Alban sublet niobium coated hie-isolde qwr superconducting accelerating cavities coating process...
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Nb-coated HIE-ISOLDE QWR SC Accelerating Cavities:
coating process and film characterization
A. Sublet1, N. Jecklin1, S. Calatroni1, G. Rosaz1, W. Venturini Delsolaro2, M. Therasse2, P. Zhang2,
L. Dufay-Chanat 3, S. Prunet 3, B. Bártová4, A.B. Aebersold5, D. T. L. Alexander5, M. Cantoni5
1 CERN/TE/VSC2 CERN/BE/RF3 CERN/TE/CRG4 CERN/EN/MME5 EPFL, Interdisciplinary Centre for Electron Microscopy (CIME)
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Outline
• QWR coating process• HIE-ISOLDE upgrade
• Production workflow
• Coating process
• Cavities performances
• Nb layer characterization• Thickness
• RRR
• FIB-SEM surface morphology
• FIB-SEM cross section imaging
• TEM composition and orientation mappings
09.10.2014 Thin Film Workshop 2014 3
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Outline
• QWR coating process• HIE-ISOLDE upgrade
• Production workflow
• Coating process
• Cavities performances
• Nb layer characterization• Thickness
• RRR
• FIB-SEM surface morphology
• FIB-SEM cross section imaging
• TEM composition and orientation mappings
09.10.2014 Thin Film Workshop 2014 4
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HIE-ISOLDE upgrade project
09.10.2014 Thin Film Workshop 2014 5
Boost the radioactive beam energy from 3MeV/u to 10MeV/u by using SC linac.
Quarter-wave resonator (QWR):
Nb thin film sputtered
on 3D forged OFE Cu substrate
Hig
h E
nerg
y a
nd I
nte
nsity –
Isoto
pe
Separa
tor
On L
ine D
Ete
cto
r
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09.10.2014 Thin Film Workshop 2014 6
Frequency 101.28 MHz
Eacc 6 MV/m
βoptimum 10.9%
R/Q 553 Ω
Epeak/Eacc 5.0
Bpeak/Eacc 95.6 G/(MV/m)
G=RsQ 30.7 Ω
U/Eacc2 0.207 J/(MV/m)2
Pc at 6MV/m 10W
|E| field|H| field
Courtesy M. Fraser
High-β QWR
Total of 20 cavities to be produced
5 cavities ready for assembly in first cryomodule by the end of 2014
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Thin Film Workshop 2014 7
Cavity reception
Frequency tuning
Surface treatment
Niobium coating
RF cold test
Niobium
Stripping
n+1 cycle
Production workflow
Cavity storage
09.10.2014
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09.10.2014 Thin Film Workshop 2014 8
Coating hardware
2 coating benches functional at CERN:
• Nb cylindrical cathode at -1000V
• Grids grounded for plasma polarization
• Adjustable cavity bias:ions densify & smooth the Nb layer
• Cavity bakeout to 650°C with IR lamp prior to coating
• Coating with hot substrate (300-620°C)
• Thermocouples along cavity to monitor temperature during bakeout and coating
• Pressure control and RGA monitoring
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09.10.2014 Thin Film Workshop 2014 9
Coating process Baseline recipe
DC-bias diode:
Pressure: 0.2mbar
Sputtering gas: Ar
Nb-cathode power: 8kW
Cavity bias: -80V
Temperature:
Inner: from 315°C to 620°C
Outer: from 300°C to 430°C
14 runs: 25’ coating + 5h35’
cool down to 300°C each,
total coating time = 6h
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09.10.2014 Thin Film Workshop 2014 10
Cavities performances
1.E+8
1.E+9
1.E+10
0 1 2 3 4 5 6 7
Q0
Eacc (MV/m)
QP1.4 (07.2013)
QP2.1 (05.2014)
QP3.2 (07.2014)
QS1.1 (07.2014)
QS2.1 (08.2014)
7W line
10W line
HIE-ISOLDE Spec
Eacc=6MV/mHIE-ISOLDE
specifications
QP1.4test Prototype
QP2.1Prototype 2
QP3.2Prototype 3
QS1.1pre-Serie
QS2.1pre-Serie
Q0 4.7E+08 6.51E+08 6.23E+08 4.37E+08 3.61E+08 2.80E+08
Pcav(W) 10 7.5 7.6 10.8 12.5 17.0
for cryomodule, avg = 12 W
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Outline
• QWR coating process• HIE-ISOLDE upgrade
• Production workflow
• Coating process
• Cavities performances
• Nb layer characterization• Thickness
• RRR
• FIB-SEM surface morphology
• FIB-SEM cross section imaging
• TEM composition and orientation mappings
09.10.2014 Thin Film Workshop 2014 11
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Test cavity Q4
09.10.2014 Thin Film Workshop 2014 12
Baseline coated cavity
cavity top zoom with samples
welding
e9
i9
outer conductor
inner conductor
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Film thickness (XRF) and |H| profile
09.10.2014 Thin Film Workshop 2014 13
inner grid
outer grid
Nb cathode
innerconductor
outer conductor
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Film thickness (XRF) and RRR profile
09.10.2014 Thin Film Workshop 2014 14
inner grid
outer grid
Nb cathode
innerconductor
outer conductor
average RRR = 35
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FIB-SEM surface morphology (SESI)
09.10.2014 Thin Film Workshop 2014 15
inner grid
outer grid
Nb cathode
innerconductor
outer conductor
e9e7
i7
Outer conductor:
very fine plate-like structure
grain size ~ few 100nm
Inner conductor:
flat grains
apparent grain boundaries
grain size ~ few mm
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1.85 kV, InLens i4 1.85 kV, InLens i7
FIB-SEM cross section imaging
09.10.2014 Thin Film Workshop 2014 16
inner grid
outer grid
Nb cathode
innerconductor
outer conductor
1.5 kV, EsB e91.85 kV, EsB e2
1.5 kV, EsB i9
1.85 kV, EsB e7
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e9 FIB tomography
09.10.2014 Thin Film Workshop 2014 17
Unexpected presence of pores lead us to FIB tomography in order to visualize distribution of the pores and
quantify their volume. Accelerating voltage during acquisition was set to 1.85 kV. 3D ATLAS software was
used during the 16 hours experiment and 788 images was acquired.
4170x576x301 (7.8nm slices) SESI detector 1.85 kV, M. Cantoni and B. Bartova
Pore reconstruction in a section (500x500x301) of Nb coating
About 1% pore
volume fraction
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e9 TEM imaging and EDS analysis
09.10.2014 Thin Film Workshop 2014 18
• HAADF STEM image with corresponding mapping of the Nb Coating.
• Oxygen layer at the top as well as around pores was revealed.
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e9 EDS at Cu/Nb interface
09.10.2014 Thin Film Workshop 2014 19
• Detailed mapping at the interface revealed presence of max 20 nm sized Cu precipitates.
• The precipitates are randomly scattered along the Cu/Nb interface and were found up to 200 nm far
from the interface.
• Oxygen enrichment at the interface and around the porosity is detected.
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Line scan along the interface
09.10.2014 Thin Film Workshop 2014 20
• Line scan shows the O enrichment at the interface and around the precipitate.
• Presence of Cu precipitate is confirmed
Cu
NbO
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Precipitate EDS spectra
09.10.2014 Thin Film Workshop 2014 21
• The spectra was taken from the area marked with the red circle, the composition
corresponds to Nb70Cu28Al2 in at.%. The peak of Al comes from TEM holder.
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e9 Orientation mapping
09.10.2014 Thin Film Workshop 2014 22
• Technique based on collection of precession electron diffraction patterns and cross-correlation with the
simulated template.
• Grains in the coating show no preferential orientation
• The very small grains close to the interface cannot be index because of grain overlap.
• For the grain size characterization plain view sample at well defined height of the coating is needed.
• XRD data measurement are needed for comparison of results.
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Summary
• Workflow and reproducible coating baseline recipe are operational to
achieve production of 1 cavity/month
• Production cavities RF performances good on average, need two more
cavities in specification by the end of the year for the first cryomodule
• Nb layer of 2-10mm from outer to inner conductor with average RRR = 35
• Grain size ranging from 200nm on outer conductor up to few mm on inner
conductor
• Around 1% vol. porosities at e9 position beside the weld, only very few nm-
size elsewhere
• Presence of O-enrichment close to the interface and porosity
• Cu precipitates identified by TEM EDS measurements close to the interface
09.10.2014 Thin Film Workshop 2014 23
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Conclusions
• Further TEM investigation of top part of the Nb-layer will follow
• TEM analysis of thick layer to investigate the nature of observed layers
• In parallel PCT measurements
• and mu-SR measurements are on the way on same samples
This systematic characterization of the film efficiently highlight the regions to
be improved and help to target the hardware/process parameters to adjust
(bias voltage to densify the film, cathode geometry, etc.)
Combined together these material science and SC/RF approaches will help
to tune the key parameters to achieve the best performances of Nb-coated
SRF cavities
09.10.2014 Thin Film Workshop 2014 24
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09.10.2014 Thin Film Workshop 2014 25
Thank you for your attention
Acknowledgements:
Barbora Bártová, CERN/EN/MME
Brian Aebersold, Duncan Alexander and Marco Cantoni, EPFL/CIME