C. Bonavolonta 1, 2 and C. de Lisio 1, 2 and M. Valentino 2 and F. Laviano 3 and G. P. Pepe 1, 2 and F. Kurth 4 and K. Iida 4, 5 and A. Ichinose 6 and I. Tsukada 6
Academic Editor:Prasenjit Guptasarma
1, Dipartimento di Fisica, Universita di Napoli Federico II, Via Cintia, Complesso di Monte S. Angelo, 80125 Napoli, Italy
2, CNR-SPIN, Via Cintia, Complesso di Monte S. Angelo, 80125 Napoli, Italy
3, Department of Applied Science and Technology, Politecnico di Torino, Corso Duca degli Abruzzi 24, 10129 Torino, Italy
4, Institute for Metallic Materials, IFW Dresden, 01171 Dresden, Germany
5, Department of Crystalline Materials Science, Nagoya University, Chikusa-ku, Nagoya 464-8603, Japan
6, Central Research Institute of Electric Power Industry, 2-6-1 Nagasaka, Yokosuka 240-0195, Japan
Received 15 March 2015; Revised 14 May 2015; Accepted 21 June 2015; 14 July 2015
This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Introduction
Recently, tremendous efforts have been made to obtain reliable information on fundamental properties of iron-based superconductors (IBS), such as superconducting energy gaps, nature of excitation assisting Cooper pair formation, and (ferro)magnetism. On the other hand, many applications based on Josephson effect have been proposed and realized, for example, Superconducting Quantum Interference Devices (SQUIDs) [1] and Single Flux Quantum (SFQ) devices.
Thin films are often preferred for applications in superconducting electronics, and, due to their controlled geometries, also for studying both transport and optical properties. Within the family of IBS, Co-doped BaFe2 As2 (Ba-122) thin films are among the most promising candidates for superconducting applications due their relatively easy fabrication through pulsed laser deposition [2-4].
In this work, we investigate magnetic and superconducting properties of Co-doped Ba-122 thin films with and without Fe buffer layer. We focussed our attention on the effect of an Fe buffer layer deposited on MgO (001) substrate by comparing the thin film behaviour with that of a similar film deposited on CaF2 substrate (without Fe layer). The Fe buffer layer acts as a strain absorber, leading to both sharp out-of-plane and in-plane texture [5-7]. However, its role is not yet completely clear. For example, it is not known how ferromagnetism due to the Fe buffer layer influences spin density waves (SDWs) and superconducting states of Ba-122. Optical techniques are very effective in isolating the contributions of different films to the overall sample properties: As an example, tuning the wavelength of incident radiation implies different penetration depths, thus allowing probing inner layers inside the material.
In particular, time-resolved spectroscopy is a suitable technique to study electronic excitations in superconductors, like IBS [8-10], since in the low-excitation regime different coexisting excitation/relaxation processes can be identified by their specific lifetimes [11, 12]. In IBS, ultrafast spectroscopy has been used to reveal the existence of pseudogap states [8], competition between SDWs and superconducting states [13] and to understand the role of interband interactions and gap symmetry [14]. Moreover, this technique ultrafast spectroscopy has been used to investigate quasiparticle (QP) dynamics in Ba-122 family, proving its ability to reveal the multigap nature of such superconductors [15].
We also report on additional characterization of Co-doped Ba-122 samples with magneto-optical imaging (MOI) and magneto-optical Kerr effect (MOKE). The magneto-optical Kerr effect (MOKE) technique reveals sample magnetization as a function of external magnetic field. It represents a powerful method to determine local magnetic properties of thin films [16]. In fact, unlike conventional techniques, such as vibrating sample magnetometer (VSM) and SQUID susceptometer [17], providing information on the average magnetization of the whole sample volume, this technique is simply implemented and capable of probing the sample magnetization with a spatial resolution limited by the laser beam spot size.
In addition, Atomic Force Microscopy (AFM), Transmission Electron Microscopy (TEM), and Energy Dispersive X-ray (EDX) analyses allowed us to determine both morphology and local analytical composition of Co-doped Ba-122 thin films, which is of particular interest in presence of the iron buffer layer.
Finally, by means of different optical techniques, namely, MOKE, MOI, and ultrafast spectroscopy, we could establish the role of Fe buffer layers on magnetic and superconducting properties of our Ba-122 samples.
2. Materials and Experimental Set-Up
In this work, we have studied two films, namely, Ba(Fe1-x Cox )2 As2 on Fe-buffered MgO substrate and Ba(Fe1-x Cox )2 As2 on bare CaF2 . From now on, these two samples shall be referred to as Ba-122/Fe and Ba-122. The estimated Co content in both samples was [figure omitted; refer to PDF] (optimal doping).
The Ba-122/Fe bilayer was prepared by pulsed laser deposition (PLD) on MgO substrate using a polycrystalline target with high phase purity. Ba-122 and Fe films were 100 nm and 20 nm thick, respectively. We then deposited 100 nm thick Ba-122 film on (001) CaF2 substrate.
In situ reflection high energy electron diffraction (RHEED) confirmed that both Fe and Co-doped Ba-122 films were epitaxially grown. Moreover, X-ray diffraction proves single phase formation of Co-doped Ba-122, whereas pole figure measurements further verify the epitaxial growth of Fe and Co-doped Ba-122 with the following relation: (001)[100]Ba-122 [figure omitted; refer to PDF] (001)[110]Fe [figure omitted; refer to PDF] (001)[100]MgO. More details about sample preparation can be found in [5-7].
Typically, growing epitaxial Co-doped Ba-122 thin films on bare MgO substrate leads to low quality superconducting films. As reported in [18], this is presumably due to the weak epitaxial strain connected to the film grain orientation, depending in turn on the thermal expansion coefficient of the substrates. However, we found that CaF2 proved to fulfil many requirements for growing epitaxial Ba-122 of good quality and without any buffer layer [5, 6]. On the other hand, mixing also occurs at Fe/CaF2 interface, giving rise to imperfect compounds [19]. Consequently, the comparison of Ba-122 film with Ba-122/Fe bilayer must necessarily be performed with different substrates. It has been demonstrated that these two samples showed almost the same crystalline quality and superconducting properties [5-7].
The superconducting transition temperatures of the Ba-122 and Ba-122/Fe thin films were measured by a 4-probe method and turned out to be 25.4 K and 26.3 K, respectively.
Using AFM and TEM analyses, both morphological properties and transverse sections of the bilayer have been investigated. TEM imaging supported by EDX analysis evidenced the different distribution of Ba, Fe, and As into the sample.
In order to investigate local magnetic properties of the samples, we recorded hysteresis loops based on longitudinal MOKE. The experimental set-up is reported in Figure 1. The He-Ne laser beam lies in the horizontal plane and its radiation is linearly polarized in the vertical direction by a Glan-Thompson (GT) polarizer with an extinction ratio of 10-6 . Due to geometrical constraints determined by the Helmholtz coils, the angle of incidence is about 20°. A 300 mm focal length lens focuses the light beam onto the sample surface. The reflected beam is modulated at 50 kHz frequency by a photoelastic modulator (PEM) (Hinds Instruments, mod. PEM-90). The modulated beam is then transmitted through a half-wave plate- (HWP-) polarizing beam-splitter (PBS) system and is finally detected by a fast responding diode-bridge detector (New Focus, mod. Nirvana 2007). The latter generates the input signal to a lock-in amplifier (EG&G, mod. 7260) whose reference signal is provided by the PEM driver electronics. A pair of Helmholtz coils powered by a bipolar power supply (Elind, mod. KL 1200) generates the external magnetic field up to 1 T. The magnetic field intensity is measured with a Hall sensor (Leybold, mod. 516-60) placed within the electromagnet gap, close to the sample surface. To perform low temperature measurements, the sample is placed on a cold finger inside a temperature controlled, liquid helium, continuous flow, optical cryostat operating down to 5 K.
Figure 1: MOKE set-up: GT: Glan-Thompson polarizer; HWP: half-wave plate; PEM: photoelastic modulator.
[figure omitted; refer to PDF]
Moreover, magnetic images of the samples were obtained by means of MOI technique, performed with an optical microscope equipped with polarization optics and a garnet indicator film [20]. In MOI pictures the light contrast is proportional to the out-of-plane magnetic field component (the brighter the contrast appears, the larger the normal component of the magnetic field is). The local magnetic moment of the sample is visualized in real-time, with microscopic resolution on the whole sample surface. Details of the technique are reported in [20]. The MOI technique achieves identification of the magnetic response in the temperature range 4 K-300 K with an applied magnetic field up to 0.2 T. In MOI pictures the light contrast is proportional to the out-of-plane magnetic field component (the brighter the contrast appears, the more intense the magnetic field pointing toward the reader is).
Additionally, time-resolved reflectivity measurements were performed using a standard pump-probe technique, based on a mode-locked Ti:Sa laser, delivering pulses at 82 MHz repetition rate, 100 fs duration, 800 mW average power, and 795 nm center wavelength. The sample was mounted in the same cryostat used for MOKE measurements. Further details on the experimental methods can be found in [21]. The photoinduced normalized reflectivity change [figure omitted; refer to PDF] , as a function of time, was measured using a pump fluence of 12 μ J/cm2 and 20 times weaker probe.
3. Results and Discussion
TEM analysis and AFM characterization of the Ba-122/Fe bilayer are reported in Figure 2. The AFM image (Figure 2(a)) shows some holes on the sample surface, indicating that the surface is not flat. This result is confirmed by the TEM image (Figure 2(b)), where the presence of holes on the superconductor surface is quite evident.
Figure 2: (a) AFM image (40 [figure omitted; refer to PDF] 40 μ m) of a Co-doped Ba-122 (100 nm)/Fe thin film and (b) TEM image of the same sample. The TEM image within the red square in (b) is enlarged in (c).
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
Moreover, the Ba-122 (100 nm)/Fe surface also presents considerable degradation, most likely due to direct exposure of the samples to the atmosphere. This effect has already been reported in literature [22], where an inhomogeneous and partially degraded surface layer in Fe-based pnictides was observed.
As reported in [23] the AFM measurement on Ba-122 sample on CaF2 substrate shows a typical multilayered surface with some smooth terraces.
An estimate of the holes dimensions (see Figure 2(b)) has been carried out. Their diameter is about 20-30 nm, whereas in some cases, the depth equals the superconductor thickness. In Table 1 the percentage of Fe, As, and Ba obtained by EDX analysis is reported. It must be noted that even close to the superconductor surface a large percentage (30%-40%) of Fe is still detected, probably due to its oxidation or diffusion during the fabrication process.
Table 1: EDX analysis relative to the white cross markers reported in Figure 2(c).
Position | Fe (at%) | As (at%) | Ba (at%) |
1 | 95.72 | 4.28 | - |
2 | 97.95 | 2.05 | - |
3 | 29.12 | 56.04 | 14.84 |
4 | 33.71 | 55.66 | 4.63 |
5 | 37.15 | 52.43 | 10.42 |
6 | 40.14 | 54.58 | 5.28 |
7 | 40.29 | 53.68 | 6.03 |
For determining magnetic properties of the samples with and without the Fe buffer layer, MOKE measurements at both room temperature and 5 K have been carried out.
Figure 3(a) reports the Kerr rotation, [figure omitted; refer to PDF] , as a function of the applied external magnetic field. It can be noted that the Ba-122/Fe sample (red and black squares) is characterized by hysteresis loop at both 300 K and 5 K (the latter temperature corresponds to the superconducting phase), while the Ba-122 sample (open squares) does not present any magnetization at room temperature or at 5 K (data at 5 K are not shown). This conclusion was verified for field intensities up to 1 T. These results clearly reveal the ferromagnetic behaviour of the Fe buffer layer.
Figure 3: (a) Hysteresis loops obtained by means of MOKE measurements: Ba-122/Fe at 5 K (red squares) and 300 K (black squares); Ba-122 thin film at 300 K (open squares); (b) MOI on Ba-122/Fe film at room temperature. Since MOI is sensitive to out-of-plane magnetic fields, the in-plane magnetization direction can be inferred from the signal at the edges (indicated by yellow arrows). (c) MOI at low temperature ( [figure omitted; refer to PDF] K), after Zero-Field Cooling (ZFC) with applied magnetic field [figure omitted; refer to PDF] mT; bright regions: preferential vortex penetration and normal zones; dark regions: screened zones.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
We also observed that the Ba-122/Fe sample presents smaller residual magnetization in the superconducting phase compared to the room temperature case, whereas the coercive fields remain quite the same (about 2.5 mT).
The smaller residual magnetization in the low temperature case can be explained as follows: Since the optical penetration depth into Ba-122 of radiation at [figure omitted; refer to PDF] nm wavelength is about 20-30 nm [24], it is reasonable to assume that the laser beam actually penetrates into the superconductor but is strongly absorbed before reaching the Fe buffer layer. On the other hand, taking into account the above-mentioned TEM analysis, we can argue that the laser beam focal spot (with a diameter of about 100 μ m) probes an area where several holes are present. From Figure 2(b), we can estimate that the total linear dimension of holes amounts to approximately 10% of the whole section length, corresponding to about 20% of the surface area. Thus, as a result of AFM and TEM analyses, we deduce that the MOKE signals from our samples consist of two main contributions: The first arises from the fraction ( [figure omitted; refer to PDF] 20%) of the laser beam cross section that directly hits the Fe buffer layer passing through the Ba-122 holes; such a contribution is expected to be temperature independent. The second is originated by the large Fe fraction (30-40%) detected close to the Ba-122 outer surface (within a laser beam penetration depth). As a consequence, the smaller residual magnetization observed at low temperature can be attributed to the Meissner effect occurring in the superconductor. This acts as a partial shield of the external magnetic field, which is, thus, unable to completely magnetize the fraction of Fe close to the sample outer surface.
In order to confirm this interpretation, MOI measurements have been performed at both low and room temperature. In MOI image at room temperature (Figure 3(b)), the magnetic field generated by the Fe buffer layer demonstrates its ferromagnetic nature and that the spontaneous magnetization lies in the film plane, in agreement with the MOKE hysteretic loop shown in Figure 3(a). On the other hand, the MOI pattern at low temperature (Figure 3(c)) shows the critical state of a disordered superconductor, with many laminar defects and grain boundaries, which are responsible for a disordered vortex distribution. However, the whole film is still superconducting, and a percolating zero-resistance state is even demonstrated by transport characterization [25]. Low contrast in the MOI image, corresponding to a weak critical current density, is unlikely due to the effect of the magnetic film which has in-plane anisotropy [26]. Therefore, from MOI analysis we can deduce that Ba-122 is not strongly affected by the underlying Fe magnetic film, but it rather presents a superconducting phase. However, in some regions of the surface the Meissner effect takes place and partially screens the magnetization of the Fe buffer layer.
In order to confirm the minor role of the Fe buffer layer on superconducting properties of Ba-122 thin films, we carried out transient reflectivity experiments at both 300 K and 20 K on Ba-122 (100 nm)/CaF2 , Ba-122 (100 nm)/Fe (20 nm)/MgO, and Fe (50 nm)/MgO thin films, respectively (see Figure 4).
Figure 4: Normalized transient reflectivity of Ba-122/CaF2 , Ba-122/Fe/MgO, and Fe/MgO thin films at 300 K (a) and 20 K (b); (c) the [figure omitted; refer to PDF] divergence-like behaviour for the two thin films. The solid lines represent the best fit of (1); inset: [figure omitted; refer to PDF] versus temperature for the same two films.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
First, we can assume that reflection from the Ba-122/Fe sample is essentially due to the upper Ba-122 thin film, since its thickness exceeds the optical penetration depth of laser radiation (~26 nm [24]). Moreover, it is worth noting that the transient reflectivity of the Fe/MgO thin film presents completely different relaxation dynamics as compared to other films at both 300 K and 20 K, namely, in the normal and superconducting phases, respectively (Figures 4(a)-4(b)).
We further investigated the influence of Fe buffer layer on superconducting behaviour. Transient reflectivity measurements with temperatures ranging from 5 K to 230 K, both below and above samples superconducting transition ( [figure omitted; refer to PDF] K), have been carried out. Transient reflectivity curves as a function of time following the excitation pulse are shown in Figures 4(a)-4(b). The experimental data have been fitted by a double exponential function in case of [figure omitted; refer to PDF] , whereas a single exponential fitting function has been used for temperatures above [figure omitted; refer to PDF] . The longest decay time, [figure omitted; refer to PDF] , in the nanosecond time-scale (only present for [figure omitted; refer to PDF] ) is reported as a function of temperature in Figure 4(c). On the contrary, the short relaxation time, [figure omitted; refer to PDF] , in the subpicosecond region, is observed throughout the entire range of temperatures. And its behaviour as a function of temperature is reported in the inset of Figure 4(c). However, since we are only interested in the superconducting phase, both relaxation times are showed for [figure omitted; refer to PDF] .
From Figure 4(c) we noticed that in the superconducting state ( [figure omitted; refer to PDF] ) both [figure omitted; refer to PDF] and [figure omitted; refer to PDF] rapidly increase as [figure omitted; refer to PDF] approaches [figure omitted; refer to PDF] . In particular, the variation of [figure omitted; refer to PDF] close to [figure omitted; refer to PDF] amounts to few tenths of femtosecond (inset of Figure 4(c)), whereas [figure omitted; refer to PDF] varies as much as 2 ps. This divergence-like behavior near [figure omitted; refer to PDF] typically occurs in the framework of quasiparticle (QP) recombination in a superconductor presenting a temperature dependent gap below [figure omitted; refer to PDF] [27], when the bottleneck regime takes place [12, 28]. The bottleneck effect consists in the creation of a large nonequilibrium phonon population, due to the emission of phonons by photoexcited electrons and holes, after absorption of a photon. In particular, phonons with energy exceeding the gap ( [figure omitted; refer to PDF] ) can subsequently excite QPs from the condensate, but these recombine again and so a bottleneck occurs, in which high frequency phonons are temporarily in quasi-equilibrium with QPs [29]. In such a framework, the QP recombination time can be expressed as [27] [figure omitted; refer to PDF] where [figure omitted; refer to PDF] is the laser pulse energy, [figure omitted; refer to PDF] the typical phonon frequency, [figure omitted; refer to PDF] the density of states (DOS), [figure omitted; refer to PDF] a characteristic phonon linewidth, and [figure omitted; refer to PDF] the superconducting gap with the BCS temperature dependence [27]. Thus, we fitted the experimental points of Figure 4(c) with (1) using [figure omitted; refer to PDF] and [figure omitted; refer to PDF] as fitting parameters. The solid black lines in Figure 4(c) are the results of the best fit for the two films Ba-122/Fe and Ba-122. It is worth noting the divergence predicted by (1) as the temperature approaches [figure omitted; refer to PDF] .
The best fitting values of the superconducting gap are [figure omitted; refer to PDF] meV and [figure omitted; refer to PDF] = ( [figure omitted; refer to PDF] ) meV for Ba-122/Fe and Ba-122 films, respectively, in agreement with the superconducting gap value estimated with different techniques [14, 30, 31]. Such an agreement also confirms our interpretation that in Ba-122 samples the relaxation channel associated with [figure omitted; refer to PDF] is described by the creation of high frequency phonon (bosons) with [figure omitted; refer to PDF] . These phonons, in turn, break additional Cooper pairs and, hence, inhibit QP recombination. On the other hand, the superconducting gap [figure omitted; refer to PDF] estimated for Ba-122/Fe is larger compared to the sample without the Fe buffer layer, which implies that the Fe buffer layer affects the Fermi surface without destroying superconductivity. It is worth mentioning that a complete transient reflectivity data analysis concerning the Ba-122/Fe superconducting samples evidenced the presence of two gaps, as reported elsewhere [15].
4. Conclusions
In this work the analysis of Co-doped Ba-122 with and without Fe buffer layer is reported. AFM and TEM measurements demonstrate an irregular surface morphology in the Ba-122 thin film in presence of Fe buffer layer. MOKE analysis shows the ferromagnetic nature of the sample (from room temperature down to 5 K) due to the presence of Fe, confirmed by the independence of coercive field from temperature. On the contrary, the Ba-122 thin film without Fe buffer layer does not present any hysteresis loop (up to 1 T). This result is confirmed by MOI characterization that showed the coexistence of ferromagnetism of the Fe buffer layer with superconductivity of the Ba-122 film. The pump-probe spectroscopy confirms that the Fe buffer layer does not alter the superconducting properties of the Ba-122 thin film. In particular, the superconducting gap of Ba-122/Fe resulted in being slightly larger than the Ba-122 layer. In conclusion, the presence of the Fe buffer layer does not modify the superconducting properties under our deposition condition while allowing a bilayer with both superconducting and ferromagnetic properties. This result could be noteworthy in the field of electronic applications.
Acknowledgment
The authors acknowledge the financial support of the EU (Iron-Sea under Project no. FP7-283141).
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
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Abstract
A systematic characterization of Co-doped BaFe2As2 (Ba-122) thin films has been carried out. Two samples were available, one grown on CaF2 substrate and the other on MgO with an Fe buffer layer. The goal was to investigate films' magnetic and superconducting properties, their reciprocal interplay, and the role played by the Fe buffer layer in modifying them. Morphological characterization and Energy Dispersive X-ray analyses on the Fe-buffered sample demonstrate the presence of diffused Fe close to the Co-doped Ba-122 outer surface as well as irregular holes in the overlying superconducting film. These results account for hysteresis loops obtained with magneto-optic Kerr effect measurements and observed at both room and low temperatures. The magnetic pattern was visualized by magneto-optical imaging with an indicator film. Moreover, we investigated the onset of superconductivity through a measure of the superconducting energy gap. The latter is strictly related to the decay time of the excitation produced by an ultrashort laser pulse and has been determined in a pump-probe transient reflectivity experiment. A comparison of results relative to Co-doped Ba-122 thin films with and without Fe buffer layer is finally reported.
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