Surface Nb oxide
variation with surface treatment
On exposure to air niobium forms a native pentoxide
layer on its surface. This material is itself a benign dielectric. Just
what happens in the bulk-to-pentoxide interface is of considerable interest
because it bears on the ultimate SRF performance that may be attained.
Suboxides of niobium, which may well be present in this transition, are
normal conducting at temperatures of interest. The crystalline texture
of the niobium at the interface may facilitate magnetic flux penetration
at less than the theoretically anticipated critical field strength.
JLab in collaboration with the College of William and
Mary, Boston University,
and others, is examining the influence of flow conditions and thermal
processing steps on the resultant nature of the surface roughness and
oxides.
- In the standard etching
process for SRF niobium cavities (BCP), solution flows in one end
and out the other. The maximum flow rate occurs at the cavity irises.
We subjected batches of identical samples to BCP with different flow
rates, then measured surface roughness by stylus profilometry and
surface composition by the XPS. A surprising correlation was found.
Its implications have yet to be sorted out.
- We also chemically polished
polycrystalline and single crystal Nb coupons, then measured surface
roughness by stylus profilometry and surface composition by the variable
photon energy XPS, which was carried out at beamline X1B at the National
Synchrotron Light Source (NSLS). Such measurements are aimed at discerning
depth profile information via the increase of electron escape depth
with energy. This would avoid surface topology complications to occur
when interpreting angle-resolved XPS of representative niobium surfaces.
This work was largely the effort of
a PhD student, now Doctor, from the
College of William and
Mary, Hui Tian.