| Paper | Title | Page |
|---|
| MO202 | Status of the Cornell ERL injector cryomodule | 9 |
| | - M. Liepe, S. Belomestnykh, E. Chojnacki, V. Medjidzade, H. Padamsee, P. Quigley, J. Sears, V. Shemelin, V. Veshcherevich
CLASSE, Cornell University
| |
| | Cornell University is developing and fabricating a SRF
injector cryomodule for the acceleration of the high current
(100 mA) beam in the Cornell ERL prototype and ERL
light source. Major challenges include emittance preservation
of the low energy, ultra low emittance beam, cw cavity
operation, and strong HOM damping with efficient HOM
power extraction. Axial symmetry of HOM absorbers, together
with two symmetrically placed input couplers per
cavity, avoid transverse on-axis fields, which would cause
emittance growth. Fabrication of five 2-cell niobium cavities
and coaxial blade tuners, ten twin high power input
couplers, and six beam line HOM absorbers has finished.
The injector cryomodule is presently under assembly at
Cornell University with beam test planned for early 2008.
In this paper we report on the cryomodule fabrication and
assembly status. | |
 | Slides(PDF) | |
| TUP24 | Studies of the high field anomalous losses in small and large grain niobium cavities | 173 |
| | - A. Romanenko, G. Eremeev, D. Meidlinger, H. Padamsee
CLASSE, Cornell University
| |
| | High field Q-slope in niobium cavities of all grain sizes
remains to be an unexplained phenomenon. Thermometry
studies performed in recent years revealed that distribution
of losses in the high field Q-slope regime is not uniform,
but exhibit a patchy character with some regions being hotter
than other. Results of surface analysis of samples dissected
from "hot" and "cold" regions of small and large
BCP cavities are reported in this contribution. | |
| TUP27 | Systematic Trends for the Medium Field Q-Slope | 178 |
| | - J. Vines, Y. Xie, H. Padamsee
Cornell University
| |
| | The medium field Q-slope for Nb cavities has been studied
in the past as a thermal feedback effect combined
with the nonlinear BCS surface resistance due to currentinduced
RF pair-breaking. We are systematically exploring
the behavior of the medium field Q-slope with various
cavity parameters such as wall thickness, residual resistance,
bath temperature, Kapitza conductance, RF frequency,
RRR, and phonon mean free path. We study cases
involving only the standard (linear) BCS resistance as well
as those including the nonlinear BCS resistance. The systematic
comparison suggests specific experiments to determine
the role of the nonlinear contribution. | |
| WE101 | Temperature Map Studies on Nearly Oxide-Free, Thin-Oxide and Standard-Oxide Cavities | 356 |
| | - G. Eremeev, H. Padamsee
CLASSE, Cornell University
| |
| | A few nanometers of niobium oxide cover niobium in
niobium cavities, prepared by standard treatments. Since
the RF penetration depth is a few tens of nanometers, the
niobium oxide and the metal-oxide interface may play role
in RF losses of superconducting niobium. In order to understand
the cause of phenomena such as the high field Qslope,
medium field Q-slope, and residual resistance, it is
important to distinguish the contributions of the niobium
oxide and its interface to losses at medium and high fields.
XPS and Auger studies have shown that it is possible to reduce
significantly the thickness of the oxide layer by heating
to 3000C - 4000C for a few hours in vacuum. Leaving
the surface in the vacuum does not re-grow the oxide layer.
Applying such treatment to a cavity one can reduce the niobium
oxide and measure the superconducting RF properties
of a nearly oxide-free cavity. Then via controllable air exposure
one can re-grow oxide and investigate the change in
properties as a function of exposure. We performed these
experiments and report results of nearly oxide-free, thinoxide
and standard-oxide cavities. | |
| Slides(PDF) | |
| WE202 | Different sputtering configurations for coating 1.5 GHZ copper cavities | 384 |
| | - G. Lanza, V. Palmieri, N. Patron, C. Pira, S. Stark
Laboratori Nazionali di Legnaro, STITUTO NAZIONALE DI FISICA NUCLEARE - E. Bemporad, F. Carassiti, M. Sebastiani
University of Rome - H. Padamsee
Cornell University
| |
| | In the framework of the attempts to densify the
sputtering discharge, two different sputtering
configuration are reported:
- a mixed bias magnetron sputtering technique has been
explored for depositing niobium into 1,5 GHz copper
cavities. Results are presented and compared with the
standard CERN technique. The superconducting and high
resolution morphological and mechanical properties of
niobium films sputtered onto the inner walls of
electropolished cavities, have been studied as a function
of the deposition technique. Even if niobium films coated
with the bias technique show a higher density and Tc
similar to the other films, they don't present higher RRR
values. Preliminary RF tests are presented.
- post Magnetron sputtering in thermoelectric emission
regime have been investigated and is under improvement
in order to increase the RRR values of sputtered Nb:
superconducting and structural properties of the obtained
films have been measured to check the technique
capability and its possible application for coating cavities. | |
| Slides(PDF) | |
| WEP33 | Realisation of a prototype superconducting CW cavity and cryomodule for energy recovery | 545 |
| | - P. A. McIntosh, R. Bate, C. D. Beard, M. Cordwell, D. M. Dykes, S. Pattalwar, J. Strachan, E. Wooldridge
STFC Daresbury Laboratory - S. Belomestnykh, M. Liepe, H. Padamsee
Cornell University - A. Buechner, F. Gabriel, P. Michel
FZR Rossendorf - T. Kimura, T. I. Smith
Stanford University - J. Byrd, J. N. Corlett, D. Li, S. Lidia
LBNL
| |
| | For Energy Recovery applications, the requirement for
high-Q accelerating structures, operating in CW mode, at
large beam currents, with precise phase & amplitude
stability and modest accelerating gradients are all
fundamental in achieving intense photon fluxes from the
synchronised FEL insertion devices. Both Daresbury
Laboratory and Cornell University are developing designs
for advanced Energy Recovery Linac (ERL) facilities
which require accelerating Linacs which meet such
demanding criteria. The specification for the main ERL
accelerator for both facilities dictates a modest
accelerating gradient of 20 MV/m, at a Qo of better than
10^10, with a Qext of up to 10^8. A collaborative R&D
program has been set-up to design and fabricate a 'proof-of-
principle' cryomodule (which is well underway) that
can be tested on ERLP at Daresbury and also on the
Cornell ERL injector. This paper details the new
cryomodule design, provides an insight to the design
solutions employed and reports on the present status of
the project. | |
| WEP39 | Status of ILC cavity processing and testing at Cornell | 567 |
| | - W. J. Ashmanskas
Fermilab - H. Padamsee
Cornell University
| |
| | As part of the coordinated U.S. effort to build up SRF infrastructure
for the ILC, the Cornell SRF lab has developed
tools and procedures for 9-cell 1.3 GHz cavity processing
and vertical testing. Steps performed with 9-cell cavities
at Cornell include tuning for field flatness, vertical electropolishing
(or BCP if desired), high-pressure rinsing in
ultra-pure water, baking at 110C, and RF testing at 2K in a
vertical cryostat. Since spring 2006, Cornell has performed
ILC cavity processing/testing cycles at a rate of about one
per month. We summarize methods, results, and possible
next steps. | |