Sparse identification modeling and predictive control of wafer temperature in an atomic layer etching reactor

Feiyang Ou; Fahim Abdullah; Henrik Wang; Matthew Tom; Gerassimos Orkoulas; Panagiotis D. Christofides

doi:10.1016/j.cherd.2023.12.024

Sparse identification modeling and predictive control of wafer temperature in an atomic layer etching reactor

Feiyang Ou, Fahim Abdullah, Henrik Wang, Matthew Tom, Gerassimos Orkoulas, Panagiotis D. Christofides

Multiscale Materials

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4 Scopus citations

Abstract

To address the escalating demand and supply constraints for semiconductor devices, manufacturing techniques such as thermal atomic layer etching (ALE) have been utilized, which require robust temperature control systems. Radiative heating with lamps is a promising method for achieving fast and precise temperature control. However, there is limited research in analyzing the dynamic control of radiative lamp heating systems. In this study, a transient, two-dimensional (2-D) radiative heating model in a cross-flow thermal ALE reactor is constructed through Ansys Fluent. A sparse identification (SINDy) modeling approach is applied to build a reduced-order dynamic model for the prediction of system states in the control system. A model predictive controller (MPC) is then developed to bring the wafer surface temperature to the target temperature while preserving the uniformity of the temperature on the wafer surface. Control is implemented by adjusting the powers of three groups of heating lamps independently. Notably, a novel feedback-based time-varying steady-state penalty approach is applied with the MPC in this study, which enables the system to reach the target temperature range within 10 s while maintaining temperature uniformity for 1000 s.

Original language	English
Pages (from-to)	1-11
Number of pages	11
Journal	Chemical Engineering Research and Design
Volume	202
DOIs	https://doi.org/10.1016/j.cherd.2023.12.024
State	Published - Feb 2024

Funding

Financial support from the National Science Foundation, United States is gratefully acknowledged. This work used computational and storage services associated with the Hoffman2 Shared Cluster provided by UCLA Institute for Digital Research and Education's Research Technology Group. Financial support from the National Science Foundation, United States is gratefully acknowledged. This work used computational and storage services associated with the Hoffman2 Shared Cluster provided by UCLA Institute for Digital Research and Education’s Research Technology Group.

Keywords

Atomic layer etching
Computer aided engineering
Model predictive control
Radiative heating lamps
Sparse identification modeling

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10.1016/j.cherd.2023.12.024

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title = "Sparse identification modeling and predictive control of wafer temperature in an atomic layer etching reactor",

abstract = "To address the escalating demand and supply constraints for semiconductor devices, manufacturing techniques such as thermal atomic layer etching (ALE) have been utilized, which require robust temperature control systems. Radiative heating with lamps is a promising method for achieving fast and precise temperature control. However, there is limited research in analyzing the dynamic control of radiative lamp heating systems. In this study, a transient, two-dimensional (2-D) radiative heating model in a cross-flow thermal ALE reactor is constructed through Ansys Fluent. A sparse identification (SINDy) modeling approach is applied to build a reduced-order dynamic model for the prediction of system states in the control system. A model predictive controller (MPC) is then developed to bring the wafer surface temperature to the target temperature while preserving the uniformity of the temperature on the wafer surface. Control is implemented by adjusting the powers of three groups of heating lamps independently. Notably, a novel feedback-based time-varying steady-state penalty approach is applied with the MPC in this study, which enables the system to reach the target temperature range within 10 s while maintaining temperature uniformity for 1000 s.",

keywords = "Atomic layer etching, Computer aided engineering, Model predictive control, Radiative heating lamps, Sparse identification modeling",

author = "Feiyang Ou and Fahim Abdullah and Henrik Wang and Matthew Tom and Gerassimos Orkoulas and Christofides, {Panagiotis D.}",

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doi = "10.1016/j.cherd.2023.12.024",

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AU - Ou, Feiyang

AU - Abdullah, Fahim

AU - Wang, Henrik

AU - Tom, Matthew

AU - Orkoulas, Gerassimos

AU - Christofides, Panagiotis D.

PY - 2024/2

Y1 - 2024/2

N2 - To address the escalating demand and supply constraints for semiconductor devices, manufacturing techniques such as thermal atomic layer etching (ALE) have been utilized, which require robust temperature control systems. Radiative heating with lamps is a promising method for achieving fast and precise temperature control. However, there is limited research in analyzing the dynamic control of radiative lamp heating systems. In this study, a transient, two-dimensional (2-D) radiative heating model in a cross-flow thermal ALE reactor is constructed through Ansys Fluent. A sparse identification (SINDy) modeling approach is applied to build a reduced-order dynamic model for the prediction of system states in the control system. A model predictive controller (MPC) is then developed to bring the wafer surface temperature to the target temperature while preserving the uniformity of the temperature on the wafer surface. Control is implemented by adjusting the powers of three groups of heating lamps independently. Notably, a novel feedback-based time-varying steady-state penalty approach is applied with the MPC in this study, which enables the system to reach the target temperature range within 10 s while maintaining temperature uniformity for 1000 s.

AB - To address the escalating demand and supply constraints for semiconductor devices, manufacturing techniques such as thermal atomic layer etching (ALE) have been utilized, which require robust temperature control systems. Radiative heating with lamps is a promising method for achieving fast and precise temperature control. However, there is limited research in analyzing the dynamic control of radiative lamp heating systems. In this study, a transient, two-dimensional (2-D) radiative heating model in a cross-flow thermal ALE reactor is constructed through Ansys Fluent. A sparse identification (SINDy) modeling approach is applied to build a reduced-order dynamic model for the prediction of system states in the control system. A model predictive controller (MPC) is then developed to bring the wafer surface temperature to the target temperature while preserving the uniformity of the temperature on the wafer surface. Control is implemented by adjusting the powers of three groups of heating lamps independently. Notably, a novel feedback-based time-varying steady-state penalty approach is applied with the MPC in this study, which enables the system to reach the target temperature range within 10 s while maintaining temperature uniformity for 1000 s.

KW - Atomic layer etching

KW - Computer aided engineering

KW - Model predictive control

KW - Radiative heating lamps

KW - Sparse identification modeling

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ER -

Sparse identification modeling and predictive control of wafer temperature in an atomic layer etching reactor

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