The electromagnetic response of a superconducting ferromagnets

The electromagnetic response of a superconducting ferromagnets

The electromagnetic response of the superconducting ferromagnets RuSr₂Gd₁.₅Ce₀.₅Cu₂O₁₀ (Ru–1222 Gd) in an ac magnetic field of finite amplitude is investigated. Taking into account weak links between granules and magnetization of the magnetic sublattice, it is shown that the response of a sample i...

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Datum:2007
Hauptverfasser: Leviev, G.I., Tsindlekht, M.I., Sonin, E.B., Felner, I.
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Veröffentlicht: Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України 2007
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Свеpхпpоводимость, в том числе высокотемпеpатуpная
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spelling nasplib_isofts_kiev_ua-123456789-1209092025-02-09T13:52:14Z The electromagnetic response of a superconducting ferromagnets Leviev, G.I. Tsindlekht, M.I. Sonin, E.B. Felner, I. Свеpхпpоводимость, в том числе высокотемпеpатуpная The electromagnetic response of the superconducting ferromagnets RuSr₂Gd₁.₅Ce₀.₅Cu₂O₁₀ (Ru–1222 Gd) in an ac magnetic field of finite amplitude is investigated. Taking into account weak links between granules and magnetization of the magnetic sublattice, it is shown that the response of a sample in a superconducting state with the fundamental frequency and frequency of the 3rd harmonic can be described by the nonlinear equation for the macroscopic field. Generation of the harmonic at temperatures above superconducting transition corresponds to Rayleigh`s mechanism. Using various regimes of a sample cooling, the internal magnetic field determined by the magnetic sublattice was measured. This is direct evidence of the coexistence of ferromagnetic and superconductive order parameters in high-Tc ruthenocuprates. The work was supported by the Klatchky foundation. The authors are deeply grateful to E. Galstyan for the sample preparation and useful discussions. 2007 Article The electromagnetic response of a superconducting ferromagnets / G.I. Leviev, M.I. Tsindlekht, E.B. Sonin, I.Felner // Физика низких температур. — 2007. — Т. 33, № 08. — С. 844–848. — Бібліогр.: 14 назв. — англ. 0132-6414 PACS: 74.70.Pq, 74.25.Nf https://nasplib.isofts.kiev.ua/handle/123456789/120909 en Физика низких температур application/pdf Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
topic Свеpхпpоводимость, в том числе высокотемпеpатуpная
Свеpхпpоводимость, в том числе высокотемпеpатуpная
spellingShingle Свеpхпpоводимость, в том числе высокотемпеpатуpная
Свеpхпpоводимость, в том числе высокотемпеpатуpная
Leviev, G.I.
Tsindlekht, M.I.
Sonin, E.B.
Felner, I.
The electromagnetic response of a superconducting ferromagnets
Физика низких температур
description The electromagnetic response of the superconducting ferromagnets RuSr₂Gd₁.₅Ce₀.₅Cu₂O₁₀ (Ru–1222 Gd) in an ac magnetic field of finite amplitude is investigated. Taking into account weak links between granules and magnetization of the magnetic sublattice, it is shown that the response of a sample in a superconducting state with the fundamental frequency and frequency of the 3rd harmonic can be described by the nonlinear equation for the macroscopic field. Generation of the harmonic at temperatures above superconducting transition corresponds to Rayleigh`s mechanism. Using various regimes of a sample cooling, the internal magnetic field determined by the magnetic sublattice was measured. This is direct evidence of the coexistence of ferromagnetic and superconductive order parameters in high-Tc ruthenocuprates.
format Article
author Leviev, G.I.
Tsindlekht, M.I.
Sonin, E.B.
Felner, I.
author_facet Leviev, G.I.
Tsindlekht, M.I.
Sonin, E.B.
Felner, I.
author_sort Leviev, G.I.
title The electromagnetic response of a superconducting ferromagnets
title_short The electromagnetic response of a superconducting ferromagnets
title_full The electromagnetic response of a superconducting ferromagnets
title_fullStr The electromagnetic response of a superconducting ferromagnets
title_full_unstemmed The electromagnetic response of a superconducting ferromagnets
title_sort electromagnetic response of a superconducting ferromagnets
publisher Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України
publishDate 2007
topic_facet Свеpхпpоводимость, в том числе высокотемпеpатуpная
url https://nasplib.isofts.kiev.ua/handle/123456789/120909
citation_txt The electromagnetic response of a superconducting ferromagnets / G.I. Leviev, M.I. Tsindlekht, E.B. Sonin, I.Felner // Физика низких температур. — 2007. — Т. 33, № 08. — С. 844–848. — Бібліогр.: 14 назв. — англ.
series Физика низких температур
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fulltext Fizika Nizkikh Temperatur, 2007, v. 33, No. 8, p. 844–848 The electromagnetic response of a superconducting ferromagnets Grigory I. Leviev, Menachem I. Tsindlekht, Edouard B. Sonin, and Israel Felner The Racah Institute of Physics, The Hebrew University of Jerusalem, Jerusalem 91904, Israel E-mail: gileviev@vms.huji.ac.il Received September 19, 2006, revised December 7, 2006 The electromagnetic response of the superconducting ferromagnets RuSr 2Gd15. Ce 0 5. Cu 2O10 (Ru–1222 Gd) in an ac magnetic field of finite amplitude is investigated. Taking into account weak links between gran- ules and magnetization of the magnetic sublattice, it is shown that the response of a sample in a supercon- ducting state with the fundamental frequency and frequency of the 3rd harmonic can be described by the nonlinear equation for the macroscopic field. Generation of the harmonic at temperatures above supercon- ducting transition corresponds to Rayleigh`s mechanism. Using various regimes of a sample cooling, the in- ternal magnetic field determined by the magnetic sublattice was measured. This is direct evidence of the co- existence of ferromagnetic and superconductive order parameters in high-Tc ruthenocuprates. PACS: 74.70.Pq Ruthenates; 74.25.Nf Response to electromagnetic fields. Keywords: electromagnetic response, superconducting ferromagnets, high-Tc ruthenocuprates. 1. Introduction The nature of the coexistence of the long-range mag- netic and superconducting order parameters is discussed in- tensively, since Ginzburg’s work [1]. The origins of the or- der parameters in ferromagnetic superconductors, magnetic structure and magnetic properties of such materials are hot topic in the present time [2]. Magnetic characteristics of superconducting ferromagnets such as Ru–1222 Gd is ex- tremely interesting [3]. Those samples exhibit a magnetic transition at TN � 125–180 K and superconducting transi- tion at Tc � 25–50 K (T TN c� ). However experimental study of the low frequency electrodynamics is almost ab- sent. In the present paper we study the behavior of the ceramic samples Ru–1222 Gd in the presence of dc and low-frequency magnetic fields at temperatures both above and below of the superconducting transition temperature. Our measurements [4] show that the critical current in the superconducting state is very small. It leads to the specific character of the response of the sample with respect to the ac fields. The response becomes nonlinear already at small am- plitudes and then — at high enough amplitudes — the linear modes return. Experimentally in our case nonlinearity also appearers at T T Tc N� � , but the mechanism in this temper- ature range is different as the characters of the curves are completely different. In particular, the generation of all har- monics is well described by the Rayleigh`s mechanism for ferromagnetic materials [5,6]. Once a remanent magnetization is induced above Tc those materials «remember» it even when they are cooled down to T Tc� , and the internal field which is created, can induce the so-called spontaneous vortex phase. The purpose of the present paper is to show how this internal field can be evaluated through the amplitude of the third harmonic generation signal. 2. Experimental details We studied the response of a Ru–1222 Gd sample to an ac magnetic field. A ceramic sample with dimensions of 8 2 2� � mm was prepared by a solid-state reaction as described in Ref. 4. In all experiments described here we measured the voltage drop induced in a pickup coil, which is proportional to the time derivative of the magne- tization M( )t . Our home made experimental setup was adapted to a commercial MPMS SQUID magnetometer. An ac field h t( ) at a frequency of �� �2 1 5� . kHz and an amplitude up to the h0 3� Oe was generated by a copper © Grigory I. Leviev, Menachem I. Tsindlekht, Edouard B. Sonin, and Israel Felner, 2007 solenoid existing inside the SQUID magnetometer. The two signals at the fundamental and at the harmonic fre- quencies were simultaneously recorded. The temperature, dc magnetic field, and amplitude dependencies of the fun- damental and harmonic signals have been measured by the two coils method. In the present paper only the results of the first and third harmonics will be discussed. 3. Experimental results and discussion The magnetization of a sample can be expressed by the macroscopic field inside the sample B( , )r t and the homo- geneous ac field h h( ) cos( )t t� 0 � to which the sample was exposed: M B r h( ) ( ) [ ( , ) ( )]t / V t t dV� � � 1 4� � � �h 0 � � � �n nn t n tcos sin( ) ( ) , (1) where the integration is made over a volume of the sample V and � n , � n are the in-phase and out-of-phase suscepti- bilities. Here we expand the magnetization to Fourier se- ries [7,8]. Generally speaking � n and � n depend on: the temperature T , the external magnetic field H and the am- plitude of the ac field h0. 3.1. Susceptibility at H = 0 Figure 1 shows the zero field cooled (ZFC) temperature dependence of the in-phase magnetic susceptibility � 1 and the amplitude of the third harmonic A i3 3� � �� � | |, mea- sured at H � 0. The temperature dependence of ��( )T is typical for superconducting ferromagnets [9]. This plot reveals three transitions: (i) the paramagnetic-antiferromagnetic tran- sition at TN �125 K, (ii) the most pronounced transition, which corresponds to peak at Tm � 78 K, and (iii) the tran- sition into a superconducting state at Tc � 28 K. The na- ture of the second transition, which is evident in both the linear and nonlinear responses, is not yet completely clear and it is discussed elsewhere [10]. Ambiguity is connected with the magnetic phase between Tm and TN , which is characterized by low coercivity. However, the low-temperature side near the Tm transition definitely corresponds to a weak ferromagnetic phase, and is dis- cussed here. The amplitude dependencies of � � ( )h0 and A h3 0�( ) are shown on Fig. 2. The �� dependence looks like a step function. Similar behavior is observed for A h3 0�( ). At T Tc� A h3 0�( ) is different, and its typical dependence is presented at Fig. 3. We shall discuss the amplitude dependencies for �1 and A3� in a superconducting state. Let us start with the microscopic Maxwell`s equation: curl h r j r( , ) ( , )t c t� 4� , (2) where r is a radius-vector, t is time, and j is current density. For macroscopic values it is necessary to average both parts of this equation over a certain volume, which includes many grains. The average current density is given by � � � � � � �j r j M M( , )t c cJ s gcurl curl . (3) The electromagnetic response of a superconducting ferromagnets Fizika Nizkikh Temperatur, 2007, v. 33, No. 8 845 200 100 0 T, K Tm 0 50 100 TN Tc A , h = 2 Oe 3 0� � 1 3 , A , ar b . u n it s � � 1 0, h = 0.4 Oe Fig. 1. Temperature dependencies of �� and A3� at H � 0. R e , ar b . u n it s � 1 0 –0.02 –0.04 –0.06 –0.08 0.01 0.1 1.0 h , Oe0 0.01 0.1 1.0 0.20 0.15 0.10 0.05 0 h , Oe0 T = 5 K ZFC A , ar b . u n it s 3 � Fig. 2. Amplitude dependencies of ��. Inset: amplitude depen- dence A3� after ZFC at T � 5 K. h , Oe0 0 1 2 3 A , ar b . u n it s 3 � 1.0 0.5 0 T = 62 K H = 0 Fig. 3. Amplitude dependencies of A3� after ZFC at T � 62 K. Here the average current density is the sum of the contri- butions from Josephson’s junctions jJ , and is propor- tional to the spin magnetization M s and to the magnetiza- tion M g caused by superconducting currents inside the grains. Using the relation � �� ��� � �1 4 4s g , where � is permeability, � g and � s are the grains and lattice suscep- tibilities, one obtains the macroscopic Maxwell equation: curl B r j r( , ) ( , )t c tJ� 4�� . (4) There is no doubt, that in granular superconductors the nonlinearity in the superconducting state is caused by weak links between grains through which Josephson’s currents jJ flow. This current averaged over numbers of junctions can be expressed by the parameters describing the granulated media. By combining the current density expression [11,12] and Maxwell`s equation (4) we obtain the nonlinear equation for the vector potential A r( , )t , which describes the behavior of a sample exposed to an ac field with finite amplitude: curl curl expA A A� � � � � � � � � � � � 1 2 2 2 2 2� � � �j j j j A B d dt , (5) where � j , B j , � are defined by the average parameters of the media. These parameters are: � � ��j c / I a2 0 3 0 2� ( ), B I /cj 2 04� �� , � � � ��� j a / Rc2 2 0 2 22( ), here 0 is a flux quantum, I is average current of junction, � is number of junctions per unit volume, a0 is average distance between grain centers, R is the junction resistance in a resistive junction model. Parameter � represents a characteristic time of the problem. The vector potential A permits one to define the magnetization of the sample M and the sus- ceptibilities of the sample. Let us consider: (a) the sample as an infinite slab of thickness d located at � ! !d/ x d/2 2, (b) the external ac field h t( ) is along the y axis, and (c) the vector potential A, electric field E, a current density jJ are all directed to z axis. Then only derivatives over x and t of the z compo- nent of the vector potential A z exist. (Further the index z will be omitted.) Now we obtain: d A x t dx A x t A x t Bj j j 2 2 2 2 2 2 1( , ) ( , ) ( , ) � � � � � � � � � � � � � � � exp j dA x t dt2 ( , ) . (6) The solution of Eq. (6) for the vector potential at the fun- damental frequency looks as follows: A x t A x i t A x i t( , ) [ ( ) ( ) ( ) ( )]*� � � � 1 2 0 0exp exp� � � �| | ( )A t0 cos � " . Using Fourier-transformation, one can get for the ampli- tude A x0( ) the second order ordinary differential equation: d A x t dx A x A x i A xj j 2 0 2 2 0 0 2 0 ( , ) ( ) [ ( )] ( )� �� �� ���# . (7) Function #( ) | | | | y y B I y Bj j j j � � � � � � � � � � � � � � � � � � �exp 2 2 2 0 2 2 22 2� � I y Bj j 1 2 2 22 | | � � � � � � � � � $ % & & ' ( ) ) takes into account the nonlinearity of the media, which is connected with Josephson’s currents. Here I 0 and I1 are modified Bessel functions. At small amplitudes, # ap- proaches to 1 and this case corresponds to the linear me- dia. For a sample inside the ac coil, it is convenient to con- sider a symmetric excitation. So the boundary conditions for the magnetic induction has the form: B t x d/( )| � � �2 � ��B t B tx d/( )| ( )2 0 cos � . Due to the symmetry, the vec- tor potential is equal to zero in the middle of the slab ( x � 0). Using Eq. (6) we can obtain the expression for the vector potential at the boundary A d/0 2( )� : 0 2 2 0 2 1 0 0 2 A d/ A d/ z y y i dy B ( ) ( ) ( ( ) ) � � � � � $ % & & & ' ( ) ) ) # �� /2 2 dz d j � � . (8) The dependence of the complex susceptibility of a sample on the fundamental frequency �1 is connected to the vector potential on the boundary: � � �1 0 0 1 4 2 2 4 � � � �A d/ dh ( ) . (9) With the limit of low and large amplitudes of excitations, Eq. (7) becomes linear and the susceptibility in these cases is � � �� � � 1 1 4 2 2 � � � * *d d th , (10) where � � �� � �� � ** ( ) ( )� � � �� j / ji i1 11 2 — at low am- plitudes and � � ��* ( )� � j /i 1 2 — at large amplituded. The transition from low to the large amplitudes occurs at a field about B j . In our experiments B j � 0 015. Oe. The ra- tio + between the real part of the susceptibility at low and high amplitudes is + � � �� � � �� �� � � � � � 1 0 1 0 1 2 1 ( ) ( ) h B h B /dj j j . Using the experimental value of this ratio, it is possible to evaluate �: � + +� �( )1 / . In our experiment we obtained + � 5, and � � 0 8. . Other parameters of the model can be evaluated as well by using the grains size a0 and resistivity the sample � in a normal state. Our SEM indicates that a0 41 10 10� � � �( ) cm, and four probe resistivity measu- rement at room temperature � res � � �2 5 10 14. in Gauss 846 Fizika Nizkikh Temperatur, 2007, v. 33, No. 8 Grigory I. Leviev, Menachem I. Tsindlekht, Edouard B. Sonin, and Israel Felner units [4]. Therefore we estimate: � j � � � �� �5 10 5 103 2 cm, � � �� �10 1011 9 s, j c � �0 3 3. A cm/ 2, R � �01 1. Ohm. 3.2. Third harmonic generation According to the nonlinear Eq. (5), application of an ac field at fundamental frequency causes the harmonic generation. To fit qualitatively the experimental data shown in 2 it is sufficient to substitute in the Eq. (6) the calculated field at the fundamental frequency, nonlinearly dependent on the amplitude of the excitation. The ampli- tude dependence of the response at T Tc� in the mag- netic-ordered state does not show a saturation (Fig. 3). The amplitude of 3rd harmonic exhibits square-law de- pendence on h0 quite well describe by the Rayleigh mech- anism [5,6]. Nonlinearity at these temperatures corre- sponds to oscillatory motion of the domain walls in an ac field (the hysteretic dependence of a susceptibility on a magnetic field). 3.3. Influence of an applied magnetic field The response in the presence of a dc magnetic field de- pends on the prehistory and the regimes of sample cool- ing. The physical picture thus is complicated — there is a magnetization connected to a lattice, the sample is broken into domains, and at low temperatures magnetization of the lattice can lead to a spontaneous vortex phase [13]. We used the dependence of the amplitude of the 3rd har- monic on an external field (Fig. 4) and various cooling re- gimes to measure internal magnetic field in a sample, re- maining after turning off the external field. The procedure of cooling of a sample which we have named internal-field cooling (IFC) is this: the sample was cooled down to TIFC at an external magnetic field H IFC (T TIFC N� ). At TIFC , the magnetic field was turned off and further cooled down to T � 5K in zero external field. It appears that by using the IFC procedure the properties of the superconducting state were different from those measured after the regular ZFC process from temperatures above TN . Thus, in the super- conducting state, the sample senses the internal magnetic field evolved from the remanent magnetization, which was formed in the normal (not superconducting) ferromagnetic phase and then quenched on further cooling. We measured the signal of the third harmonic at 5 K af- ter the IFC procedure. Figure 5 shows the A H IFC3�( ) dependence for TIFC � 40 and 70 K. It is evident that the field H IFC sup- presses the third harmonic as well as the external field after ZFC even though the field H IFC was turned off be- fore the superconductivity onset. The turn off H IFC at T � 40 K affects A3� more strongly than for T � 70 K be- cause the remanent magnetization in the first case is larger than for the latter. Figure 6 presents the signal of the third harmonic A T3�( � 5 K) as a function of TIFC after cooling in H IFC � 30 Oe. The signal of the third harmonic goes down for TIFC � 80 K. This demonstrates that the suppression of the third harmonic response by the internal magnetic field takes place only if the field cooling continues down to the weakly ferromagnetic phase with essential coercivity. It is known that in idealized single-domain superconducting The electromagnetic response of a superconducting ferromagnets Fizika Nizkikh Temperatur, 2007, v. 33, No. 8 847 T = 5 K h = 0.2 Oe0 q = 0.8 H–q A , V 3 � � 15 10 5 0 H, Oe 0 50 100 150 Fig. 4. Magnetic field dependence of A3� at T � 5 K after ZFC. T = 70 KIFC T = 0 KIFC 4 h = 0.2 Oe0 A , V 3 � � H, Oe 0 50 100 150 10 5 Fig. 5. A T3 5�( )� K as a function of HIFC for TIFC � 40 and 70 K. h = 0.2 Oe0 H = 30 OeIFC T , KIFC A , ar b . u n it s 3 � 15 10 5 0 0 20 40 60 80 100 Fig. 6. Amplitude of the third harmonic A3� at H � 0 and T � 5 K versus TIFC . ferromagnets the internal magnetic field from spontaneous magnetization 4�M has the same effect on the phase dia- gram, i.e., on the magnetic flux penetrating into the sample, as the external field. This can be generalized in a more real- istic case of a multi-domain sample with nonzero average internal field � �4�M . On the basis of this argument we can use the third harmonic signal versus dc magnetic field de- pendence as a calibration curve to estimate the magnitude of the quenched internal magnetic field H I . Figure 7 presents the dependence of H I on H IFC . The phenomenon revealed in our experiment is possible if the domain structure formed in the ferromagnetic phase can be quenched down to the superconducting state. On the other hand, as was noted in the pioneer paper by Ginzburg [1] and confirmed by detailed analysis in [14], supercon- ductivity should strongly affect the equilibrium domain structure: its period should grow, and in the Meissner state any sample is a single domain in equilibrium. But in our case we deal with a nonequilibrium domain structure, which is a metastable state possible due to coercivity. The presence of the quenched internal field in the supercon- ducting phase clearly demonstrates that the sample is in the mixed state with many vortices in the bulk. One can hardly call this state as the spontaneous vortex phase be- cause the latter refer to the equilibrium state, but we deal with a metastable state. The nonlinear response is sensi- tive to the average internal field � �4�M . The absolute value of the average magnetization � �M is less than the saturation magnetization M, which can determine the vor- tex density in a single-domain sample. However, the satu- ration magnetization may create vortices inside domains. Since M changes its directions from a domain to a do- main, we obtain the vortex tangle, which does not contrib- ute to the average internal field � �4�M , studied here. This vortex tangle is expected to exist even after the ZFC pro- cess, and contributes to the initial value of the third har- monic, which was detected without external or internal magnetic field. These arguments illustrate that vorticity (magnetic flux) distribution in real especially ceramic superconducting ferromagnets can be very complicated. Genuinely zero-field cooling is practically impossible: if one cools a sample in zero external field, one cannot avoid an internal magnetic field from the spontaneous magnetization even if these fields vanish on average but still remain inside the domains. 4. Summary In summary, our measurements of the nonlinear re- sponse unambiguously demonstrates coexistence of the superconducring and ferromagnetic order parameters in Ru-1222 samples below superconducting critical temper- atures. Coexistence is manifested by the clear effect from the domain structure quenched from temperature above the superconducting critical temperatures on supercon- ducting properties. We have shown that the nonlinear de- pendence of the response of a sample on a variable mag- netic field manages to be understood qualitatively in all ranges of temperatures. The work was supported by the Klatchky foundation. The authors are deeply grateful to E. Galstyan for the sample preparation and useful discussions. 1. V.L. Ginzburg, Zh. Exp. Teor. Fiz. 31, 202 (1956) [Sov. Phys. JETP 4, 153 (1957)]. 2. V.P. Mineev, Int. J. Mod. Phys. B18, 2963 (2004); B. Lo- renz and C.-W. Chu, Nature Materials 4, 516 (2005); M. Faure and A.I. Buzdin, Phys. Rev. Lett. 94, 187202 (2005); N.A. Logoboy and E.B. Sonin, Phys. Rev. B75, 153206 (2007). 3. D.G. Naugle, K.D.D. Rathnayaka, V.B. Krasovitsky, B.I. Belevtsev, M.P. Anatskam, G. Agnolet, and I. Felner, J. Appl. Phys. 99, 08M501 (2006). 4. I. Felner, E. Galstyn, B. Lorenz, D. Cao, Y.S. Wang, Y.Y. Xue, and C.W. Chu, Phys. Rev. B67, 134506 (2003). 5. J.W.S. Rayleigh, Philos. Mag. 23, 225 (1887). 6. R.M. Bozorth, Ferromagnetism, D. Van Nostrand Com- pany, Inc., NY (1951). 7. S. Shatz, A. Shaulov, and Y. Yeshurun, Phys. Rev. B48, 13871 (1993). 8. T. Ishida, and R.B. Goldfarb, Phys. Rev. B41, 8937 (1990). 9. I. Felner, U. Asaf, Y. Levi, and O. Millo et al., Phys. Rev. B55, R3374 (1997). 10. C.A. Cardoso, Phys. Rev. B67, 020407(R) (2003). 11. G.I. Leviev, A. Pikovsky, and D.W. Cooke, Supercond. Sci. Technol. 5, 679 (1992). 12. M.V. Belodedov and V.K. Ignatjev, Supercond. Phys. Chem. Technol. 3, S24 (1990). 13. E.B. Sonin and I. Felner, Phys. Rev. B57, 14000 (1998). 14. E.B. Sonin, Phys. Rev. B66, 100504 (2002). 848 Fizika Nizkikh Temperatur, 2007, v. 33, No. 8 Grigory I. Leviev, Menachem I. Tsindlekht, Edouard B. Sonin, and Israel Felner H , OeIFC 0 50 100 150 H , O e I 50 40 30 20 10 0 40 K 70 K Fig. 7. Internal magnetic field versus HIFC for TIFC � 40 K and 70 K.

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