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Physica C

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PHYSICA C C
ELSEVIER

CONDUCTIVITY and Antiferromagnetism of CaCuO2 Thin Films Doped by Sr
Gennady A. Ovsyannikova,b*, Viktor V. Demidovb, Yuli V. Kislinskib, Philippe V. Komissinskia,b, Dag Winklera
a

Chalmers University of Technology, Department of Microtechnology and Nanoscience, SE-41296 Goteborg, Sweden
b

Institute of Radio Engineering and Electronics RAS, Mokhovaya 11 bld7, 125009 Moscow, Russia Elsevier use only: Received 15 June 2006; revised date here; accepted date here

Abstract The results of electrical and magnetic investigations of epitaxial CaxSr1-xCuO2 (CSCO) thin films grown by pulsed laser deposition are presented. The experimental temperature dependence of the CSCO film conductivity at low doping level is well described by the 3-d Mott insulator model over a wide temperature range (4.2-300K). A deviation from the model with changing of Sr concentration has been observed. The Neel temperature of the films, TN, was determined by Electron Paramagnetic Resonance technique. The comparison of the obtained TN value with the one previously obtained for the CSCO powder sample could be caused by oxygen vacancies in the CSCO films. YBa2Cu3O7-/Ca1-xSrxCuO2/Au/Nb heterostructures have been fabricated and superconducting current has been observed at low temperatures. © 2001 Elsevier Science. All rights reserved
Keywords cuprates, superconductivity, antiferromagnetic, Electron paramagnetic Resonance

1. Introduction The critical temperature of cuprate superconductors increases with a number of CuO2 layers in the unit cell [1]. Thus there is a great interest to study the materials with a large number of the CuO2 layers in the unit cell. The typical example is CaxSr1-xCuO2 (SCO), where CuO2 planes are divided by atoms sometimes replaced by Sr. This material represents a two-dimensional Heisenberg antiferromagnet with strong interlayer interaction Cu2+ at low temperature. 2. Experimental Epitaxial films of SCO with x=0, 0.15 and 0.5 were grown on (110)NdGaO3 substrates by laser ablation at 700-750° and 0.3-0.6 mBar of O2 pressure.The CSCO ------ * Corresponding author.

thin film growth technique is similar to YBa2Cu3Ox (YBCO) superconducting films [2]. Typical films thicknesses used are 100-200 nm. Heterostructures Nb/Au/CSCO/YBCO of the areas A=10в10-50в50 µm2 were fabricated by means of photolithography and Ar ion milling. During the processing SiO2 thin films were used as insulation layers to define the area of the heterostructures [2]. 3. Results and discussion The lattice constants of CSCO films were determined to a=b=0.3855 nm, c=0.318nm. The c-axis lattice parameter increased to c=0.323 nm for x=0.15. For the films with the small Sr content x<0.5 temperature dependences of conductivity correspond well to the model of three-dimensional hopping conductivity with the characteristic temperature of T0=(2-60) 106 K determined from the experiments (Fig.1). If N(Ef) = 1021,

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Physica C For the CSCO film with x = 0.15 the copper (Cu2+, S = 1/2) line was observed within the measured temperature range near-by a g-factor 2.8. The considerable suppression of the signal with temperature changing (Fig. 2) is related to the paramagnetic-antiferromagnetic transition. Thus the Neel temperature may be determined. There is a small growth of signal absorption within the temperature range from 300K to 130K, which is followed by a sharp drop of the signal at paramagnetic-antiferromagnetic transition. The Neel temperature obtained for the two CSCO films is in the range of 90-120. Considerable difference in the TN values from the data obtained by the neutrons scattering of the CSCO powder samples [5] is probably caused by large difference of the oxygen content both in CSCO films and the powder samples. The number of spins NCu ~ 4·1015 was estimated from EPR line. This value is close to the number of molecules in the Ca0.85Sr0.15CuO2 sample. Epitaxial multilayer thin film heterostructures of YBCO/CSCO/Au/Nb were fabricated and investigated at low temperatures, where CSCO films are in the antiferromagnetic state. X-ray diffraction technique and AFM microscopy were used to examine crystal structure and surface morphology of the heterostructures. Superconducting current with current density up to 200A/cm2 and ICRN200 µV was observed in the heterostructures with thickness of the CSCO layer up to 50 nm. This fact contradicts to the Bogolubov­De Gennes theory of superconducting proximity effect. From comparison of the properties of the YBCO/CSCO/Au/Nb and YBCO/Au/Nb heterostructures we have found that adding of the antiferromagnetic interlayer increases the ICRN product of the junctions by 3-4 times. In addition the period of the modulation of the Josephson current is about ten times smaller in the YBCO/CSCO/Au/Nb heterostructure than in the YBCO/Au/Nb ones. The work is partially supported by the Russian Academy of Sciences, project 05-02-1672; Russian Foundation for Basic Research, 04-02-16818; and by the President of Russian Federation Grants for School 7812.2006.2 and Young Researcher MK-2654.2005.2. References
[1] T. Siegrist, S.M. Zahurak, D.W. Murphy, R.S. Roth. Nature, 334, (1988) 231. [2] P.V.Komissinski, G.A. Ovsyannikov, Yu.V. Kislinski, I.M. Kotelyanski, Z.G. Ivanov, JEPT. 95, (2002) 1074 [3] X.M. Xie, C. Hattere, V.Mairet, C.F. Beuran, C. Coussot, C.D. Cavellin, B.Eustache, P.Laffez, X.Z.Xu, M.Lagues. App. Phys. Lett. 67, (1995)1671. [4] G.A. Ovsyannikov, S.A. Denisuk, Z. Ivanov. Physica C,408-410, (2004) 616 [5] D.Vaknin, E.Caignol, P.K. Davies, J.E. Fischer, D.C. Jonson, D.P. goshorn, Phys. Rev. B38, (1989) 9122

Fig.1. Temperature dependence of CSCO film resistance =0.15.

then the activating energy Ehop = kB T (T0/T)1/4=(0.2-0.5) eV, which at =300 is smaller than the dielectric gap determined by certain optical methods: E=1.5 eV [3]. In our thin CSCO films the hopping conductivity is replaced by a T-S dependence at high values of x ( 0.01 cm). Early the T-S dependence was observed in CSCO films with x=0.3-0.4 [4] and is typical for disordered electronic systems with high resistance at low temperatures. However no metallic temperature dependence of conductivity has been observed in our experiments at the high doping level (x0.5). In order to determine TN the EPR spectrums of the CSCO films in a temperature range of 80 ­ 300 were carried out. The standard Bruker spectrometer R 200 (9.56 GHz) with the modulation of the magnetic field at frequency of 100 kHz was used. The concentration of the paramagnetic centers was determined from comparison of the EPR line with the Mn2+ of the standard MgO:Mn sample placed in the same cryostat.

Fig.2. Temperature dependence EPR amplitude for two CSCO films with =0.15