Abstract
The development of the nanoelectronics semiconductor devices leads to the shrinking of transistors channel into nanometer dimension. However, there are obstacles that appear with downscaling of the transistors primarily various short-channel effects. Graphene nanoribbon field-effect transistor (GNRFET) is an emerging technology that can potentially solve the issues of the conventional planar MOSFET imposed by quantum mechanical (QM) effects. GNRFET can also be used as static random-access memory (SRAM) circuit design due to its remarkable electronic properties. For high-speed operation, SRAM cells are more reliable and faster to be effectively utilized as memory cache. The transistor sizing constraint affects conventional 6T SRAM in a trade-off in access and write stability. This paper investigates on the stability performance in retention, access, and write mode of 15 nm GNRFET-based 6T and 8T SRAM cells with that of 16 nm FinFET and 16 nm MOSFET. The design and simulation of the SRAM model are simulated in synopsys HSPICE. GNRFET, FinFET, and MOSFET 8T SRAM cells give better performance in static noise margin (SNM) and power consumption than 6T SRAM cells. The simulation results reveal that the GNRFET, FinFET, and MOSFET-based 8T SRAM cells improved access static noise margin considerably by 58.1%, 28%, and 20.5%, respectively, as well as average power consumption significantly by 97.27%, 99.05%, and 83.3%, respectively, to the GNRFET, FinFET, and MOSFET-based 6T SRAM design.
Highlights
Academic Editor: Raul Arenal e development of the nanoelectronics semiconductor devices leads to the shrinking of transistors channel into nanometer dimension
Our findings revealed that the static noise margin during the access mode is greatly improved in Graphene nanoribbon field-effect transistor (GNRFET)-based 8T static random-access memory (SRAM) cells
GNRFET is another alternative solution to solve the obstacles and challenges that occur in the conventional planar MOSFET in the sub-100 nm technology node
Summary
Carbon-based FETs have risen over the years in view of their exceptional characteristics and compatibility to contemporary silicon-based fabrication processes [1]. In 8T SRAM cells, two n-type FETs are added to the conventional 6T SRAM cells, which are controlled by the read word line (RWL) to isolate the access and write mode path for better access stability. Transistor Sizing for 6T and 8T SRAM Cells. To isolate the cell core from the output, two extra n-type transistors with a control signal and additional bit line are incorporated. To isolate the cell core from the output, two extra n-type transistors with a control signal and additional bit line are incorporated. e write mode is performed through the access transistors. e access mode is conducted, and the data stored appears on the access bit. e cross-coupled inverters in the design is open circuited for the write mode as feedback loop is only needed in the access mode to store the data [16]
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