In ionized physical vapor deposition, used in Cu interconnect technology, t
he interaction of energetic ions with the growing Cu film is sensitive to b
oth the impact angle and the energy. Detailed information, such as the angl
e and energy dependence of the sputter yield and sticking probability, is r
equired for realistic feature scale modeling of film coverage in the metall
ization of micron-sized features (vias and trenches) in integrated circuits
. Here we describe the results of molecular dynamics (MD) simulations of sp
uttering of Cu (111) surfaces by Cu and Ar ions suitable for incorporation
into feature scale simulations. For each impact angle and energy considered
(10-100 eV for Cu ions and 50-250 eV for Ar ions), the following averaged
properties were calculated: sputter yield (number of Cu atoms sputtered per
impact), sticking probability, thermal accommodation coefficient, average
reflection angle of the impact ion, and average emission angle of the sputt
er products. The calculated sputter yields and energy threshold at normal i
ncidence for both Ar and Cu sputtering of Cu are in good agreement with exp
eriment and other MD simulations. Detailed comparisons are also made with p
reviously reported sputter yields calculated with binary collision theory.
(C) 1999 American Vacuum Society. [S0734-2101(99)07705-2].