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Modeling of microtrenching and bowing effects in nanoscale Si inductively coupled plasma etching process

Ziyi Hu, Hua Shao, Junjie Li, Panpan Lai, Wenrui Wang, Chen Li, Q.W Yan, Xiaobin He, Junfeng Li, Tao Yang, Rui Chen, Yayi Wei

2023Journal of Vacuum Science & Technology A Vacuum Surfaces and Films13 citationsDOI

Abstract

Plasma etching effects, such as microtrenching and bowing, negatively impact device performance. Modeling of these effects at nanoscale is challenging, and theoretical and experimental investigations are highly desired to gain insights into mechanisms. In this paper, we propose a new plasma etching model based on Monte Carlo simulations with a cellular method. This model considers reactions and ion-enhanced etching and consists of a novel particle reflection algorithm, which is a key factor impacting the etch profile. This model reproduces the adjustable microtrenching and bowing effects in periodic dense trenches with tens of nanometer dimensions. We conduct experiments of Si etching by Cl2 and validate the model by comparing the simulated profile with cross-sectional scanning electron microscope images. This work enables a potential physical model driven process emulation tool toward design technology co-optimization.

Topics & Concepts

Etching (microfabrication)BowingPlasma etchingInductively coupled plasmaMaterials scienceNanoscopic scaleReactive-ion etchingEmulationPlasmaOptoelectronicsDry etchingNanotechnologyMonte Carlo methodScanning electron microscopeComposite materialPhysicsStatisticsPhilosophyMathematicsTheologyLayer (electronics)EconomicsQuantum mechanicsEconomic growthSemiconductor materials and devicesIon-surface interactions and analysisNanowire Synthesis and Applications
Modeling of microtrenching and bowing effects in nanoscale Si inductively coupled plasma etching process | Litcius