论文信息 - Neural network modeling of reactive ion etching using principal component analysis of optical emission spectroscopy data

Neural network modeling of reactive ion etching using principal component analysis of optical emission spectroscopy data

In this paper, neural networks trained by the error back-propagation algorithm are used to build models of etch rate, uniformity, selectivity and anisotropy as a function of optical emission spectroscopy (OES) data in a reactive ion etching process. The material etched is benzocyclobutene (BCB), a low-k dielectric polymer, which is etched in an SF/sub 6/ and O/sub 2/ plasma in a parallel plate system. Neural network training data are obtained from a multi-way principal component analysis (MPCA) of the OES data. These data are acquired from a 2/sup 4/ factorial experiment designed to characterize etch process variation with controllable input factors consisting of the two gas flows, RF power and chamber pressure. Evaluation of the trained neural networks is performed in terms of root mean square (RMS) error, and less than 3% prediction errors are achieved.

Gary S. May | Sang Jeen Hong | G. May | S.J. Hong

[1] Duane S. Boning,et al. Spatial characterization of wafer state using principal component analysis of optical emission spectra in plasma etch , 1997 .

[2] Gary S. May,et al. Reactive ion etch modeling using neural networks and simulated annealing , 1996 .

[3] Gary S. May,et al. Advantages of plasma etch modeling using neural networks over statistical techniques , 1993 .

[4] J. E. Jackson. A User's Guide to Principal Components , 1991 .

[5] J. Macgregor,et al. Monitoring batch processes using multiway principal component analysis , 1994 .

[6] Costas J. Spanos,et al. Statistical Experimental Design in Plasma Etch , 1991 .

[7] James P. Roland,et al. Endpoint detection in plasma etching , 1985 .

[8] Michael J. Berry,et al. Soft Mask for Via Patterning in Benzocyclobutene , 1993 .