The ionized metal physical vapour deposition (IMPVD) process is being devel
oped to produce metal seed layers and diffusion barriers in deep contacts a
nd vias for microelectronics fabrication. An IMPVD reactor is typically an
antenna excited system where transmission line effects may produce asymmetr
ic ion fluxes to the target and hence an asymmetric distribution of sputter
ed metal species in the reactor. A possible result is a non-uniform metal d
eposition on the wafer. In this paper, a three-dimensional model for an IMP
VD reactor is employed to examine the consequences of asymmetric excitation
and irregular sputter tracks on species' densities and fluxes. It was foun
d that for typical conditions for Al IMPVD severe asymmetries in electron t
emperature and electron density profiles produced by a poorly optimized ant
enna are not reflected in the metal fluxes to the substrate. The metal spec
ies have improved symmetry due to charge exchange of the buffer gas ions to
the metal and the higher mobility of the metal ions relative to the buffer
gas ions. The symmetry and uniformity of the metal species above the wafer
significantly improve when increasing the aspect ratio of the plasma regio
n or increasing the pressure due to there being more diffusional transport.
However, this improvement is accompanied by a decrease in the magnitude of
metal fluxes to the wafer. Irregular sputter tracks combined with rotation
of the target were also investigated.