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Development and application of the Oxide Stress Separation technique for the measurement of ONO leakage currents at low electric fields in 40 nm floating gate embedded-flash memory

Published on 29 March 2018
Development and application of the Oxide Stress Separation technique for the measurement of ONO leakage currents at low electric fields in 40 nm floating gate embedded-flash memory
Description
 
Date 
Authors
Dobri A., Jeannot S., Piazza F., Jahan C., Coignus J., Perniola L., Balestra F.
Year2017-0138
Source-TitleMicroelectronics Reliability
Affiliations
STMicroelectronics, Crolles, France, CEA-LETI, Grenoble, France, IMEP-LAHC, Université Grenoble Alpes, Grenoble, France
Abstract
The silicon dioxide/silicon nitride/silicon dioxide (ONO) inter-gate dielectric layer has long been used in floating gate flash memories to provide coupling with the control gate, while simultaneously blocking leakage to it. Given the thickness and quality of the ONO, it is not possible to directly measure the leakage currents at low electric fields. This article presents the Oxide Stress Separation (OSS) technique which places a flash cell in a condition where the potential drop occurs entirely across the ONO. This allows for the measurement of currents on the order of 10? 23 A to be measured at low electric fields using nominal floating gate flash memory cells. Using OSS, state-of-the-art 40 nm embedded-flash memories are characterized, allowing an evaluation of data retention contributors. Comparing OSS results with bake tests, ONO is found to be minimally responsible for the data retention drift, even in modern memories. © 2016
Author-Keywords
40 nm embedded flash, Flash memory, Floating gate, Leakage current, ONO
Index-Keywords
Electric field measurement, Electric fields, Gate dielectrics, Leakage currents, Development and applications, Embedded flash, Embedded flash memory, Floating gate flash memory, Floating gates, Gate dielectric layers, Potential drop, State of the art, Flash memory
ISSN262714
LinkLink

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