Presentation is loading. Please wait.

Presentation is loading. Please wait.

Laser heating and laser scanning microscopy of SRF cavities

Published byBryan Flowers Modified over 6 years ago

Similar presentations

Presentation on theme: "Laser heating and laser scanning microscopy of SRF cavities"— Presentation transcript:

1 Laser heating and laser scanning microscopy of SRF cavities
G. Ciovati 7th SRF Materials Workshop, July 16th 2012 Jefferson Lab

2 Acknowledgements Design and fabrication of the laser scanning microscope: C. Baldwin, G. Cheng, R. Flood, K. Jordan, P. Kneisel, M. Morrone, G. Nemes, L. Turlington, H. Wang, K. Wilson, and S. Zhang (JLab) G. Nemes (ASTiGMAT) Discussions on LSM experiments and data analysis: Steven M. Anlage (Univ. of Maryland) Discussions on hotspot laser heating: A. Gurevich (Old Dominion Univ.) Funding: American Recovery and Reinvestment Act (ARRA) through the US Department of Energy, Office of High Energy Physics, Contract No. DE-PS02- 09ER09-05

3 Hotspots in SRF cavities
Temperature mapping reveals that the surface resistance of SRF cavities is: spatially non-uniform the field dependence is non-linear Hotspots

4 Low Temperature Laser Scanning Microscopy
Nondestructive spatially resolved characterization (optical, structural and electronic properties) of HTS materials Point-by-point raster scanning of the surface of a sample-under-test with a focused laser beam Local heating of the SC  perturbation of its electronic system and changes in intensity and polarization of the reflected beam Photoresponse PR(x,y)  local LSM contrast voltage dV(x,y) A. P. Zhuravel et al., Low Temp. Phys. 32, 592 (2006)

5 LTLSM setup for SRF cavity
Thermometry system Mirrors’ chamber Optics 71 Dimension are in cm G. Ciovati et al., Rev. Sci. Inst. 83, (2012)

6 SRF cavity for LSM Built from ingot Niobium TESLA half-cell shape
TM010 mode: 1.3 GHz TE011 mode: 3.3 GHz 18 cm 21 cm H-field in TE011 mode G = Q0Rs = 501 W Bp/√U = 76 mT/√J

7 Measurement setup Assuming Rs(Tf)>>Rs(2K) and Hrf T-independent
dVrms: voltage measured with lock-in amp V0: voltage from crystal diode with laser off Pc0: power dissipated in the cavity with laser off rL: laser beam radius QL: cavity loaded Q Qext: external Q of input and pick-up RF antenna fM: laser modulation frequency

8 Results: hotspot vs. coldspot
Temperature map of the cavity plate at Bp = 13 mT, Tb = 2.0 K Pabs = 0.92 W, fM = 10 Hz, rL = mm for both scans. Tin ~ 8.5 K

9 Results: hotspots Temperature map of the cavity plate at Bp = 13 mT, Tb = 2.0 K Pabs = 50 mW, fM = 1 Hz, rL = mm for both scans. Tin ~ 4 K, RBCS  3.3 mW

10 Comparison with HTS setup
Thermal diffusion length Thermal response time C: specific heat per unit volume k: thermal conductivity d: wall thickness hK: Kapitza conductance if fMt >> 1 Spatial resolution = SRF Cavity: Nb, 2.0 K HTS, 4.2 K dT ~ 2.2 mm t ~ 0.4 ms, up to ~ 30 ms for Tout > 2.17 K Sample size: tens of cm Size of apparatus: few meters dT ~ 1-10 mm t ~ ms Sample size: few mm Size of apparatus: tens of cm

11 Eliminating vortex hotspots by thermal gradients
Thermal force acting on the vortex: The condition fT > JcF0 gives the critical gradient which can depin vortices: Taking Bc1 = 0.17T, Jc = 1kA/cm2 and T = 2 K for clean Nb yields |T|c  1.7 K/mm Vortices in Nb may be moved by moderate thermal gradients Any change of thermal maps after applying local heaters indicate that some of the hot-spots are due to pinned vortices A. Gurevich, talk TU104 at SRF’07 Workshop

12 Laser hotspot annealing
Dissipation due to vortices // surface can be reduced by pushing them into the bulk ANSYS thermal analysis of Nb plate with a gaussian laser beam 0.87 mm diameter, Pabs ~ 0.92 W yields T ~ 8 K/mm

13 Experimental procedure and results
At 2.0 K: Baseline cavity RF test: locate RF hotspots by thermometry RF off, scan laser at hotspot locations (tried different scanning profiles: raster, spiral) Repeat cavity RF test: locate RF hotspots by thermometry Top view T-map before laser heating, 82 mT Ring 2 Ring 3 T-map after laser heating, 82 mT

14 DT before and after laser heating
DT(Bp=82mT, Tb=2.0K) along rings 2 & 3 before and after laser heating Ring 2 Ring 3 Top view GB GB 15° 345° 11° 349° G. Ciovati et al., to be published

15 Conclusions A setup to perform LTLSM of an SRF cavity has been designed and built at Jefferson Lab to study “hotspots” 3D maps of surface resistance with ~ 1 mW resolution at 3.3 GHz Hotspots can be identified with ~ 2 mm spatial resolution (~ 1 order of magnitude better than thermometry) The same setup was used to attempt laser “hotspot annealing” Pinned vortices are a source of hotspots Cannot be easily “eliminated”  improve magnetic shielding of cavities in cryomodule, reduce thermal gradients of cavities in cryomodules during cool-down below Tc

Download ppt "Laser heating and laser scanning microscopy of SRF cavities"

Similar presentations

The Continuing Role of SRF for AARD: Issues, Challenges and Benefits SRF performance has been rising every decade SRF installations for HEP (and other.

The Continuing Role of SRF for AARD: Issues, Challenges and Benefits SRF performance has been rising every decade SRF installations for HEP (and other.
Superconducting Materials R&D: RRCAT-JLAB Collaboration S B Roy Materials & Advanced Accelerator Science Division RRCAT, Indore Collaborators: M. K. Chattopadhyay,

Superconducting Materials R&D: RRCAT-JLAB Collaboration S B Roy Materials & Advanced Accelerator Science Division RRCAT, Indore Collaborators: M. K. Chattopadhyay,
VTSLM images taken again at (a) 4.5  (T=84.7K), (b) 3.85  (T=85.3K), (c) 22.3  (T=85.9K), and (d) 31.6  (T=86.5K) using F-H for current and A-C for.

VTSLM images taken again at (a) 4.5  (T=84.7K), (b) 3.85  (T=85.3K), (c) 22.3  (T=85.9K), and (d) 31.6  (T=86.5K) using F-H for current and A-C for.
Thin Films for Superconducting Cavities HZB. Outline Introduction to Superconducting Cavities The Quadrupole Resonator Commissioning Outlook 2.

Thin Films for Superconducting Cavities HZB. Outline Introduction to Superconducting Cavities The Quadrupole Resonator Commissioning Outlook 2.
Progress of SRF and ERL at Peking University Lu Xiangyang Institute of Heavy Ion Physics Peking University.

Progress of SRF and ERL at Peking University Lu Xiangyang Institute of Heavy Ion Physics Peking University.
7.8GHz Dielectric Loaded High Power Generation And Extraction F. Gao, M. E. Conde, W. Gai, C. Jing, R. Konecny, W. Liu, J. G. Power, T. Wong and Z. Yusof.

7.8GHz Dielectric Loaded High Power Generation And Extraction F. Gao, M. E. Conde, W. Gai, C. Jing, R. Konecny, W. Liu, J. G. Power, T. Wong and Z. Yusof.
1 Basics of Microwave Measurements Steven Anlage

1 Basics of Microwave Measurements Steven Anlage
Rong-Li Geng Jefferson Lab High Efficiency High Gradient Cavities - Toward Cutting Down ILC Dynamic Heat Load by Factor of Four R.L. Geng, ALCW2015, 20-24.

Rong-Li Geng Jefferson Lab High Efficiency High Gradient Cavities - Toward Cutting Down ILC Dynamic Heat Load by Factor of Four R.L. Geng, ALCW2015,
201 MHz NC RF Cavity R&D for Muon Cooling Channels

201 MHz NC RF Cavity R&D for Muon Cooling Channels
Bias Magnet for the Booster’s 2-nd Harmonic Cavity An attempt to evaluate the scope of work based of the existing RF design of the cavity 9/10/2015I. T.

Bias Magnet for the Booster’s 2-nd Harmonic Cavity An attempt to evaluate the scope of work based of the existing RF design of the cavity 9/10/2015I. T.
1 Imaging of Microwave Currents and Microscopic Sources of Nonlinearities in Superconducting Resonators Alexander P. Zhuravel*, Steven M. Anlage, and Alexey.

1 Imaging of Microwave Currents and Microscopic Sources of Nonlinearities in Superconducting Resonators Alexander P. Zhuravel*, Steven M. Anlage, and Alexey.
Materials Testing With a High-Q RF Cavity Sami Tantawi, Christopher Nantista, Valery Dolgashev, Gordon Bowden, Ricky Campisi, T. Tajima, and P. Kneisel.

Materials Testing With a High-Q RF Cavity Sami Tantawi, Christopher Nantista, Valery Dolgashev, Gordon Bowden, Ricky Campisi, T. Tajima, and P. Kneisel.
Photocathode 1.5 (1, 3.5) cell superconducting RF gun with electric and magnetic RF focusing Transversal normalized rms emittance (no thermal emittance)

Photocathode 1.5 (1, 3.5) cell superconducting RF gun with electric and magnetic RF focusing Transversal normalized rms emittance (no thermal emittance)
High Current Electron Source for Cooling Jefferson Lab Internal MEIC Accelerator Design Review January 17, 2014 Riad Suleiman.

High Current Electron Source for Cooling Jefferson Lab Internal MEIC Accelerator Design Review January 17, 2014 Riad Suleiman.
Cornell SRF New Materials Program Nb 3 Sn Development Sam Posen and Matthias Liepe Cornell University TTC Meeting 6 December 2011 Beijing, China.

Cornell SRF New Materials Program Nb 3 Sn Development Sam Posen and Matthias Liepe Cornell University TTC Meeting 6 December 2011 Beijing, China.
Clustered Surface RF Production Scheme Chris Adolphsen Chris Nantista SLAC.

Clustered Surface RF Production Scheme Chris Adolphsen Chris Nantista SLAC.
Flat-Top Beam Profile Cavity Prototype

Flat-Top Beam Profile Cavity Prototype
High Q R&D at JLab G. Ciovati, P. Dhakal, R. Geng, P. Kneisel, G. Myneni TTC Topical Meeting on CW SRF Cornell Univ., June 12 th -14 th, 2013.

High Q R&D at JLab G. Ciovati, P. Dhakal, R. Geng, P. Kneisel, G. Myneni TTC Topical Meeting on CW SRF Cornell Univ., June 12 th -14 th, 2013.
Francesco Cottone INFN & Physics Departments of Perugia, Pisa, Florence (Collaboration Work under VIRGO Project) Thermomechanical properties of silicon.

Francesco Cottone INFN & Physics Departments of Perugia, Pisa, Florence (Collaboration Work under VIRGO Project) Thermomechanical properties of silicon.
R.L. Geng, 5/27-31,2013 ECFA LC2013, DESY 1 Update on Raising Q0 at Ultra-High Gradient via Large-Grain Niobium Material Rongli Geng Jefferson Lab ECFA.

R.L. Geng, 5/27-31,2013 ECFA LC2013, DESY 1 Update on Raising Q0 at Ultra-High Gradient via Large-Grain Niobium Material Rongli Geng Jefferson Lab ECFA.

Similar presentations

Ads by Google