Abstract
In this study, we fabricated a 2 × 2 one-transistor static random-access memory (1T-SRAM) cell array comprising single-gated feedback field-effect transistors and examined their operation and memory characteristics. The individual 1T-SRAM cell had a retention time of over 900 s, nondestructive reading characteristics of 10,000 s, and an endurance of 108 cycles. The standby power of the individual 1T-SRAM cell was estimated to be 0.7 pW for holding the “0” state and 6 nW for holding the “1” state. For a selected cell in the 2 × 2 1T-SRAM cell array, nondestructive reading of the memory was conducted without any disturbance in the half-selected cells. This immunity to disturbances validated the reliability of the 1T-SRAM cell array.
Highlights
In this study, we fabricated a 2 × 2 one-transistor static random-access memory (1T-SRAM) cell array comprising single-gated feedback field-effect transistors and examined their operation and memory characteristics
Simulation studies have demonstrated that the low standby power consumption and reliability of one-transistor SRAM (1T-SRAM) cells, each of which consists of a single-gated feedback field-effect transistor (FBFET), provide a promising possibility for the future of memory devices[17]
A Ti/TiN/Al/TiN metal alloy was deposited for the bit line (BL), word line (WL), and source line (SL) contacts
Summary
We fabricated a 2 × 2 one-transistor static random-access memory (1T-SRAM) cell array comprising single-gated feedback field-effect transistors and examined their operation and memory characteristics. This is mainly because the low-power operation of SRAM cell arrays decreases the reliability of memory operation due to disturbances caused by the half selected c ell[14,15,16].
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