Semi-empirical model of light scattering from submicron pyramidal pits

Michael Jordan Jr.; Rodolfo E. Diaz; E. Dan Hirleman

doi:10.1117/1.1431252

1 February 2002 Semi-empirical model of light scattering from submicron pyramidal pits

Michael Jordan Jr., Rodolfo E. Diaz, E. Dan Hirleman

Optical Engineering, Vol. 41, Issue 2, (February 2002). https://doi.org/10.1117/1.1431252

Silicon wafers that are fabricated by the Czochralski technique contain pyramidal pits, which are referred to in more general terms as crystal-originated particles (COPs). Because wafer inspection systems now benefit from the predictability of scattering from particles of known size, shape, and composition, it is of interest to achieve the same level of predictability for surface breaking defects such as pits. A model, valid for s-polarization and a high incidence angle, is based on the Fraunhoffer approximation for the diffraction from a square aperture, and is enhanced by an empirically derived term that accounts for the scatter component attributed to facets. Measurements and the model show that (using the prescribed optics configuration) a characteristic peak occurs between 20 and 45 deg in the forward scatter region, which increases in magnitude and moves forward with increasing pit size. This kind of information can be used to improve an instrument's ability to distinguish between surface particles and COPs by strategically positioning detectors accordingly. Furthermore, the model can be used as a check against numerical models that are designed to predict scatter from pyramidal pits that are of size equal to a wavelength or much smaller.

©(2002) Society of Photo-Optical Instrumentation Engineers (SPIE)

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Michael Jordan Jr., Rodolfo E. Diaz, and E. Dan Hirleman "Semi-empirical model of light scattering from submicron pyramidal pits," Optical Engineering 41(2), (1 February 2002). https://doi.org/10.1117/1.1431252

Published: 1 February 2002

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