Abstract
A series of quasi-multilayers of YBa2Cu3O7−δ (YBCO)/Y2O3 specifically 70 × (m YBCO/n Y2O3) were prepared on SrTiO3 single crystal using pulsed-laser deposition (PLD) with a controlled deposition pulses of m = 40 and n = 2, 5, and 10 for YBCO and Y2O3, respectively. The x-ray diffraction patterns indicate that all the present quasi-multilayers exhibit good c-axis orientation. The angular dependence of critical current density (J c ) on applied magnetic field directions are systemically measured to study the anisotropic vortex pinning performances for those quasi-multilayers. It is revealed that compared with the pure YBCO films, the quasi-multilayers with n = 2, i.e., a proper constituent pulse of Y2O3, exhibits the enhanced vortex pinning abilities in all angles between c-axis orientation and the applied magnetic field direction. As well, such a quasi-multilayer film (n = 2) shows the higher lift factor J c (Θ)/ J c (90°) and much better vortex pinning properties at high fields and high temperatures, showing promising potential for coated conductor application.
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1 Introduction
The coated conductors (CCs) based on epitaxial REBa2 Cu3O7−δ (rare earth (RE); Y, Gd Sm, etc.) possess high critical current density (J c) values at liquid nitrogen temperature (77 K) and self-filed. For technical applications, it is necessary to enhance in-field J c of coated conductors. In the past decade, vortex pinning issue has been one of the most important keys for coated conductors. There are several types of crystalline defects that can act as pinning centers, such as non-superconducting phases, dislocations, vacancies, grain boundaries, and twins [1]. Substrate decoration, secondary phases, multilayers with ultrathin interlayers, and various artificial pinning centers (APCs) have been also suggested and evidenced to be effective to enhance RBa2Cu3O7−δ thin films performance [2,3,4].
Recently, different approaches have been proposed to improve the REBCO film in-field performance. It is revealed that the growth controlling of RE2O3 is a typical way to deposit multilayers or quasi-multilayers, which normally results in a high density of APCs [5,6,7,8,9,10,11,12]. The measurement of field angular dependence of J c (H) in REBCO films is an important way to characterize the anisotropic properties of flux pinning centers. The J c decreases significantly as the magnetic field is applied from the parallel direction with c-axis to the perpendicular direction with c-axis. As the nanoparticles are insufficient and uncorrelated along c-axis, the J c angular dependence appear anisotropic without the peak modified at B//c [13].
In the present work, a series of growth-controlled quasi-multilayers consisting of YBa2Cu3O7−δ (YBCO) and Y2O3 are prepared. Electrotransport measurements were made at different applied directions of magnetic fields (H), characterized by the angles (Θ) between the c-axis orientation and magnetic field direction. A methodology based on angular-dependent J c measurement is proposed to identify the in-field properties and the effect of the artificial defects.
2 Experimental
Quasi-multilayers namely, p × (m YBCO/ n Y 2O3) were fabricated on (100) SrTiO3 single crystal through pulse laser deposition (PLD with a KrF excimer laser (λ = 248 nm, Lambda Physik), where m and n denote the number of laser pulses on YBCO and Y2O3, respectively, and p is the periodic number. The laser ran at a repetition rate of 5 Hz and an energy density of 2.4 J/cm2. Commercial stoichiometric YBCO and Y2O3 targets and standard deposition conditions for YBCO were applied, with a heating temperature of 820 °C, a background pressure of 0.3 mbar O2, and oxygen loading under 400 mbar. The growth rates of YBCO and Y2O3 were around 1 and 0.4 Å per pulse, respectively. After each m = 40 pulses on YBCO target, Y2O3 target was set into position and a certain number of pulses (n = 2, 5 and 10) were deposited. This was repeated 70 times (p = 70). Hence, 40 pulses of YBCO produced roughly 3.4 unit cells, while 2–10 pulses of Y2O3 were assumed as incomplete layers of 0.075–0.375 unit cells. This results in a so-called quasi-multilayer, consisting of a YBCO film matrix and an island-like Y2O3 nanoparticles. A pure YBCO film as a reference sample was prepared using the same conditions. The thickness of YBCO is around 280 nm for each sample.
The texture was determined by x-ray diffraction (XRD). J c was measured in various fields up to 9 T with a Quantum Design PPMS system by standard four-probe method on a bridge of 0.8 mm length and 50 μ m width. The angular dependence of J c was measured in a maximum force configuration, i.e., the sample was rotated around the current axis to achieve various angles Θ between the c-axis orientation and the magnetic field direction. The critical current density was determined by an electric field criterion of E c = 1 μ V/cm.
3 Results and Discussion
Figure 1 shows the XRD patterns of pure YBCO film (n = 0) and YBCO/Y2O3 quasi-multilayers (n = 2, 5, 10), YBCO (00 l) indicating good c-axis orientation for YBCO, and the absence of other extra peaks except Y2O3 reflections confirm the phase purity. The intensity of Y2O3 increases with the used pulse number. The above phenomenon is due to good chemical stability and lattice matching between Y2O3 and YBCO.
The self-field critical current density (J c s ) of YBCO/Y2 O3 quasi-multilayers (n = 2, 5, 10), about 2.6, 2.3 and 2.1 MA/cm2, respectively. As shown in Fig. 2, although their J c s are a little lower than that of the pure YBCO sample which is about 3.6 MA/cm2, the magnetic field dependence of J c for the pure YBCO film (n = 0) and the YBCO/Y2O3 quasi-multilayer (n = 2) at 77 K are much different. It implies that the enhanced flux pinning occurs due to the proper Y2O3 doping at high fields, giving rise to a crossover behavior. The crossover behavior at logarithmic coordinate diagram of the J c H is frequently observed in case of low-doped YBCO films. That means it might be difficult to improve J c in the whole range of magnetic fields using precipitates. In films with nanoparticles, it is reported that the irreversibility field H irr may be improved, while the self-field J c value is reduced due to lower T c values or disturbed crystallinity [14, 15]. The crossover behavior of the J c − H can be understood from the difference in H irr (T = 0 K). If the H irr is increased, J c (H) is in most cases reduced in the range of several thousands of Oersted with the crossover behavior described above.
We compared the angular-dependent vortex pinning properties of YBa2Cu3O7−δ/Y2O3 quasi-multilayers. As shown in Fig. 3 we found that J c (Θ)/ J c (90°) of YBCO/Y2O3 quasi-multilayer (n = 2) is clearly enhanced compared with pure YBCO in all angles, indicating a contribution of Y2O3 doping to flux pinning even at high temperature and high fields. However, when n = 5 to 10 the enhancement of the J c (Θ)/ J c (90°) for YBCO/Y2O3 quasi-multilayers are not obvious. The films with a high content of Y2O3 (n = 5, 10) hardly demonstrate the doping contribution to flux pinning, due to no pronounced increase in H irr at this temperature. Those films with lower H irr(T = 0 K) may easily switch to the flux-flow phase, leading to lower flux pinning force, even though the amount of potential pinning centers are sufficient enough [15].
The anisotropic defects may modify the J c , depending on the angle between the directions of applied field and transport current. In case of H//ab, the pinning source mainly arise from the intrinsic (a,b) plane pinning associated with the periodic modulation of the order parameter, i.e., the layered structure of YBCO. In case of H//c, the c-axis peak of J c (H) is mainly attributed to correlated defect [16]. To further investigate the flux pinning characteristics in those quasi-multilayers with different doping levels, the angular dependence of J c in various applied magnetic fields from 0.25 to 5 T are measured. Figure 4 shows the angulardependent J c (Θ)/ J c (90°) for the YBCO/Y2O3 quasi-multilayers with the n = 2, 5, and 10 at 77 K in the magnetic fields of 0.25, 1, 3 and 5 T, respectively. All the curves of angular dependence present a main strong peak at H//ab which is attributed mainly to intrinsic pinning including defects parallel to (a, b) planes like linear or planar defects. In contrast, a second weak peak can be observed at H//c in case of n = 2, which may emerge from the correlated defects parallel to c-axis [17,18,19,20].
One may estimate the intrinsic flux pinning contribution to J c according to the model of Tachiki and Takahashi, giving J c (Θ) = J c (0)|cos Θ|−0.5 [21]. An example for μ H = 1 T and T = 77 K is shown in Fig. 5. The model shows a good fit for the angles around 90° or 270°. In view of isotropic defects and mass anisotropy, however, an obvious difference emerged at the region of H||c. The discrepancy at this region suggests that there may exist correlated defects along the c-axis. The c-axis correlated defects are assumed to be either interface or lattice mismatch between YBCO and Y2O3 The Y2O3 particles are evenly distributed on the quasi-multilayer plane and produce a certain stress field. The Y2O3 particles and dislocation due to the stress field may act as strong flux-pinning centers. Thus, Y2O3 particles enhance J c of low-doped quasi-multilayer films at magnetic fields.
Moreover, the crossover behavior shows the diversity of flux pinning effect for YBCO/Y2O3 quasi-multilayer (n = 2) at different magnetic fields. As shown in Fig. 6, the lift factor defined as J c (180°)/ J c (90°) mostly reduced by increasing magnetic fields. It is revealed that the sample with n = 2 shows a higher lift factor than other samples in all studied fields, and the lift factor achieved the highest value when the magnetism is 14 Oe. It means that at 104 Oe the vortex pinning reach saturation. For the case of n = 5 and 10, a high level of doping, the increasing Y2O3 defects degraded the superconducting components too much, leading to the hardly remarkable vortex pinning properties.
4 Conclusion
In summary, we have successfully fabricated a series of quasi-multilayers of YBCO/Y2O3 by using the intermediated pulsed laser deposition. The θ2θ diffraction pattern indicates the good c-axis orientation of YBCO, showing no additional phases for all the present YBCO/Y2O3 quasi-multilayers. Our results revealed that growth controlling of secondary phase (Y2O3) appears hard to introduce an effective vortex pinning at high fields and high temperature, while the J c (Θ)/ J c (90°) of quasi-multilayers is clearly enhanced compared with pure YBCO in all angles. Especially at the case of n = 2 the YBCO/Y2O3 quasi-multilayer film exhibits anisotropic correlated defects demonstrating the optimized angular-dependent vortex pinning properties and potential power application for coated conductors.
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Acknowledgements
This work was supported in part by National Program on Key Basic Research Project (2016YFF0101701); the Science and Technology Commission of Shanghai Municipality (16521108400, 16DZ0504300 and 14521102800); and the National Natural Science Foundation of China (51572165 and 51202141).
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Zhong, H.X., Liu, X.M., Boubeche, M. et al. Angular-Dependent Vortex Pinning Properties of YBa2Cu3O7−δ /Y2O3 Quasi-Multilayers. J Supercond Nov Magn 31, 55–59 (2018). https://doi.org/10.1007/s10948-017-4195-1
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DOI: https://doi.org/10.1007/s10948-017-4195-1