The possibility of identifying the chemical nature of atomic adsorbates (C,
N, O, F and S) on metal surfaces has been explored both theoretically and
experimentally. It is shown that, although the tip and the surface may mark
edly influence the appearance of adatoms in STM images, atomic size and ele
ctronegativity are the dominant factors that determine the contrast. In thi
s work, low-temperature (<40 K) STM is used to suppress adatom diffusion on
the Pd(lll) surface and to image isolated adsorbates at low coverages. It
is found experimentally that isolated carbon and sulfur atoms on the Pd(ll)
surface scanned by a platinum tip appear as bumps with a height of about 0
.3-0.4 Angstrom and 0.8 Angstrom, respectively, whereas oxygen atoms are ch
aracterized by a depression with a negative corrugation of -0.35 Angstrom.
To simulate STM images of adatoms on metal surfaces, we have applied Green'
s function formalism to solve the Schrodinger equation in the tight binding
approximation. It is shown that highly electronegative atoms such as O and
F always appear as depressions. As the electronegativity decreases (from F
to C), the depression transforms into a shallow dimple with a slight bump
in the middle in the case of N, and into a well-pronounced bump for C. Thir
d-row adsorbates (Na through Cl) are also calculated to produce bumps, with
a corrugation that does not correlate simply with the adatom-surface spaci
ng. The shape and size of the image corrugations predicted theoretically ar
e in good agreement with the experimental data. (C) 1998 Published by Elsev
ier Science B.V. All rights reserved.