CL-2 PLASMA-ETCHING OF SI(100) - NATURE OF THE CHLORINATED SURFACE-LAYER STUDIED BY ANGLE-RESOLVED X-RAY PHOTOELECTRON-SPECTROSCOPY

The interaction of a Cl-2 plasma with a Si(100) surface has been inves tigated by angle resolved x-ray photoelectron spectroscopy (XPS). It w as found that the amount of chlorine incorporated into the near-surfac e region of Si increases with ion energy, and does not change with lon g exposure to the plasma. Chlorine is present as SiClx (x=1-3) with av erage relative coverages (integrated over depth) of [SiCl]:[SiCl2]:[Si Cl3]congruent to 1:0.33:0.13 at -240 V dc bias (mean ion energy approx imate to 280 eV) and 1:0.34:0.087 at 0 V de bias (mean ion energy appr oximate to 40 eV), at x-ray photoelectron spectroscopy (XPS) binding e nergies of 100.2, 101.2 and 102.3 eV, respectively. Moreover, there is a substantial amount of disordered Si within the chlorinated layer at high ion energy, reflected in a broadening of the 99.4 eV Si peak and the appearance of a shoulder at 98.8 eV, ascribed to Si with a dangli ng bond. In addition, bulk Si plasmon losses associated witt 1 the Cl( 2p) and Cl(2s) con levels indicate that roughly one-third of the CI in the near-surface region is surrounded by bulklike Si at the high ion energy. Modeling of the dependence of the relative concentration of Cl on the take-off angle was used to estimate the Cl content and thickne ss of the surface layer. From an inversion of the observed take-off an gle dependence of the relative Cl and Si XPS signals, depth profiles w ere derived for the near-surface region. Cl content falls off in a gra ded fashion, over a depth of about 25 and 13 Angstrom for a mean ion e nergies of 280 and 40 eV, respectively. The Cl areal density (coverage integrated throughout the layer) increases with increasing mean ion e nergy from 1.8x10(15) Cl/cm(2) at 40 eV to 3.5 x 10(15) Cl/cm(2) at 28 0 eV. From a similar inversion of the take-off angle dependence of the SiClx signals, SiCl2 and SiCl3 are found to be largely confined at th e top similar to 5 Angstrom, while below the surface, disordered Si an d SiCl are present. (C) 1997 American Institute of Physics.