Abstract
Interfacial exchange coupling and magnetization reversal characteristics in the perpendicular heterostructures consisting of an amorphous ferrimagnetic (FI) TbxCo100–x alloy layer exchange-coupled with a ferromagnetic (FM) [Co/Ni]N multilayer have been investigated. As compared with pure TbxCo100–x alloy, the magnetization compensation composition of the heterostructures shift to a higher Tb content, implying Co/Ni also serves to compensate the Tb moment in TbCo layer. The net magnetization switching field Hc⊥ and interlayer interfacial coupling field Hex, are not only sensitive to the magnetization and thickness of the switched TbxCo100–x or [Co/Ni]N layer, but also to the perpendicular magnetic anisotropy strength of the pinning layer. By tuning the layer structure we achieve simultaneously both large Hc⊥ = 1.31 T and Hex = 2.19 T. These results, in addition to the fundamental interest, are important to understanding of the interfacial coupling interaction in the FM/FI heterostructures, which could offer the guiding of potential applications in heat-assisted magnetic recording or all-optical switching recording technique.
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Introduction
In the past years, extensive work has been devoted to the heterostructures with a ferromagnetic (FM) /antiferromagnetic (AFM) exchange coupling interface1,2,3,4,5,6. The exchange bias effect7, arising from the interfacial unidirectional anisotropy and displaying a shift along the magnetic field axis of the magnetic hysteresis loop, has been employed in giant magnetoresistance (GMR) devices for magnetic data storage applications8,9,10. Recently, with great demand for increasing storage density, new writing technique such as heat-assisted magnetic recording (HAMR)10,11,12 and all-optical switching (AOS)13,14 have received much attention, which intrigues great interest in seeking perpendicular exchange-coupled heterostructures with strong and temperature (T) sensitive interfacial AFM exchange coupling. However, in previous studies, most of the exchange-coupled heterostructures with perpendicular magnetic anisotropy (PMA) are restricted to a FM layer antiferromagnetically coupled with an AFM layer such as MnIr or FeMn, for which the room temperature (RT) coupling field (Hex) is usually below 0.1 T3,4,5,6, apparently cannot meet the practical requirements of future high density data storage.
It is known that in ferrimagnetic (FI) rare earth-transition metal (RE-TM) alloy films, there are two types of pair interactions: antiparallel exchange between the RE-TM moments and parallel exchange of the TM moments themselves, both interactions would greatly enhance the coupling strength12,14,15,16,17,18. Moreover, amorphous ferrimagnetic RE-TM films such as TbCo or TbFe can exhibit strong PMA when the antiferromagnetically coupled magnetic moments of RE and TM are nearly balanced by controlling the element composition or measurement temperature19. As a result, a perpendicular heterostructure consisting of a FM layer in contact with a FI alloy layer can owns not only low stray field, but also strong, tunable and T-dependent interfacial coupling and net magnetization switching fields (Hc⊥)20,21. Such FI-based heterostructures might possess potential applications in HAMR and AOS, since its large and temperature-sensitive Hc⊥ and Hex can be used to store information while the strongly coupled FM layer can improve the properties of readout. Therefore, understanding and clarifying the related coupling and switching mechanism in the FM/FI heterostructures should be of great importance for ultrahigh density recording in these new storage techniques.
Due to the great potential applications in data storage technology, in recent years some research work has been performed regarding the FM/FI composite structures12,15,16,17. For instance, S. Romer et al. investigated the temperature dependence of large exchange bias effect in TbFe/[Co/Pt] system12. The dependence of interfacial exchange coupling on the stoichiometry of TbFe layer and repetition numbers of Co/Pt was analyzed by C. Schubert et al.17. However, the net magnetization switching properties were not well analyzed in these studies. Moreover, except Co/Pt (Pd) multilayer, no other FM layer material has been employed. In our previous work, the [Co/Ni]N multilayer has been employed to couple with TbCo as the reference layer of perpendicular spin valves, by which we have achieved high GMR signal and large switching plateau20. The Co/Ni multilayer, which owns relatively higher spin polarization and smaller Gilbert damping factor than Co/Pt, has been considered as a potential material in MRAMs for high spin torque efficiency22. In order to thoroughly understand the interfacial exchange coupling, magnetization reversal and their relationship in FM/FI heterostructures, in this work we have fabricated several series of samples of glass /Ta(3) /Cu(3) /[Co(0.28)/Ni(0.58)]N /Co(tCo) /TbxCo100–x(t) /Ta(5) (layer thickness in unit of nm). The influences of Tb contents x, Co/Ni repetition number N and thicknesses (tCo and t) of the additional Co and TbCo layers will be discussed. Note that for all these samples the easy axes of both the FI TbCo and FM [Co/Ni]N layers are maintained perpendicular to the film plane.
Results
Figure 1 displays the out-of-plane magnetic hysteresis loops measured by Physical Property Measurement System (PPMS) for the heterostructure samples of [Co/Ni]5/TbxCo100–x (12) with various Tb content x. As defined in the loops, the magnetic coercivity Hc⊥ in the central loop corresponds to the total net magnetic moment switching, while the antiferromagnetic coupling field Hex denotes the magnetization switching of either TbCo or Co/Ni layer that has lower magnetic moment. Clearly, for different x the loops exhibit different Hex and Hc⊥. Especially for x = 33.0%, no central switching loop can be detected, indicating that the magnetization of 12-nm thick Tb33Co67 layer is balanced with that of Co/Ni and thus the sample has nearly zero net magnetic moment.
In order to clearly see the variation trends, Tb content dependence of Hc⊥ and Hex are shown in Fig. 2, the Hc⊥ values of pure TbxCo100–x are also given for comparison. Note that, for the pure TbCo alloy film, the Hc⊥ firstly increases with increasing Tb content, at x ≈ 22% it starts to decrease. It is noticed that the largest Hc⊥ occurs when the magnetic moments of Tb and Co are approaching compensated according to the inverse relation to the magnetization23,
where Keff and Mnet denote the effective magnetic anisotropy and net saturation magnetization of the heterostructure, respectively. As a result, for our 12-nm thick TbCo film, the magnetization compensation composition at RT is approximately 22%. Interestingly, for the perpendicularly exchange-coupled [Co/Ni]5/TbCo composite film, a similar relationship between Tb content and Hc⊥ happens. Nevertheless, the RT compensation composition has been moved to a higher Tb content of x ≈ 33%, verifying that the Co/Ni atoms also serve to compensate the magnetic moment of Tb atoms in the Tb-rich TbCo layer20,21. Therefore, for x < 33%, the heterostructure is [Co/Ni]5 rich in magnetic moment and the Hex comes from magnetization switching of the TbCo layer. On the contrary, for x > 33% it becomes TbCo rich and the Hex corresponds to the switching field of Co/Ni multilayer. As shown in Fig. 2(b), the Hex reaches a value as high as 3.22 T at x = 25.5%, significantly larger than the exchange field observed in normal FM/AFM systems. With the increase of x, it firstly decreases rapidly until x reaches the compensation point, after that it becomes nearly stable. The observed Hex tendency of the heterostructure can be well interpreted by the following formula17,24,
where Jex is the interlayer coupling strength, Ms and t represent the saturation magnetization and thickness of the switched layer, while Kp is the magnetic anisotropy energy of the pinning layer, respectively. At x < 33%, the TbCo layer is switched since it has a lower moment than the Co/Ni layer, so the strong decrease of Hex with the increase of x is mainly caused by the increased magnetization of TbCo layer. At x > 33%, the Co/Ni layer is switched, further increase of Tb content will only affect the Kp of TbCo slightly25, thus giving rise to the observed slight reduction of Hex.
Considering that the Tb moment enlarges much more rapidly than the transition metal as the measurement temperature decreases, the Hc⊥ and Hex will have different temperature-dependent variation trends for samples with different Tb contents, which can be clearly seen in Fig. (3). As shown in Fig. 3(a), the Hc⊥ value for x = 25.5% decreases slowly with the increase of temperature when T is below 200 K, above which it drops dramatically. Here T = 200 K is the transition point of magnetization compensation temperature (TMcomp) for the sample of x = 25.5%, i.e. the sample is Co/Ni rich at T > TMcomp and TbCo rich as T < TMcomp. According to our analyses in the preceding parts, maximum Hc⊥ should take place at the TMcomp where magnetic moments are compensated. However, the Hc⊥ value keeps increasing as T decreases from 200 K to 50 K, we attribute this increase to the enhanced PMA strength of TbCo pinning layer at reduced temperatures. For the x = 30.0% sample the temperature dependence of Hc⊥ is similar to that of x = 25.5% case, except that it has a higher TMcomp of about 260 K. However, for the sample of x = 33.0% which has a TMcomp of RT, the varying trend of Hc⊥ is distinctly different from the other two samples. Instead of a monotonic slow increase as T decreases from TMcomp = RT, the Hc⊥ value firstly decreases and subsequently increases after reaching a minimum at about 200 K. We attribute such behavior to the combined action of enhanced PMA strength and net magnetic moment. The initial decrease of Hc⊥ originates from the enlarged uncompensated moment of the heterostructure due to the much rapidly increased Tb moment in TbCo layer, whereas with further decreasing temperature the PMA enhancement plays a dominant role which leads to the slow increasing behavior, similar to the varying trend of samples of x = 25.5% and 30.0% at T < 200 K. Interestingly, as shown in Fig. 3(b), the Hex value at T = TMcom is always the smallest for all the three samples. The fast increase of Hex with T at T > TMcomp can be ascribed to the reduced magnetization of TbCo switched layer. Nevertheless, at T < TMcomp the switching field change of Co/Ni layer is very likely related to the enhanced PMA of TbCo pinning layer.
In addition to the Tb content, the TbCo layer thickness also plays an important role on the magnetization switching of [Co/Ni]5/TbCo heterostructures. Figure 4(a) shows the Hc⊥ and Hex values for samples with a fixed Tb content of x = 30.0% but various Tb30Co70 layer thicknesses. Three representative out-of-plane magnetic loops of t = 8.0, 13.5 and 20 nm, measured by Vibrating Sample Magnetometer (VSM), are inserted in Fig. 4(a). With the increase of Tb30Co70 thickness, we find the Hc⊥ varies also non-monotonically. It firstly increases with increasing t and then begins to decrease at t = 13.5 nm, which means that t ≈ 13.5 nm is the magnetization compensation thickness for the [Co0.28/Ni0.58]5/Tb30Co70 (t) heterostructure. Meanwhile, no central switching loop takes place from the magnetic hysteresis loop of t = 13.5 nm sample, confirming that the total net magnetic moment is compensated. Accompanied with the change of Hc⊥, the exchange coupling field Hex also varies but in a different way. At t <13.5 nm, the sample is Co/Ni rich, so the coupling field comes from the TbCo layer switching, which certainly increases with the decrease of TbCo layer thickness. As soon as t is over 13.5 nm, the Co/Ni layer with fixed magnetization and thickness will be switched. Therefore, owing to the increased PMA of thicker TbCo layer, the Hex exhibits a weak increase. Note that the Hex value for the samples of t <12 nm is not given here because it is far beyond the highest magnetic field of 2.2 T supplied by our VSM. Figure 4 (b) shows the remanent net magnetization (Mnet) values as a function of Tb30Co70 thickness. As expected, starting from the compensation thickness, the Mnet increases from zero towards both thicker and thinner Tb30Co70 layers. By using the following equation of Mnet = (Ms–FMtFM-Ms–FItFI)/(tFM + tFI), we obtain the Co/Ni magnetization of Ms–FM = 596 ± 45 kA/m and Tb30Co70 of Ms–FI = 183 ± 15 kA/m, which are in good agreement with the measured values (604 kA/m for [Co0.28/Ni0.58]5 and 176 kA/m for Tb30Co70). Based on these results, we calculate the interfacial coupling strength Jex is up to 4.4 ± 0.3 mJ/m2, such magnitude is comparable to the value found in other exchange-coupled FI/FM structures12,17, but greatly higher than that of the FM/AFM systems.
Furthermore, we selected 12 nm-thick Tb30Co70 as the switching layer and investigated the PMA effect of the FM pinning layer on the Hex and Hc⊥. The perpendicular anisotropy energy Kp of the FM pinning layer was firstly modulated by changing the repetition number N of the [Co/Ni]N multilayer. Figure 5(a) shows the Hc⊥ and Hex of the heterostructure, as well as the effective uniaxial anisotropy energy Kp of the single Co/Ni layer as a function of N for the [Co/Ni]N/Tb30Co70 (12.0) samples. The Kp was calculated according to Kp = MsHk/2, where Hk is the saturation magnetic field of in-plane magnetic loops. Apparently, the Kp increases monotonically with N due to the increased Co/Ni interfaces. From the maximum Hc⊥ we can conclude that the magnetization is compensated at N = 4. Therefore, the magnetization of Co/Ni is dominant and the TbCo layer will be switched at N > 4. Although the magnetization and layer thickness of TbCo layer are fixed, we can still see an obvious Hex increase, which can be ascribed to the enhanced Kp of the FM layer. By optimizing the layer structure, we achieved large Hc⊥ up to 1.31 T and Hex of 2.19 T simultaneously at the N = 4 case, which will be of great importance for practical applications. In addition, the PMA strength of Co/Ni layer was manipulated by tuning the thickness of an additional Co interlayer inserted between the [Co/Ni]5 and Tb30Co70 (12.0) layers as well. The interlayer Co thickness tCo is kept below 1.2 nm to ensure the easy axis of Co/Ni along perpendicular direction. A maximum Kp occurs at tCo = 0.28 nm, further increasing tCo will give rise to Kp decrease. Such non-monotonic variation is the result of competition between the interfacial PMA and in-plane shape anisotropy. For this sample structure, the net magnetization is always dominated by [Co/Ni]/Co and increases with tCo, thus leading to the monotonic reduction of Hc⊥, as shown in Fig. 5(b). Meanwhile, the Hex follows a similar variation trend to the Kp, again demonstrating that the exchange coupling field is strongly dependent on Kp of the pinning layer.
In conclusion, we have investigated the antiferromagnetic exchange coupling interactions and net magnetization switching in perpendicular [Co/Ni]N/TbCo composite structures. The magnetization compensation composition, compensation thickness of FM or FI layer, as well as compensation temperature for the coupled heterostructures have been clarified. By controlling the magnetization, thickness and PMA strength of the FM and FI layers, a wide range of variation in both net magnetization switching field Hc⊥ and exchange coupling field Hex are realized. The calculated interfacial coupling strength at RT is as strong as 4.4 ± 0.3 mJ/m2, leading to a large Hex value even exceeding 3.0 T, which is significantly higher than the normal FM/AFM systems. These results offer us valuable information for practical applications in data storage technology and profound understanding of the fundamental exchange coupling mechanism.
Methods
Different series of samples, in a structure of glass/Ta(3)/Cu(3)/[Co0.28/Ni0.58]N/Co (tCo)/TbxCo100–x (12)/Ta(5) (layer thickness in unit of nm), were deposited sequentially at ambient temperature in a Kurt J. Lesker magnetron sputter system with a base pressure better than 1 × 10−8 Torr. The TbCo alloy layer was fabricated by co-sputtering from pure Tb and Co targets, their relative atomic concentration was controlled by varying the sputtering power of Tb and determined by X-ray Photoelectron Spectroscopy (XPS). Magnetic properties were characterized by Vibrating Sample Magnetometer and Physical Property Measurement System.
Additional Information
How to cite this article: Tang, M. H. et al. Interfacial exchange coupling and magnetization reversal in perpendicular [Co/Ni]N /TbCo composite structures. Sci. Rep. 5, 10863; doi: 10.1038/srep10863 (2015).
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Acknowledgements
This work is supported by the National Basic Research Program of China (No. 2014CB921104), the National Natural Science Foundation of China (Grant Nos. 11474047, 51222103, 11274113 and 51171047) and the Program for New Century Excellent Talents in University (NCET-12-0132).
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Z.Z.Z. and Q.Y.J. conceived and supervised the study. M.H.T. fabricated the samples and performed the VSM and XPS measurements. S.Y.T. and J.W. performed the PPMS experiments. Z.Z.Z. and M.H.T. analyzed the data and wrote the paper. All authors discussed the results and commented on the manuscript.
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Tang, M., Zhang, Z., Tian, S. et al. Interfacial exchange coupling and magnetization reversal in perpendicular [Co/Ni]N/TbCo composite structures. Sci Rep 5, 10863 (2015). https://doi.org/10.1038/srep10863
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DOI: https://doi.org/10.1038/srep10863
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