Characterization of a novel radiation hardened by design (RHD14) bit-cell based on 20-nm FinFET technology using TCAD simulations

Abstract

Radiation has been a traditional concern in microelectronic devices used in space applications, causing high probability of single event upsets (SEUs). SEUs induced by particle radiation are becoming an increasingly important threat to the reliability of memories. Moreover, recent studies reveals that single event multiple-node upsets (SEMNUs) is the prime effect of radiation in SRAM chips fabricated in nanoscale CMOS technologies. In view of the weaknesses of the existing radiation hardened bit-cell configurations, a highly reliable radiation hardened by design (RHD14) bit-cell is proposed in this paper to address the issues related to SEUs and SEMNUs. Hardness against radiation of the proposed bit-cell is compared with the recently reported radiation hardened bit-cells and popular SRAM bit-cell (6T). Radiation and its effect in the bit-cells under consideration are simulated with the help of 3-D Technology Computer Aided Design (TCAD) and Visual Particle (VP) tools. Radiation hardening capability of RHD14 over the existing and conventional bit-cells is demonstrated focusing on linear energy transfer (LET) threshold and recovery time. It is observed that the proposed radiation hardened cell needs lesser silicon area and performs better in terms of power dissipation. Other performance metrics like read delay, write delay are also evaluated in order to study ensuing trade-off.