Embedded non–volatile memory study with surface potential based model

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Coupling coefficients calculation is known to be a critical issue in Non-Volatile Memory cell compact modelling. To this purpose, the accuracy of the capacitive network method can be significantly improved using the charge balance method, both methods relying on the floating gate potential calculation. In this study, the charge balance method has been implemented in a surface potential based model accounting for short channel and saturation velocity effects on both currents and charges, including an advanced 3-terminals-overlap model and fringing capacitances. The results obtained by our semi-analytical model are compared to 2D TCAD simulations, which have been previously calibrated on 65nm-node measurements. Excellent agreement is found for various device lengths and bias conditions. It is shown that the short channel effects, overlap capacitances and velocity saturation dominate over the intrinsic behaviour of the cell in ultra scaled devices, each playing an independent role on the coupling coefficients. Showing the dependency of the drain current with respect to stored FG charge, we extended our research to transient analysis, demonstrating the capability of our model to simulate the full electrical behaviour of a flash cell.

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Journal: TechConnect Briefs
Volume: 3, Nanotechnology 2009: Biofuels, Renewable Energy, Coatings, Fluidics and Compact Modeling
Published: May 3, 2009
Pages: 554 - 557
Industry sector: Sensors, MEMS, Electronics
Topic: WCM - Compact Modeling
ISBN: 978-1-4398-1784-1