The low-temperature (T&lt;300 K) electron-spin-resonance (ESR) spectra of Gd3+ and Er3+ in Pr2CuO4 show symmetry properties appropriate to the crystal tetragonal symmetry. The completely resolved Gd3+ spectra allowed us to measure, at T=2 K, the principal g values g?=1.985(8), g=2.040(8), and the crystal-field parameters [b20=-399(2)×10-4 cm-1, b40=-33.1(7)×10-4 cm-1, and b44=205(3)×10-4 cm-1]. The large broadening of the ESR lines, observed above T40 K, is due to a relaxation via the thermally populated crystal-field excited Pr levels. For Er3+ in Pr2CuO4 we observe a single ESR line corresponding to a ground-state doublet with g?=17.94(5) and g0.2. The absence of any splittings of the ESR lines below the Néel temperature implies that the magnetostatic dipole field at the rare-earth-ion site due to the antiferromagnetically ordered Cu moments is &lt;45 Oe. © 1991 The American Physical Society

Cheong, S

Fisk, Z

Oseroff, S

Rao, D

Rettori, C

Schultz, S

Tovar, M

Vier, DC

Zysler, RD

C. Rettori

D. Rao

S. Oseroff

R. D. Zysler

M. Tovar

Z. Fisk

S.-W. Cheong

S. Schultz

D. C. Vier

Crossref

Crystal-field effects in the electron-spin resonance of<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msup><mml:mrow><mml:mi mathvariant="normal">Gd</mml:mi></mml:mrow><mml:mrow><mml:mn>3</mml:mn><mml:mo>+</mml:mo></mml:mrow></mml:msup></mml:mrow></mml:math>and<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msup><mml:mrow><mml:mi mathvariant="normal">Er</mml:mi></mml:mrow><mml:mrow><mml:mn>3</mml:mn><mml:mo>+</mml:mo></mml:mrow></mml:msup></mml:mrow></mml:math>in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi mathvariant="normal">Pr</mml:mi></mml:mrow><mml:mrow><mml:mn>2</mml:mn></mml:mrow></mml:msub></mml:mrow></mml:math><mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi mathvariant="normal">CuO</mml:mi></mml:mrow><mml:mrow><mml:mn>4</mml:mn></mml:mrow></mml:msub></mml:mrow></mml:math>

Cheong, S-W

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UC IrvineUC Irvine Previously Published WorksTitleCrystal-field effects in the electron-spin resonance of Gd3+ and Er3+ in Pr2CuO4Permalinkhttps://escholarship.org/uc/item/0qr2q36hJournalPhysical Review B, 44(2)ISSN2469-9950AuthorsRettori, CRao, DOseroff, Set al.Publication Date1991-07-01DOI10.1103/physrevb.44.826Copyright InformationThis work is made available under the terms of a Creative Commons Attribution License, availalbe at https://creativecommons.org/licenses/by/4.0/ Peer reviewedeScholarship.org Powered by the California Digital LibraryUniversity of CaliforniaPHYSICAL REVIEW 8 VOLUME 44, NUMBER 2 1 JULY 1991-IICrystal-field effects in the electron-spin resonance of Gd + and Er + in Pr2CnO4C. Rettori, * D. Rao, and S. OseroffSan Diego State University, San Diego, California 92182R. D. Zysler and M. TovarCentro Atomico Bariloche, 8400 Barioloche, Bio Negro, ArgentinaZ. Fisk and S.-W. CheongLos Alamos National Laboratory, Los Alamos, New Mexico 87545S. Schultz and D. C. VierUniversity of California, San Diego, La Jolla, California 92093-0319(Received 22 October 1990)The low-temperature (T &300 K) electron-spin-resonance (ESR) spectra of Gd + and Er + inPr2Cu04 show symmetry properties appropriate to the crystal tetragonal symmetry. The complete-ly resolved Gd + spectra allowed us to measure, at T=2 K, the principal g values g~~ =1.985(8),g, =2.040(8), and the crystal-field parameters [bz = —399(2)X10 cm ', bP4= —33.1(7)X 10cm ', and b4 =205(3)X 10 cm 'j. The large broadening of the ESR lines, observed above T-40K, is due to a relaxation via the thermally populated crystal-field excited Pr levels. For Er + inPr2Cu04 we observe a single ESR line corresponding to a ground-state doublet withg~~=17.94(5)and g~ 0.2. The absence of any splittings of the ESR lines below the Neel temperature impliesthat the magnetostatic dipole field at the rare-earth-ion site due to the antiferromagnetically orderedCu moments is &45 Oe.I. INTRODUCTIONThe magnetic properties of the high superconductingtransition temperature copper oxide materials have beenintensively studied in order to determine whether the un-derlying superconducting mechanism has a magnetic ori-gin. Alternatively, even if the origin of the superconduc-tivity does not involve magnetism, it may be possible toutilize magnetic probes to help elucidate the nature of theelectronic system. We have undertaken a comprehensivestudy of the magnetic properties of the host insulatingT'-phase materials (with symmetry l4/mmm) of the formR2CuO~ (where R is one of several rare earths), using avariety of magnetically sensitive probes including dc andac magnetization, microwave magnetoabsorption, andelectron-spin resonance (ESR). In general, we find thatthe T'-phase R2Cu04 compounds may be classified intotwo groups which show different types of magnetic be-havior. One exhibits a remarkably rich set of magneticfeatures such as weak ferromagnetism, anisotropic mi-crowave absorption signals, and an unusually large aniso-tropic shift of the Gd + ESR field for resonance, whilethe other does not. More recently, we have found thereare also additional splittings of the crystal-field fine struc-ture Gd + ESR lines in Eu2CuO4, and the related T-phase La2Cu04 doped with Gd. The compoundEuzCu04 is a member of the group that does exhibitsome of the unusoal magnetic properties just mentioned(i.e., other than the extra splittings), while LazCuO4forms in a different structure.One of the properties found in the first group of ma-terials is that all the unusual magnetic features are"turned off" above a characteristic temperature, termedTI„which we have identified with the Neel temperatureassociated with the three-dimensional (3D) antiferromag-netic (AF) ordering of the planar Cu-0 set of moments.However, neutron scattering and muon spin rotation(@+SR) (Ref. 9) experiments also indicate a 3D-AF or-dering in the second group, which does not show theunusual magnetic features. As the extra splittings of thecrystal-field fine structure for the Gd + ESR lines werefound in Eu2CuO4, a member of the group which showsthe complex magnetic properties, it was felt that a morecareful examination of the Gd + fine structure spectrumfor a compound that had none of the unusual magneticfeatures was warranted. Pr2CuO4 was chosen and in thisarticle we present an accurate fitting of the crystal-fieldparameters for a spin Hamiltonian with C4, site symme-try. To the accuracy given, we find no deviations fromthat Hamiltonian nor any anomalous behavior of thespectra which might be identified with the transition tothe AF state.EXPERIMENTThe samples used were single crystals of nominal com-position Pr, 9sGdp p2(E1)CUO4 grown from a PbO-basedAux. Pb incorporation into the crystals was not detect-able by x-ray Auorescence. The crystal structure istetragonal (l4/mmm) with ideal lattice parametersa=3.961 A and c=12.214 A. Typical size of the crystals1991 The American Physical SocietyCRYSTAL-FIELD EFFECTS IN THE ELECTRON-SPIN. . .TABLE I. Crystal-field parameters and g values for Gd'+ in Pr2Cu04, measured at T=2 K.bO(10 cm ')—399(2)bo(10-' cm-')—33.1(7)b4(10-:--)205(3) 1.985(8) 2.040(8)where gII and g~ are the gyromagnetic factors for theexternal magnetic field H parallel and perpendicular tothe c axis, respectively. O„are the Stevens operators andb„ the corresponding crystal-field parameters. The gvalues and crystal-field parameters obtained from thefitting of the experimental data at both frequencies aregiven in Table I. These parameters can reproduce thefield for resonance of the spectrum within one-third ofthe linewidth (-20 G) for any arbitary magnetic fieldorientation and microwave frequency. The sign of thecrystal-field parameters was determined from the temper-ature dependence of the relative intensity of the ESRlines at 35 GHz.The observed difference between gII and the free Gd+ion g value (1.991) is smaller than in the case of EuzCu04(see Table I), indicating smaller couplings along the c axisT=4.2K Pr, Cu 04. Gd ~=35.1 6 Hz-5/2 ~-7/2 -3/2~-5/2 -1/2~-3/2Hp II c axisHp ll [100]was 2X3X0.3 mm with the c axis oriented parallel tothe smaller dimension. The ESR experiments were per-formed at 9 and 35 GHz in the temperature range 2 —300K, using conventional spectrometers.Figure 1 shows a low-temperature, well resolved finestructure spectrum (for Pr2Cu04:Gd) which allowed anaccurate determination of the crystal-field Hamiltonianappropriate for the C4, point symmetry occupied by therare-earth ions in these cuprate compounds:H =g~~~p&HzSz+ g @~ (HxSx +HySy )+b 202+ b 404+ b 404,5.5Pr2Cu04' . GdT=SK~ u = 9.219 GHz4.5-~ ~ 0 —~ ~~ W~ -~0 4 ~~ ~ ~~ ~O» ~~ ~o350I/I~ ~ ~ ~~ ~ ~ ~~ 0eN ~ ~2.5.~ ~~ ~ ~ ~ - ~ -o-~4 ~0 0 ~~ ~~O~ ~ ( ~ —~~ ~ g j'N ~~ ~ ~ ~ ~ ~0 ~ ~for the Pr-based compound. However, there is asignificant g-value anisotropy. Also, the crystal-field pa-rameters given in Table I are smaller than those corre-sponding to Eu2Cu04. This reduction is consistent withthe larger lattice parameter of Pr2Cu04. Figures 2—5show the angular dependence of the ESR spectrum forPr2Cu04. Gd for each microwave frequency for differentcrystal orientations.Figure 6 shows the temperature dependence of thelinewidth for two Gd + ESR transitions. An initial tem-perature independent linewidth (T (40 K) is in generalexpected for Gd ions (S state) in insulators. The sharpincrease of the linewidth above 40 K is probably due torelaxation via thermally populated excited crystal-field Prlevels. Indeed, recent inelastic neutron scattering experi-ments in Pr2CuO4, determined the presence of a I 5 firstexcited level at about 13.7 meV above the I 3 groundstate. This excited level could provide the relaxationchannel for the Gd + impurities, via an exchange or elec-tric dipolar coupling mechanism. 'As mentioned above, we have also prepared a singlecrystal of Pr, 99Er00,CuO4 and observed a single strongESR resonance as expected for a ground-state Er + dou-1.50[ 110]I30 60[ 100]9010 11 12 13Magnetic Field {kOe)14 15 8 (deg )FIG. 1. 35 GHz ESR spectrum of Gd in Pr2Cu04 atT=4.2 K.FIG. 2. Angular dependence of the 9 GHz ESR spectrum ofGd'+ in Pr2Cu04 for the dc magnetic field on the (001) plane.The dashed lines are guides to the eye.828 C. RETTORI et al.l514- '-00-~ - ~13-0 —~Pr& CuO4.' GdT=4.2K~ = 35.15 GHz~ a~ ~O ~~~ ~ W ~~ ~O ~~ g~O~ ~~ ~~ ~ —~ -e —~ -o- ~ ~ —~ —~ —~ ~ ~~O~ ~ ~ -- ~~ ~ 0 r+4 ~~~O0 ~ ~~~~~ ~Or%4[ 110]16O12~ - ~ —~ -'~lf2~-1f2~ —~ —~ —~-1/2'/24 —~ ~-3/2'/2~ —~ —~ -10--5/2m-7f2 ~e- ~7/2wSf2Sf2w3/21 4 ~ —~ ~ ~Pr~cu04. GdT =42 Ku = 35.08 GHz4 ~ ~ ~ ~~ ~ P~ ~ 00 /~ 1—~ ~ ~ X 0 ~ ~ ~/ rO~ ~-4-~ —~ —~ —~ y / ~4»/ - ~-~ ~ —~ «0~ ~ ~ ~g~ ~ ~ ~ 0 0~ ~~ ~g 0 ~ ~~ Mt /~ ~~ 0/ N ~/ ~ ~/0e/'/e010[ 100]30 608 (deg)90[010] c axisI608 (deg )30 0[ 100]FIG. 3. Angular dependence of the 35 GHz ESR spectrum ofGd in PrzCu04 for the dc magnetic field on the (001j plane.The dashed lines are guides to the eye.FIG. 5. Angular dependence of the 35 GHz ESR spectrum ofGd + in Pr&Cu04 for the dc magnetic field in the plane from thec axis to the [100]. The dashed lines are guides to the eye.blet. Along the c axis, at 4.2 K, we have measured alinewidth of AH —=60 Oe, which is considerablybroadened by -20 K. The resonance field as a functionof angle is shown in Fig. 7, from which we deduce the gvalues, g~~= 17.94(5) and gt ~ 0.2. No splitting of this linewas observed for angles of magnetic field from 0' to 85'away from the c axis. (Angles further from the c axiswere not measured because the field for resonance is thenshifted beyond the range of our magnet. )CONCLUSIONSThe crystal-field parameters obtained by fitting thespin-Hamiltonian of Eq. (1) are consistent with the ob-4Pr CuO: GdT=2K 7/2 w 5/2u = 9.229 GHz/////-Sf'-7/2 //1~ 5f2~ 3/2/r/ -~ 3/2 m 1/2/1/2 m -1/2/ O~r -1/2 w -3f2r + —' ———0 ~ ~&p 0-3/2 w -5/2O~e ~500400'O O OO gO0 300'~ 200'00Og100's ss~0 ~Pr Cuo: GdH II c axisu = 35.5 GHz0O O g ~-3g~5/2o ~0[ 100]30 608 (deg)90c axis080 160 240 320Temperature ( K )FIG. 4. Angular dependence of the 9 GHz ESR spectrum ofGd + in Pr&Cu04 for the dc magnetic field in the plane from the[100] to the c axis. The dashed lines are guides to the eye.FIG. 6.ture.ESR linewidth of the Gd'+ ( ——,' ~——,' ) andtransitions in Pr&Cu04 as a function of tempera-CRYSTAL-FIELD EFFECTS IN THE ELECTRON-SPIN. . .12—Pr, Cu 04. ErT=4.2K~=35.1 0HZ10—0c axisI20 400 (deg)2- ~ —0I I ~ 0 ~ OO--i -~~WI60iI)III/lI/I/I//I//////~O80[a,b]Neel temperature (this splitting was interpreted as a re-sult of the internal field due to the Cu moments at therare-earth site), no additional splittings were observed inPr2CuO4 at any temperature or magnetic field orienta-tion. Our experiments for Pr2Cu04 place a limit of &45Oe for the magnetic dipole field of the Cu moments at therare-earth sites, in contrast to —500 Oe found forEu2Cu04 and La2Cu04. If one assumes that our sampleshave the same AF transition as observed by neutronscattering, we can conclude that the Pr2Cu04 is represen-tative of that subgroup of the R 2Cu04 which does notmanifest an indication of the 3D-AF transition via any ofthe diverse magnetic signatures observed for the sub-group that do. We may speculate that the di6'erence de-pends upon subtle lattice distortions which have not yetbeen detected. The reason for the absence of any split-ting that could be attributed to the magnetic dipole fieldfor the Cu moments also remains a puzzle.FIG. 7. Angular dependence of the 35 GHz ESR spectrum ofEr + in Pr2Cu04 in the (100) plane. The dashed line is the bestfit obtained for g~~= 17.94 and g~ =0.2.served ESR spectra being due to a Gd ion in a site ofC4, symmetry. In contrast to the ESR spectra of Gd +in EuzCu04, and La2Cu04, which clearly showed an ad-ditional splitting of each fine structure line below theACKNOWLEDGMENTSThis research was partially supported at San DiegoState University by the National Science Foundation(NSF) under Grants Nos. NSF-DMR-88-01317 andNSF-INT-89-00851; at the University of California, SanDiego by Grants Nos. NSF-DMR-86-13858 and ONR-N00014-87-K-0338; and at the Los Alamos NationalLaboratory by the United States Department of Energy.'Permanent address: Universidade Estadual de Campinas, In-stituto de Fisica, C.P. 6165, 13081 Campinas {SP),Brazil.Y. Kitaoka, S. Hiramatsu, K. Ishida, T. Kohara, and K. Asya-ma, J. Phys. Soc. Jpn. 56, 3024 (1987); Y. Kitaoka, K. Ishida,S. Hiramatsu, and K. Asayama, ibid. 57, 734 (1988);Watanabe, K. Kumagi, Y. Nakamura, T. Kimura, Y. Nakam-ichi, and H. Nakajima, ibid. 56, 3028 (1987); D. Vaknin, S. K.Sinha, D. E. Moncton, D. C. Johnston, J. M. Newsam, C. R.Safinya, and H. E. King, Jr., Phys. Rev. Lett. 58, 2802 (1987);Y. J. Uemura, W. J. Kossler, X. H. Yu, J. R. Kernpton, H. E.Schone, D. Opie, C. E. Stronach, D. C. Johnston, M. S. Al-varez, and D. P. Goshorn, ibid. 59, 1045 (1987);J. I. Budnick,B. Chamberland, D. P. Yang, Ch. Niedermayer, A. Golnik,E. Recknagel, M. Rossmanith, and A. Weidinger, Europhys.Lett. 5, 651 (1988); J. I. Budnick, A. Golnik, Ch. Nieder-mayer, E. Recknagel, M. Rossmanith, A. Weidin ger, B.Charnberland, M. Filipkowski, and D. P. Yang, Phys. Lett. A124, 103 (1987); P. W. Anderson, Science 235, 1196 (1987); P.W. Anderson, G. Baskaran, Z. Zou, and T. Hsu, Phys. Rev.Lett. 58, 2790 (1987); V. I. Emery, ibid. 58, 2794 (1987); M.Cyrot, Solid State Commun. 62, 821 (1987); J. R. Schrieffer,X.-G. Wen, and S.-C. Zhang, Phys. Rev. Lett. 60, 944 (1988);A. Aharony, R. J. Birgeneau, A. Coniglio, M. A. Kastner,and H. E. Stanley, ibid. 60, 1330 (1988); R. J. Birgeneau, M.A. Kastner, and A. Aharony, Z. Phys. B 71, 57 (1988).~S. B. Oseroff, D. Rao, F. Wright, D. C. Vier, S. Schultz, J. D.Thompson, Z. Fisk, S.-W. Cheong, M. F. Hundley, and M.Tovar, Phys. Rev. B 41, 1934 (1990).R. D. Zysler, M. Tovar, C. Rettori, D. Rao, S. B.Oseroff, D. C.Vier, S. Schultz, Z. Fisk, and S.-W. Cheong, Bull. Am. Phys.Soc. 35, 429 {1990).4S. B. Oseroff, C. Rettori, D. Rao, D. C. Vier, S. Schultz, Z.Fisk, S.-W. , Cheong, M. Tovar, and R. D. Zysler (unpub-lished).5P. Allenspach, S.-W. Cheong, A. Dommann, P. Fischer, Z.Fisk, A. Furrer, H. R. Ott, and B. Rupp, Z. Phys. B Cond.Matter 77, 185 (1989).D. E. Cox, A. I. Goldman, M. A. Subramanian, J. Gopalak-rishnan, and A. W. Sleight, Phys. Rev. B 40, 6998 (1989).7S. Skanthakumar, H. Zhang, T. W. Clinton, W. H. Li, J. W.Lynn, Z. Fisk, and S.-W. Cheong, Physica C 160, 124 (1989).~Y. Endoh, M. Matsuda, K. Yarnada, K. Kakurai, Y. Hidaka,G. Shirane, and R. J. Birgeneau Phys. Rev. B 40, 7023 (1989).G. M. Luke, B. J. Sternlieb, Y. J. Uemura, J. H. Brewer, R.Kadono, R. F. KieA, S. P. Kreitzman, T. M. Riseman, J.Gopalakrishnan, A. W. Sleight, M. A. Subramanian, S. Uchi-da, H. Takagiana, and Y. Tokura, Nature 338, 49 (1989).F. Mehran, K. W. H. Stevens, and T. S. Plaskett, Phys. Rev. B20, 1817 (1979); F. Mehran, K. W. H. Stevens, T. S. Plaskett;and W. J. Fitzpatrick, ibid. 22, 2206 (1980).

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Crystal-field effects in the electron-spin resonance of Gd3+ and Er3+ in Pr2CuO4

Crystal-field effects in the electron-spin resonance of Gd3+ and Er3+ in Pr2CuO4.

Crystal-field effects in the electron-spin resonance of Gd3+ and Er3+ in Pr2CuO4.

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