down into the substrate, charging it. A negative voltage causes the electrons to tunnel back up into the wires. This process is the key to the device鈥檚 memory function: when fully charged, each nanowire device stores a single bit of information, either a 鈥0鈥 or a 鈥1鈥 depending on the position of the electrons. When no voltage is present, the stored information can be read.
The device combines the excellent electronic properties of nanowires with established technology, and thus has several characteristics that make it very promising for applications in non-volatile memory. For example, it has simple read, write, and erase capabilities. It boasts a large memory window鈥攖he voltage range over which it stores information鈥攚hich indicates good memory retention and a high resistance to disturbances from outside voltages. The device also has a large on/off current ratio, a property that allows the circuit to clearly distinguish between the 鈥0鈥 and 鈥1鈥 states.
Two advantages the NIST design may hold over alternative proposals for nanowire-based memory devices, the researchers say, are better stability at higher temperatures and easier integration into existing chip fabrication technology.
Citation: Q. Li, X. Zhu, H. Xiong, S.-M. Koo, D.E. Ioannou, J. Kopanski, J.S. Suehle and C.A. Richter. Silicon nanowire on oxide/nitride/oxide for memory application. Nanotechnology 18 (2007) 235204.
Source: National Institute of Standards and Technology
