Prediction of surface microtrenching by using neural network

Byungwhan Kim; Dong Hwan Kim; Jaeyoung Park; Seung Soo Han

doi:10.1016/j.cap.2006.09.018

Prediction of surface microtrenching by using neural network

Byungwhan Kim
, Dong Hwan Kim
, Jaeyoung Park
, Seung Soo Han

Dept. of Mechanical System and Design Engineering

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Silicon oxynitride films were etched in a C₂F₆ inductively coupled plasma. A prediction model of microtrenching depth (MD) was constructed by using a neural network and a genetic algorithm. For a systematic modeling, etching data were collected by using a statistical experimental design. The process parameters and ranges were 400-1000 W, 30-90 W, 6-12 mTorr, and 30-60 sccm for source power, bias power, pressure, and C₂F₆ flow rate, respectively. The root mean-squared prediction error of the constructed model was about 0.019. The model was utilized to generate 3-D plots, which were used to examine etch mechanisms under various plasma conditions. Depending on the plasma conditions, parameter effects on MD were quite different. For most of the parameter variations, MD variations were strongly related to profile angle variations. The effect of bias power on MD seems to be dominated by polymer deposition due to the variations in C₂F₆ flow rates maintained in the chamber.

Original language	English
Pages (from-to)	434-439
Number of pages	6
Journal	Current Applied Physics
Volume	7
Issue number	4
DOIs	https://doi.org/10.1016/j.cap.2006.09.018
State	Published - May 2007

Keywords

Computer modeling and simulation
Neural networks
Plasma etching

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10.1016/j.cap.2006.09.018

Cite this

@article{57674b6db5994ef0bcb9b414fef6e691,

title = "Prediction of surface microtrenching by using neural network",

abstract = "Silicon oxynitride films were etched in a C2F6 inductively coupled plasma. A prediction model of microtrenching depth (MD) was constructed by using a neural network and a genetic algorithm. For a systematic modeling, etching data were collected by using a statistical experimental design. The process parameters and ranges were 400-1000 W, 30-90 W, 6-12 mTorr, and 30-60 sccm for source power, bias power, pressure, and C2F6 flow rate, respectively. The root mean-squared prediction error of the constructed model was about 0.019. The model was utilized to generate 3-D plots, which were used to examine etch mechanisms under various plasma conditions. Depending on the plasma conditions, parameter effects on MD were quite different. For most of the parameter variations, MD variations were strongly related to profile angle variations. The effect of bias power on MD seems to be dominated by polymer deposition due to the variations in C2F6 flow rates maintained in the chamber.",

keywords = "Computer modeling and simulation, Neural networks, Plasma etching",

author = "Byungwhan Kim and Kim, \{Dong Hwan\} and Jaeyoung Park and Han, \{Seung Soo\}",

year = "2007",

month = may,

doi = "10.1016/j.cap.2006.09.018",

language = "English",

volume = "7",

pages = "434--439",

journal = "Current Applied Physics",

issn = "1567-1739",

number = "4",

}

TY - JOUR

T1 - Prediction of surface microtrenching by using neural network

AU - Kim, Byungwhan

AU - Kim, Dong Hwan

AU - Park, Jaeyoung

AU - Han, Seung Soo

PY - 2007/5

Y1 - 2007/5

N2 - Silicon oxynitride films were etched in a C2F6 inductively coupled plasma. A prediction model of microtrenching depth (MD) was constructed by using a neural network and a genetic algorithm. For a systematic modeling, etching data were collected by using a statistical experimental design. The process parameters and ranges were 400-1000 W, 30-90 W, 6-12 mTorr, and 30-60 sccm for source power, bias power, pressure, and C2F6 flow rate, respectively. The root mean-squared prediction error of the constructed model was about 0.019. The model was utilized to generate 3-D plots, which were used to examine etch mechanisms under various plasma conditions. Depending on the plasma conditions, parameter effects on MD were quite different. For most of the parameter variations, MD variations were strongly related to profile angle variations. The effect of bias power on MD seems to be dominated by polymer deposition due to the variations in C2F6 flow rates maintained in the chamber.

AB - Silicon oxynitride films were etched in a C2F6 inductively coupled plasma. A prediction model of microtrenching depth (MD) was constructed by using a neural network and a genetic algorithm. For a systematic modeling, etching data were collected by using a statistical experimental design. The process parameters and ranges were 400-1000 W, 30-90 W, 6-12 mTorr, and 30-60 sccm for source power, bias power, pressure, and C2F6 flow rate, respectively. The root mean-squared prediction error of the constructed model was about 0.019. The model was utilized to generate 3-D plots, which were used to examine etch mechanisms under various plasma conditions. Depending on the plasma conditions, parameter effects on MD were quite different. For most of the parameter variations, MD variations were strongly related to profile angle variations. The effect of bias power on MD seems to be dominated by polymer deposition due to the variations in C2F6 flow rates maintained in the chamber.

KW - Computer modeling and simulation

KW - Neural networks

KW - Plasma etching

UR - https://www.scopus.com/pages/publications/33847328296

U2 - 10.1016/j.cap.2006.09.018

DO - 10.1016/j.cap.2006.09.018

M3 - Article

AN - SCOPUS:33847328296

SN - 1567-1739

VL - 7

SP - 434

EP - 439

JO - Current Applied Physics

JF - Current Applied Physics

IS - 4

ER -

Prediction of surface microtrenching by using neural network

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