Trapped residual magnetic field during the cooldown of superconducting radio frequency (SRF) cavities is one of the primary source of RF residual losses leading to lower quality factor. Historically, SRF cavities have been fabricated from high purity fine grain niobium with grain size ~50 - 100 μm as well as large grain with grain size of the order of few centimeters. Non-uniform recrystallization of fine-grain Nb cavities after the post fabrication heat treatment leads to higher flux trapping during cooldown, hence the lower quality factor. We fabricated two 1.3 GHz single cell cavities from cold-worked niobium from different vendors and processed along with cavities made from SRF grade Nb. The flux expulsion and flux trapping sensitivity were measured after successive heat treatments in the range 800 – 1000°C. The flux expulsion from cold-worked fine-grain Nb cavities improves after 800°C/3 hours heat treatments and it becomes similar to that of standard fine-grain Nb cavities when the heat treatment temperature is higher than 900°C

Anisimov, P. M., (Ed.)

Balachandran, S.

Biedron, S., (Ed.)

Chetri, S.

Dhakal, P.

Khanal, Bashu D.

Lee, P. J.

Milton, S., (Ed.)

Schaa, V. R. W., (Ed.)

Simakov, E., (Ed.)

English

Old Dominion University

Old Dominion University ODU Digital Commons Physics Faculty Publications Physics 2022 Magnetic Flux Expulsion in Superconducting Radio-Frequency Niobium Cavities Made From Cold Worked Niobium Bashu D. Khanal S. Balachandran S. Chetri P. J. Lee P. Dhakal See next page for additional authors Follow this and additional works at: https://digitalcommons.odu.edu/physics_fac_pubs  Part of the Engineering Physics Commons Authors Bashu D. Khanal, S. Balachandran, S. Chetri, P. J. Lee, P. Dhakal, S. Biedron (Ed.), E. Simakov (Ed.), S. Milton (Ed.), P. M. Anisimov (Ed.), and V. R. W. Schaa (Ed.) MAGNETIC FLUX EXPULSION IN SUPERCONDUCTINGRADIO-FREQUENCY NIOBIUM CAVITIES MADEFROM COLD WORKED NIOBIUM∗B. D. Khanal1, S. Balachandran 2, S. Chetri2, P. J. Lee 2, P. Dhakal3†1Department of Physics, Old Dominion University, Norfolk, VA, USA2Applied Superconductivity Center, Tallahassee, FL, USA3Thomas Jefferson National Accelerator Facility, Newport News, VA, USAAbstractTrapped residual magnetic field during the cooldown ofsuperconducting radio frequency (SRF) cavities is one of theprimary source of rf residual losses leading to lower qualityfactor. Historically, SRF cavities have been fabricated fromhigh purity fine grain niobium with grain size 50 - 100 µmas well as large grain with grain size of the order of fewcentimeters. Non-uniform recrystallization of fine-grain Nbcavities after the post fabrication heat treatment leads tohigher flux trapping during cooldown, hence the lower qual-ity factor. We fabricated two 1.3 GHz single cell cavitiesfrom cold-worked niobium from different vendors and pro-cessed along with cavities made from SRF grade Nb. Theflux expulsion and flux trapping sensitivity were measuredafter successive heat treatments in the range 800 – 1000 ◦C.The flux expulsion from cold-worked fine-grain Nb cavi-ties improves after 800 ◦C/3 hours heat treatments and itbecomes similar to that of standard fine-grain Nb cavitieswhen the heat treatment temperature is higher than 900 ◦C.INTRODUCTIONThe performance of the SRF cavities is influenced by sev-eral intrinsic and extrinsic parameters. One of the significantcontributing factor being the trapped mangetic flux due to theinsufficient flux expulsion of ambient magnetic field fromthe SRF cavities when cavities cool-down through the super-conducting transition temperature [1–4] . In theory, duringthe superconducting phase transition, all residual magneticflux should be expelled from the bulk of the superconduc-tor. However, material defects, dislocations, segregation ofimpurities provide favorable sites for magnetic flux pinning,which contribute to an additional rf loss when exposed tothe rf field. It has been demonstrated that several differ-ent pinning mechanism plays a role to the rf losses due tovortices [4]. Studies showed that doped cavities are morevulnerable to the vortex dissipation loss due to the presenceof the dopant on cavities rf surface [3, 5, 6].Earlier studies on flux expulsion and rf losses due topinned vortices showed that the better flux expulsion canbe achieved when the cavity annealing temperature is in-∗ The work is partially supported by the U.S.Department of Energy, Officeof Science, Office of High Energy Physics under Awards No. DE-SC0009960. The manuscript has been authored by Jefferson Science Asso-ciates, LLC under U.S. DOE Contract No. DE-AC05-06OR23177.† dhakal@jlab.orgcreased [7]. The increase in annealing temperature mini-mizes the pinning centers by removing the clusters of disloca-tions and impurities. In addition, the metallurgical state withlarger grain size is expected as the annealing temperature isincreased. Fine-grain recrystallized microstructure with anaverage grain size of 10 - 50 µm leads to flux trapping evenwith a lack of dislocation structures in grain interiors [8].Here, we have conducted a systematic study on cold workSRF niobium in an attempt to correlate the metallurgicalstate with respect to the flux expulsion, flux pinning and fluxtrapping sensitivity. One of each 1.3 GHz TESLA shapesingle cell cavities were fabricated from cold work sheetfrom two different vendors as well as the standard cavitygrade SRF niobium. The cavities were fabricated and pro-cessed together along with witness samples to analyze themetallurgical state as well as pinning strength with respectto the process applied to cavities.CAVITY FABRICATION ANDSURFACE PREPARATIONSFine grain Nb sheet of thickness ∼3 mm SRF grade highpurity with residual resistivity ratio greater than 350 werepurchased from two different Nb vendors. In addition, aspecial order was made with vendors to provide the coldwork with no post processing at vendor site. The vendorsdid not provide any material specifications for cold worksheets, however the sheets were made out of the same batchof SRF grade niobium and the final recrystallization step wasomitted. The electron backscattered diffraction–orientationimage (EBSD-OI) on two sets of Nb sheet along with thetwo single cell cavities fabricated at Jefferson Lab are shownin Fig. 1 from material provided by Tokyo Denkai. Thesecond set of cavities were fabricated at cavity manufacturerfrom the material provided by Ningxia. The fabrication ofcavities were followed the standard practice of deep drawingto half cells, trimming, machining of the iris and equatorof the half-cells, electron beam welding of the beam tubes(made from low purity niobium).After the cavity fabrication, the cavities were chemicallypolished by electropolishing (EP) in a horizontal, rotatingsetup, using a mixture of electronic grade HF:H2SO4 = 1:9 ata constant voltage of ∼14 V, temperature of 15 - 20 ◦C and aspeed of 1 rpm. The total bulk removal of ∼150 µm at cavityequator was removed by EP. The first cycle of heat treatmentof the cavity was done at 800 ◦C for 3 hours in UHV furnace.5th North American Particle Accel. Conf. NAPAC2022, Albuquerque, NM, USA JACoW PublishingISBN: 978-3-95450-232-5 ISSN: 2673-7000 doi:10.18429/JACoW-NAPAC2022-WEZE508: Accelerator ApplicationsWEZE5611ContentfromthisworkmaybeusedunderthetermsoftheCCBY4.0licence(©2022).Anydistributionofthisworkmustmaintainattributiontotheauthor(s),titleofthework,publisher,andDOIFigure 1: 1.3 GHz TESLA shaped single cell cavities fab-ricated with SRF grade Nb (left) and cold work Nb (right).Also shown is the cross-sectional EBSD-OI for respectivesheet materials.The cavity was again subjected to EP at temperature lowerthan 5 ◦C. The successive heat treatment of 900 and 1000 ◦Cfor 3 hours followed by 25 µm EP was done before eachcavity test.EXPERIMENTAL SETUPThree single-axis cryogenic flux-gate magnetometers(FGM) (Mag-F, Bartington) were mounted ∼ 120◦, aparton the external cavity surface parallel to the cavity axis inorder to measure the residual magnetic flux density duringthe cooldown process. The magnetic field uniformity withinthe cavity enclosure is ∼ ±1 mG. Six calibrated temperaturesensors (Cernox, Lakeshore) were mounted on the cavity:two at the top iris, ∼ 180◦ apart, two at the bottom iris,∼ 180◦ apart, and two at the equator, close to the flux-gatemagnetometers. The distance between the temperature sen-sors at top and bottom irises is ∼ 20 cm. The measurementprotocols consisted of two parts. The first part involved sev-eral cooldown and warm up cycles above 10 K in order toexplore the flux expulsion ratio while changing the tempera-ture gradient along the cavity axis. The second part of themeasurement procedure was as follows: (i) the magneticfield was initially set below 1 mG using the field compen-sation coil that surrounds the vertical dewar. (ii) The cavitycool-down process was applied, resulting in < 0.1 K tem-perature difference between the top and bottom iris. Thetemperature and magnetic field were recorded until the de-war was full with liquid He and a uniform temperature of4.3 K was achieved. This step assumes that all applied mag-netic field is trapped into the SRF cavity. (iii) 𝑄0 (𝑇) at lowrf field (peak surface rf magnetic field 𝐵p ∼ 20 mT) from4.3−1.6 K was measured using the standard phase-lock tech-nique. (iv) 𝑄0 vs 𝐸acc was measured at 2.0 K. (v) The cavitywas warmed up above 𝑇c and the residual magnetic fieldin Dewar is set to certain values (∼20 and ∼40 mG). Steps(ii) to (iv) were repeated for different values of magneticfield.RESULTS AND DISCUSSIONSFlux ExpulsionThe ratio of the residual dc magnetic field measured after(𝐵sc) and before (𝐵n) the superconducting transition qualita-tively explains the effectiveness of the flux expulsion duringthe transition. A value of 𝐵sc/𝐵n = 1 represents completetrapping of magnetic field during cooldown, whereas a fluxexpulsion ratio of ∼1.7 at the equator would result from theideal superconducting state. A representative plot of theresidual magnetic field at the FGMs locations measured dur-ing one cool-down cycle for cavity is shown in Fig. 2. Theaverage value of 𝐵sc/𝐵n for the three FGMs at the equatorwas 1.55 ± 0.03. The temperature difference between thetop and bottom iris when the equator of the cavity reachedtransition temperature ∼9.3 K is 3.28 K.Figure 2: Temperature and magnetic field during transitionfrom normal to superconducting state measured during acool-down cycle.Figure 3 shows the results of flux expulsion measurementson 4 cavities under this study after 800 ◦C/3 hours heat treat-ment and successive heat treatment at 1000 ◦C/3 hours. Notshown here, the cavity was also heat treated at 900 ◦C/3 hoursand measurements were repeated before additional 3 hoursheat treatment at 1000 ◦C. It is clearly seen that cavitiesfabricated with SRF grade Nb showed the poorer flux ex-pulsion after 800 ◦C/3hours heat treatment compared to cav-ities made from cold work Nb. The flux expulsion ratioshowed similar behavior after successive heat treatment at1000 ◦C/3 hours.RF MeasurementsThe average rf surface resistance was obtained from themeasurement of 𝑄0 (𝑇) at low rf field (𝐵p ∼ 20 mT) for dif-ferent applied dc magnetic field, 𝐵a, prior to each cool-down.The 𝑅s (𝑇) data were fitted with the generic expression andmethod used in Ref. [9] to extract the residual resistance.The residual resistance as a function of trapped residual mag-netic field was fitted to extract the flux trapping sensitivity,the increase in residual resistance per mG of trapped residual5th North American Particle Accel. Conf. NAPAC2022, Albuquerque, NM, USA JACoW PublishingISBN: 978-3-95450-232-5 ISSN: 2673-7000 doi:10.18429/JACoW-NAPAC2022-WEZE5WEZE5ContentfromthisworkmaybeusedunderthetermsoftheCCBY4.0licence(©2022).Anydistributionofthisworkmustmaintainattributiontotheauthor(s),titleofthework,publisher,andDOI612 08: Accelerator Applications20 --Tlup_Ui~ 20 -- 1"'-'l T! <• r I B,., g· V £ l:: 15 1:i :;:: 2 ~ e u E" ij f- 10 10 .'~ u @) " ;,;: 5 5 16:56: IO 16:57:03 16:57:56 16:58:50 16:59:43 Figure 3: The flux expulsion ratio 𝐵sc/𝐵n as a function oftemperature differenceΔ𝑇 = (𝑇top-iris−𝑇bottom-iris) for cavitiesmade from traditional and cold work Nb sheet from vendors(a) Ningxia and (b) Tokyo Denkai.magnetic field. The flux trapping sensitivity was ∼ 0.35 -0.45 nΩ/mG for all cavities when final surface preparationwas electropolishing. When the final surface preparation waschanged to low temperature baking at 120 ◦C, the flux trap-ping sensitivity increased as high as 0.67 nΩ/mG dependingon the duration of bake [10]. In literature, the flux trappingsensitivities were as high as a few nΩ/mG for nitrogen dopedcavities [4, 5].SUMMARY AND FUTURE OUTLOOKAs shown in Fig. 3, the flux expulsion for cavity madefrom cold work Nb showed a better expulsion when thecavity was heat treated at 800 ◦C/3 hours compared to SRFgrade Nb. After a 900 ◦C and 1000 ◦C heat treatment, theinitial microstructure state of the cavity sheet no longer af-fects the flux expulsion performance. On the other hand,the flux trapping sensitivity depends on the final surfacepreparation of the cavities before the rf test. The poor fluxexpulsion will result in higher flux sensitivity if the finalsurface preparation is other than electropolishing. Whenthe rf surface is modified with impurity doping, the fluxtrapping sensitivity increases. Thus, efficient flux expul-sion is required to minimize the additional rf loss relatedto the trapped flux. It is possible to achieve the full fluxexpulsion limit on cavities fabricated with cold work Nbafter 800 ◦C/3 hours heat treatment if one can maintain thetemperature gradient between the cavities irises above 5.0 K,which is not the case with cavities made from SRF gradeNb. To achieve the high flux expulsion ratio and hence thehigh quality factor in nitrogen doped SRF cavities, someof the cavities used in LCLS-II project were heat treatedas high as 975 ◦C. Achieving good flux expulsion at lowerannealing temperature has an advantage of keeping a higheryield strength and better mechanical stability of Nb cavities.Several sample coupons from half-cell cut out and sheetswere also processed along with the cavities in order the un-derstand the metallurgical state and superconducting pinningproperties with respect to heat treatment temperature. Thereis a correlation of flux expulsion ratio with the grain size,recrystallization and reduced pinning force as a result ofhigh temperature heat treatment. The more detailed samplecoupon studies and comparison with cavity performancewill be presented in future publications. Additionally, the rfsurface modifications to understand the flux trapping sensi-tivity with impurity doping and oxygen alloying on cavitiesmade from SRF grade and cold work Nb is left for futurestudy.ACKNOWLEDGEMENTSWe would like to acknowledge Dr. Gianluigi Ciovati forsupport and several discussions. We would like to thankJefferson Lab technical staff members for cavity fabrication,processing and cryogenic support during rf test.REFERENCES[1] J.-M. Vogt, O. Kugeler, and J. Knobloch, “Impact ofcooldown conditions at 𝑇c on the superconducting rf cavityquality factor”, Phys. Rev. Spec. Top. Accel Beams, vol. 16,no. 10, p. 102002, Oct. 2013.doi:10.1103/PhysRevSTAB.16.102002[2] A. Romanenko, A. Grassellino, O. Melnychuk, and D.A. Ser-gatskov, “Dependence of the residual surface resistance ofsuperconducting radio frequency cavities on the cooling dy-namics around 𝑇c”, J. Appl. Phys., vol. 115, no. 18, p. 184903,2014. doi:doi:10.1063/1.4875655[3] S. Posen et al., “Role of magnetic flux expulsion to reach𝑄0 > 3× 1010in superconducting rf cryomodule”, Phys. Rev.Accel. Beams, vol. 22, no. 3, p. 032001, Mar. 2019.doi:10.1103/PhysRevAccelBeams.22.032001[4] P. Dhakal, G. Ciovati, and A. Gurevich, “Flux expulsion inniobium superconducting radiofrequency cavities of differentpurity and essential contributions to the flux sensitivity”,Phys. Rev. Accel. Beams, vol. 23, no. 2, p. 023102, Feb. 2020.doi:10.1103/PhysRevAccelBeams.23.023102[5] D. Gonnella, J. Kaufman, and M. Liepe, “Impact of nitrogendoping of niobium superconducting cavities on the sensitivityof surface resistance to trapped magnetic flux”, J. Appl. Phys.,vol. 119, no. 7, p. 073904, 2016. doi:10.1063/1.4941944[6] M. Martinello et al., “Effect of interstitial impurities on thefield dependent microwave surface resistance of niobium”,Appl. Phys. Lett., vol. 109, no. 6, p. 062601, 2016.doi:10.1063/1.4960801[7] S. Posen et al., “Efficient expulsion of magnetic flux in super-conducting radiofrequency cavities for high 𝑄0 applications”,J. Appl. Phys., vol. 119, no. 21, p. 213903, 2016.doi:10.1063/1.4953087[8] S. Balachndran et al., “Direct evidence of microstructuredependence of magnetic flux trapping in niobium”, Sci. Rep.,vol. 11, no. 1, p. 5364, 2021.doi:10.1038/s41598-021-84498-x5th North American Particle Accel. Conf. NAPAC2022, Albuquerque, NM, USA JACoW PublishingISBN: 978-3-95450-232-5 ISSN: 2673-7000 doi:10.18429/JACoW-NAPAC2022-WEZE508: Accelerator ApplicationsWEZE5613ContentfromthisworkmaybeusedunderthetermsoftheCCBY4.0licence(©2022).Anydistributionofthisworkmustmaintainattributiontotheauthor(s),titleofthework,publisher,andDOI:j .. ~· ,: , : ,: 1: I , : 11 : . A i. ~I •• "··•••••Cl',g'••D" ,: , ... { ,' ···g•' · □·· Cavity Grade, 800 °C/3h · O·· Cold Work, 800 °C/3h 1.8 Full flux expulsion 1.6 1.4 1.2 (a) • ■·· Cavity Grade, 1000 °C/Jh 1.0 ..-.-------------1 0 • •·· Cold Work. 1000 'C/Jh i..;(..,b,..)~~~--Fu_l_l _fl~ux~tra~p-i-ng__. 2 3 4 5 6 ~T (K) 0 2 3 4 5 ~T (K) 6 [9] G. Ciovati, P. Dhakal, and A. Gurevich, “Decrease of thesurface resistance in superconducting niobium resonatorcavities by the microwave field”, Appl. Phys. Lett., vol. 104,no. 9, p. 092601, 2014. doi:10.1063/1.4867339[10] B. D. Khanal and P. Dhakal, “Effect of Duration of 120 C Bak-ing on the Performance of Superconducting Radio FrequencyNiobium Cavities”, presented at NAPAC’22, Albuquerque,New Mexico, USA, Aug. 2022, paper WEPA27, this confer-ence.5th North American Particle Accel. Conf. NAPAC2022, Albuquerque, NM, USA JACoW PublishingISBN: 978-3-95450-232-5 ISSN: 2673-7000 doi:10.18429/JACoW-NAPAC2022-WEZE5WEZE5ContentfromthisworkmaybeusedunderthetermsoftheCCBY4.0licence(©2022).Anydistributionofthisworkmustmaintainattributiontotheauthor(s),titleofthework,publisher,andDOI614 08: Accelerator Applications

Magnetic Flux Expulsion in Superconducting Radio-Frequency Niobium Cavities Made From Cold Worked Niobium

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Magnetic Flux Expulsion in Superconducting Radio-Frequency Niobium Cavities Made From Cold Worked Niobium

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