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Gain-Cell Embedded DRAM Under Cryogenic Operation—A First Study

Esteban Garzón, Yosi Greenblatt, Odem Harel, Marco Lanuzza, Adam Teman

2021IEEE Transactions on Very Large Scale Integration (VLSI) Systems41 citationsDOI

Abstract

Operating circuits under cryogenic conditions is effective for a large spectrum of applications. However, the refrigeration requirement for the cooling of cryogenic systems introduces serious issues in terms of power dissipation. Gain-cell embedded dynamic random access memory (GC-eDRAM) is a low-area, logic-compatible embedded memory alternative to static random access memory (SRAM), which has the potential to provide ultralow-power operation under cryogenic conditions due to the lower leakages at these temperatures. In this article, we present the first comparative design exploration of GC-eDRAM under cryogenic conditions performed with transistor models characterized based on actual silicon measurements under temperatures as low as 77 K. Our study shows that the two-transistor (2T)-based GC-eDRAM configurations turn out to be the best solutions for very low-temperature operation. In particular, the 2T mixed GC-eDRAM configurations allow read sensing margin improvements (up to 99%) within the 2T-based configurations while at the same time excel in terms of data retention time (+44%) and power consumption (-27%) when compared to more complex GC-eDRAM topologies. Moreover, even better improvements in terms of area (-73%), leakage power (-97%), retention power (-76%), and energy (-66%) are observed when compared to conventional 6T-SRAM.

Topics & Concepts

Static random-access memoryDramTransistorDissipationComputer scienceData retentionElectronic engineeringPower (physics)Dynamic random-access memoryEmbedded systemElectrical engineeringSemiconductor memoryVoltageEngineeringComputer hardwarePhysicsThermodynamicsQuantum mechanicsAdvancements in Semiconductor Devices and Circuit DesignSemiconductor materials and devicesFerroelectric and Negative Capacitance Devices