We have measured the effects of dilute magnetic-atom doping on the superconducting transition temperature of tungsten thin films. Our “Tc tuning” technique is accurate, precise, and simple. Experiments were performed using dc-magnetron-sputtered tungsten films with undoped values of Tc in the range of 70–150 mK. The magnetic-atom doping was achieved using ion implantation. Specific Tc suppressions of between 5% and 65% were targeted and observed in this study. The transition width of each undoped sample was ≈1 mK and the transition widths remained sharp after implantation with 56Fe+ ions. Our data are in good agreement with predictions of a linear dependence of Tc suppression with increasing magnetic-atom concentration, in the small concentration limit. At higher concentrations, antiferromagnetic coupling between the magnetic dopant atoms becomes important and the Tc-suppression effect is diminished. We use our Tc data to calculate the Abrikosov–Gor’kov (AG) and Ruderman–Kittel–Kasuya–Yosida (RKKY) spin–flip relaxation parameters τAG and τRKKY. We conclude with a brief discussion of applications of the Tc-tuning technique, and present our plans for future studies in this area

Abusaidi, R. A.

Cabrera, Blas

Clarke, R. M.

Cross, J. J.

Saab, T.

Young, Betty A.

English

Scholar Commons - Santa Clara University

Santa Clara University Scholar Commons Physics College of Arts & Sciences 12-1999 Measurement of Tc suppression in tungsten using magnetic impurities Betty A. Young Santa Clara University, byoung@scu.edu T. Saab Blas Cabrera J. J. Cross R. M. Clarke See next page for additional authors Follow this and additional works at: https://scholarcommons.scu.edu/physics  Part of the Physics Commons Recommended Citation Young, B. A., Saab, T., Cabrera, B., Cross, J. J., Clarke, R. M., & Abusaidi, R. A. (1999). Measurement of Tc suppression in tungsten using magnetic impurities. Journal of Applied Physics, 86(12), 6975–6978. https://doi.org/10.1063/1.371781 Copyright © 1999 American Institute of Physics Publishing. Reprinted with permission. This Article is brought to you for free and open access by the College of Arts & Sciences at Scholar Commons. It has been accepted for inclusion in Physics by an authorized administrator of Scholar Commons. For more information, please contact rscroggin@scu.edu. Authors Betty A. Young, T. Saab, Blas Cabrera, J. J. Cross, R. M. Clarke, and R. A. Abusaidi This article is available at Scholar Commons: https://scholarcommons.scu.edu/physics/84 JOURN AL OF APPLIED PHYSICS VOLUME 86, NUMBER 12 15 DECEMBER 1999 Measurement of Tc suppression in tungsten using magnetic impurities B. A. Younga) Deparrment of Phys ics, Santa Clara University, Santa Clara, Californ ia 95053 T. Saab and B. Cabrera Departm enl of Physics, Stanford Universiry, Stc111ford, California 94305 J. J. Cross Department of Phys ics, Santa Clara Universiry. Santa Clara, California 95053 R. M. Clarke and R. A. Abusaidi Departmenl of Physics , Sranford University, Sta,~ford, California 94305 (Rece ived 8 July 1999; acce pted for publi cat ion IO September 1999) We have meas ured the effec ts of dilut e magnetic- atom dopin g on the superco nducting transition temperature of tungsten thin films . Our " Tc tuning " technique is acc urate, prec ise, and simple. Ex periments were performed using de-magnetron-sputtered tung sten films with undop ed values of Tc in the range of 70- 150 mK . The magnetic-ato m doping was achieved using ion implantation . Specific Tc suppr ess ions of between 5% and 65% were targeted and observed in this study. The transition width of eac h undop ed sample was = I mK and the transition width s remain ed sharp after impl antati on with 56Fe + ions. Our data are in good agreement with predi ctions of a linear dependence of Tc suppr ess ion with incre as ing magnetic- atom concentration, in the small co ncentration limit. At higher concentrations , antiferromagnetic coupling betwee n the magnetic dopant ato ms beco mes import ant and the Tc-suppression effect is dimini shed. We use our Tc data to ca lculat e the Abriko sov-Gor'kov (AG) and Rud erman-Kitt el-K asuya- Yosida (RKKY ) spin -flip relaxat ion param eters 7 AG and TRKKY . We concl ude with a brief discuss ion of applications of the Tc-tunin g technique , and prese nt our plans for future studie s in this area. © 1999 American Institute of Phys ics. [S002 l-8979(99)03624-5 ] MOTIVATION AND BACKGRO UND Thin films of superco nducting mate rials have been used as phonon sensors for man y years. The exac t des ign of pho-non sensors varies according to the intended applicat ions. 1 For exa mple, some of the cryo genic detectors deve loped by the Co ld Dark Matter Search (CDMS) collaboration to sea rch for weak ly interacting massive particle (WIMP) dark matter rely on collecting thermal phonons using ove rlappin g thin films of superco nducti ng aluminum and tungste n.2 These phon on sensors are called " W / Al quasi-particle-trap-ass isted electrothermal- feedback transition-edge sensors (QETs )." 3 The energy sensitivit y of a QET phon on sensor depe nds critica lly on the Tc of the superconductin g W film, and also on the width of the superconductin g tran sition . Our tungsten and aluminum films are deposited using a Balzers 450 de-magnetron sputtering syste m and a 99 .999 % pure , vacuum-pr essed tungsten target purcha sed from Joh nson Matthey. Thi s metalization sys tem provid es high-quality films with sufficiently narrow supercondu ct ing tran-sit ions (width ,;;; l mK), howeve r, the " as-deposited " W films ofte n have values of Tc above our target value of 65 mK . The exac t value of the tun gste n film Tc obtained in a given meta lizat ion run depe nds significantly on the detail s of depos ition parameter s and spec ific vacuum chamber condi-tions. The var iabilit y in Tc from one batch of dev ices to the a)Electro nic mai l : byoung @scuacc.scu.edu 0021-8979/99/86(12)/6975/4/$15.00 6975 next is likely due to differin g stress characteristic s in the depos ited films, as well as to minut e quantitie s of various res idual impuriti es prese nt in our vacuum chamber durin g depos ition. Beca use film depos ition parameters cannot be ab-so lutely contro lled, and eve n sligh~ dev iations from our pre-scribed depo sition recipe can give rise to nonoptim al QET Tc values , we recently foc used on developing a techniqu e to adj ust the Tc of our sputtered tungsten films, by postp rocess-ing. We were spec ifically interested in deve lopin g a tech-niqu e which would suppr ess Tc by a presc ribed amount, yet no broade n the superconducting transition nor degra de de-vice performance. DEMONSTRATION OF Tc•TUNING TECHNIQUE Our idea was to use the precision and acc urac y of con-vention al ion-impl antat ion techniques to tune the Tc of indi-vidual W films. To study this possibility , we used a collec-tion of 350-A-thi ck, sputt ered W films with as-deposited Tc's of = 70-150 mK. The films were depo sited in a series of separate depositions; the substrates used were identica l, and co nsisted of a 210-A-thick layer of amorphous silicon on top of a ( I 00) silico n wafer . Imm ediately adjacent samples, each of area = 0.25 cm2, were take n from our as-deposited W films and separately ion-impl anted with 56Fe + ions at 50 ke V. At this energy, a negligible fraction of the incident 56Fe ions fully penetrate a 350-A -thick tungsten film. Doses rang-ing from l.00 X l0 12 to I.00 X I 0 13 ions/c m2 ( ± 0.01 % ) were used in the study prese nted here. A plot of the depth profi le © 1999 American Institute of Physics 6976 J. Appl. Phys., Vol. 86, No. 12, 15 December 1999 2.5 X 10 lS 2 X 10 18 5el 2 56Fe al 50 kc V 5 X 10 17 50 I 00 150 200 250 300 350 400 Depth into Tungsten (A) FIG. I. Calculated Fe concentration vs depth into the W film for one Fe-ion implantation dose used in our study. for one of our implants (5.00 X 1012 cm- 2 at 50 keV), show-ing the concentration of implanted 56Fe + ions versus depth into the tungsten film, is presented in Fig. I. The plot in Fig. I was calculated using PROFILE CODETM, a software simula-tion package purchased from Implant Sciences, Inc. The sputter ing target used to deposit all of our tungsten films contains a res idual impurity concentration of 0.9 ppm Fe. In our study, this Fe concentration would corres pond to an equivalent 50 keV Fe-atom dose of = I .3 X 1011 cm- 2 . In Fig. 2, we plot the measured film T ,. versus ion dose for 50 keV 56Fe+ implant ed into a 350-A-t hick tungsten film with unimplanted superconducting T,. of ( 135 ± 2) mK. In Fig. 3, we plot the T,. data in an alternate form; we plot Tc (control samp le)- Tc (implanted sample) versus peak 56Fe + concentration in atomic ppm, calculated for each of the mea-sured implant doses, and for the one control sample . Our control samp le was not implanted; it contained only the 0.9 ppm Fe contributed from the high-purit y W sputtering target. A quadra tic fit to the combined data provid es an empirica l relationship between [Fe] , the peak concentration of Fe ions in our W samples, and I::,. Tc , the resulting shift in the transi -tion temperat ure: t:.Tc= - 3. 16+ l.66[F e] - 0.00457[Fe] 2 , 40 '-'---'--'--'::-'--'---'--'-:::-'--'-.L...l.--'--'--L..,_--'-..._jLJ..._.__..._J 8x !0 12 lxl0 13 l.2x !0 13 Implanted Fe Dose (atoms/cm"2) FIG. 2. Measured superconducting transition temperature for 350-A-thick tungsten films implanted with 56Fe+ at 50 keY kinetic energy. 80 6 Q E ~4 <l 2 Young et al. FIG. 3. Measured T,. suppression for tungsten samples as a function of peak Fe concentration in our tungsten films. The control sample with 0.9 ppm [Fe] had a T,. of 135::+: 2 rnK. The plotted points include the [Fe]= 0.9 ppm from the sputtering target. The fitted curve is a quadratic. where t:,. T,.= T, (control samp le)- T, (implanted samp le) is measur ed in mK and [Fe] is in ppm , atom ic fraction. We have demonstrated the T, -tunin g process on several additional W films with unimplant ed Tc's of 70- 150 mK. In the simplest approach, we used the data shown in Fig. 2 to determine the dose of 56Fe+ needed to shift the Tc of a given film the desired amount . We assumed a straig ht-line fit to the low-dose data plotted in Fig. 2, then shifted they intercept of that line up or down to match the T, of the new unimplant ed control sample. The slope ( = 1.5 mK/ppm) was not adjusted because the 56Fe + -implanted energy for all samples was held at 50 keV. The ion dose necessa ry to shift Tc by a prescribed amount was then read from the x axis of the intercept-adjusted graph . Using this simple approach, we have suc-cess fully tuned severa l films to within a few mK of a speci-fied target Tc . Most importantly , for all of our samples , the narrow superconductin g transition widths of = 1 mK were maintained even after the Tc-tunin g procedure was com-pleted. In Fig. 4, we show the 135 mK film data, along with a fit to the theoretica l predict ion of Abrikosov and Gor ' kov (AG) for the genera l dependence of T, on magnetic-imp urity con-centration. Based on the AG mode l,4 we assume an antisym-metric exchange coupling between the magnet ic impurity ions (Fe) and the latt ice host atoms in our W films. We assume a one-e lectron Hamiltoni an is sufficient to describe the W system . We also assume the Fe concentration is suf-ficiently low that a dilute-limit approximat ion is valid, and that the presence of impurit y atoms resu lts only in the scat-tering of W conducti on electro ns. That is, we assume no coup ling exists between one impurit y atom and another. Fi-nally , we assume the pair potential for Cooper pairs in the W film is position indepe ndent. For reference, the coherence length in our supe rcondu cting W films is ~0 = 0.3 µm , which is much greater than the film thickness = 350 A. In the AG model, the interac tion betwee n a W-atom electron and an iron impurity can be represented by a perturbin g Hamil-tonian term of the form : J. Appl. Phys., Vol. 86, No. 12, 15 December 1999 Q1 20 s l': 100 ::l co g_ 80 E ~ 60 C: 0 ·;:;; 40 C: "' ,:; ~ 20 IO 20 30 40 50 60 70 80 Conce ntratio n of Fe at Peak (ppm) FIG. 4. Superconducting transition temperature of tungsten as a function of iron dopant concentration (at peak of ion-impl ant distribution ). Curve " AG" corresponds to the Abriko sov and Gor ' kov model. Curve s " AFO " correspond to the AG model modified to include antiferroma gnetic ordering between Fe atoms. Fit " AFO 136" corres ponds to Te0= 136 mK. For com-parison, we include fit " AFO 95," the pred icted curve for films with Teo = 95 mK. Our Fe in W data are best fit for the AFO model with a= -( 0.06 :±:0.0 1). where re and r ; are the position vectors of the W-atom elec-tron and the magnetic impurit y atom , respectively. Similarly , Se and S; are the spin vecto rs of the W-atom electro n and the magnetic-ion impurity . K( re - r;) is the exc hange couplin g constant, which can be positive or negat ive because it oper-ates differently (asy mmetrically) on the two electro n (i 1) in a Cooper pair. The AG model fo r superco nductors with mag-netic impurities yie lds the follow ing relationship between the reduced tran sition temperature Tc /T eo and the reduced magnetic-imp urity concentrat ion xlx c of a sample:5 In( Tc !T c0 ) = i/1{ l/2}- i/1{ ( 1/2) + ( 1 /4)( e - Y)(xl Xe) X (T c0 IT c)} , where i/J is the digamma function , i.e., i/J is the derivative of the logarithm of the r function : ljJ= -y-(1/ z)- L {l/ (z+k)-( 1/k)}, k = I and y is the Euler-M aschero ni constant ( y = 0.577 215 66 .. . ) . At low- impurit y concentratio ns the AG model predicts a linear decrease in Tc as a function of x lx c . At substantially higher concentratio ns, i.e., when Tc~ Teo, the mode l predicts an extre mely rap id decrease of Tc such that the superco nductivity vanishes altoge ther at a certain critical concentrat ion Xe . The cr itical concentra tion can be eva luated from the slope of the T c vs x curve in the low concentration limit: dT cl - - 7T2Tco dx x=O 8e -Y Xe For our W data , and referenced to the peak of each Fe-implant distrib ution, this ca lculation yields a critica l concen-tration Xe= 69 ppm . Young et al. 6977 The AG curve shown in Fig. 4 fits our data well at low-impurit y concentrations , where Tc decreases linearly with increasi ng impurity concentration. For higher concentratio ns, however, i.e., for doping leve ls exceeding = 30-40 ppm Fe , our data deviate substantially from the AG curve. In particu -lar , our data show that the Tc suppress ion due to antisym-metric electro n- ion excha nge coupling in the film become s less significant at the higher Fe conce ntrations studied. At these higher concentrations it is prob able that the weak cou-pling approximatio n for the W-Fe system is not valid and Fe-Fe interact ions can be no longer ignored. Indeed, we believe that the observed dev iation fro m the AG model at high Fe concentration s (i.e., Tc~ Tc0 ) is due to antiferromag-netic interactio ns between the Fe impuriti es in our samples . The antiferro magnetic ordering increases the superco nduct-ing order parameter , which allow s the syste m to supercon-duct when it would otherwise be normal (x ;;;:xc)· In contrast, ferromagnetic (rather than antiferromagnetic) coupling be-tween impuriti es would inhibit the persistence of the super-conducting state. Includin g the effec t of nearest -neighbor magnetic interactio ns between the dopant atoms, we get ln(T c/T c0 ) = i/1{ 1/2}-i/l{( 1/2)+( l/4)(e - -Y)(x/xc) X (T c0 /T c)[ I + a(x!xc)(T c0 /T c)]}, where a is a magnetic coupling parameter 5 a= 'TAdxc)ITRKKY(xc ,Teo), a > 0 for ferro magnetic orderi ng (para llel spins) and a < 0 for antiferro magnetic ordering (antiparallel spins). The best fit to our data shown in F ig. 4 has a= -0.06±0.0l. The parameter s aAG and 'TRKKY (Ruderma n-Kitt el-Kas uya-Yosida) give the relative stre ngths of the impurit y- host atom (Fe-W) interact ions and the impurit y- impurit y (Fe-Fe) in-teractions, respec tively. Us ing our data, we can readi ly cal-culate 'TAG and -rRKKY for the Fe - W system. In the dilute dop ant limit: · Thu s 7T -rAdx c)=-4(- l.5 mK/ppm )(69 ppm) = 7.6 K- 1, and Magnetic ordering in superconduct ors is discu ssed in depth by Roshen and Ruvalds,5 Maple ,6 Fulde and Keller ,7 and Dupont , Ziemniak , and Usade l.8 CONCLUSION AND FUTURE DIRECTIONS The Tc-tuning techniqu e we have developed is reliable and repro ducibl e, and offer s flexibility for fabricati ng cryo-genic devices with specific superco nducting transition tem-perature s. The fact that the measured transition widths of our Tc-suppressed films are not affec ted by the doping proce ss is encourag ing, since we expect that a broadening of the tran-6978 J. Appl. Phys., Vol. 86, No. 12, 15 December 1999 sition would accomp any a decrease in the criti cal current of our superconducting films. For our prim ary applications to cryoge nic particle and photon detectors, such a decrease in critical current would adverse ly affect the ove rall perfor-mance of our dev ices. Soon, we will meas ure direct ly the effec ts of dilut e Fe-a tom doping on the critica l current and heat capacity of the W films. We are in the process of extending our Tc-suppress ion work to W-Co and W -N i sys tems, to further study the ef-fec ts on Tc of magnetic ordering in superconducting films. Those results will be prese nted in a futu re publi cation. ACKNOWLEDGMENTS Tw o of the author s (B.Y. and J.C.) thank The Resea rch Corporation and The Clare Boothe Luce Found ation for their generous support of this work. Additi onal fundi ng was pro-vided by the Department of Energy under Grant No. DE-FG03-90ER40569 . The authors' thin-film samp les were fab-ricated at the Stanford Nanofabrication Facility, a Nati onal Yo ung el al. Sc ience Foundation Technology Center housed in the Center for Integra ted Systems at Stanford University. One of the authors (T .S.) acknow ledges additi onal support from FCAR, of Quebec, Canada. 1 See , for examp le, J . Low Te mp. Phys. 93. ( 1993): The Proceedin gs of the Sixth /11ternatio11a/ Workshop 011 Low Temperarure Detec tors (LTD6 ), ed-ited by H. R. Ott and A. Ze hnde r (E lsev ier Science, New York , 1996): The Proceed ings of the Seventh Internati onal Workshop 011 Low Temperature Detectors for Neu trinos and Dark Matt er (LTD- 7) (Ma x Planck Inst itute of Physics. M unich, Ger many, 1997). 2 R. M. Clarke, P. L. Brink, S. W. Nam , A. K. Dav ies, B. Chugg. B. A. Youn g, and B. Cabrera, The Proceed ings of the Seventh Internati onal Workshop 011 Low Temp eratu re Detectors for Neutrinos and Dar k Matter (LTD -7) , (Max Planck Inst itute of Phy sics, Munich , Germa ny, 1997). 3 K. D. Irw in, Appl. Phys. Lett. 66. I 998 ( 1995). 4 A. A. Ab rikosov and L. P. Gor ' ko v, So v. Phy s. JETP 12, 1243 ( 1961). 5 W. A. Roshen and J . Ruvald s, Phy s. Rev. B 31, 2929 ( 1985). 6 M. B. Map le, in Superco 11ductiviry in d- and f-Band Metal s, edited by D. H. Do ug lass (A merica n Inst itute of Physics, New Yo rk, 1972 ). p. 175; App l. Phys. 9, 179 ( 1976). 7 P. Fu Ide and J . Keller, in Superconducrivity in Ternary Compound s II, ed ited by M. B. Map le and 0. Fisc her (Spr inge r, New York. 1982) , p. 249. 8 W. Du pont. E. Zie mni ak, and K. D. Usadel, J . Low Temp. Phys. 52. 41 ( 1983). 

Measurement of T\u3csub\u3ec\u3c/sub\u3e suppression in tungsten using magnetic impurities

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Measurement of T\u3csub\u3ec\u3c/sub\u3e suppression in tungsten using magnetic impurities

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