Tuning the magnetic properties of multisegmented Ni/Cu electrodeposited nanowires with controllable Ni lengths

Susano, M.; Proença, Mariana P.; Moraes, Suellen Silveira; Sousa, C. T.; Araújo, João P.

doi:10.1088/0957-4484/27/33/335301

Cited by 45 publications

(34 citation statements)

References 44 publications

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“…In addition, the concentration of Cu in the ferromagnetic alloy is very low. This agrees with previous assumptions that, when using low concentrations of Cu in the electrodeposicion solution, the amount of Cu that incorporate to the layers when applying the FeCo activation voltage is very small and do not significantly change the magnetic properties of FeCo alloys [21,23].…”

Section: Samplesupporting

confidence: 92%

“…Therefore, using a template process in the electrochemical deposition is an excellent method to grow NWs and enables the tuning of the composition and the morphology of multisegmented structures [14] [15,16,17]. Segmented NWs with a magnetic/nonmagnetic mutilayered structure grown by pulsed electrodeposition have been highly investigated in the last years: Co/Cu [18,19,20], Ni/Cu [21,22,23] [24], Fe/Cu [25,26], CoFeB/Cu [27], CoFe/Cu [28,29,30], CoNi/Cu [31,14], CoPt/Pt [32], CoFe/Au [33], Ni/Au [34,35], etc.. Most of these works aim the application of spin valves and the exploration of the giant magnetoresistance effect [36] [37,38].…”

Section: Introductionmentioning

confidence: 99%

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Magnetic behaviour of multisegmented FeCoCu/Cu electrodeposited nanowires

Núñez

Pérez

Abuín

et al. 2017

J. Phys. D: Appl. Phys.

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Understanding the magnetic behaviour of multisegmented nanowires (NWs) is a major key for the application of such structures in future devices. In this work, magnetic/non-magnetic arrays of FeCoCu/Cu multilayered NWs electrodeposited in nanoporous alumina templates are studied. Contrarily to most reports on multilayered NWs, the magnetic layer thickness was kept constant (30 nm) and only the non-magnetic layer thickness was changed (0 to 80 nm). This allowed us to tune the interwire and intrawire interactions between the magnetic layers in the NW array creating a three-dimensional (3D) magnetic system without the need to change the template characteristics. Magnetic hysteresis loops, measured with the applied field parallel and perpendicular to the NWs' long axis, showed the effect of the non-magnetic Cu layer on the overall magnetic properties of the NW arrays. In particular, introducing Cu layers along the magnetic NW axis creates domain wall pinning nucleation that facilitate the magnetization reversal of the wires, as seen by the decrease in the parallel coercivity and the reduction of the perpendicular saturation field. By further increasing the Cu layer thickness, the interactions between the magnetic segments, both along the NW axis and of neighbouring NWs, decrease, thus rising again the parallel coercivity and the perpendicular saturation field. This work shows how one can easily tune the parallel and perpendicular magnetic properties of a 3D magnetic layer system by adjusting the non-magnetic layer thickness.

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Section: Samplesupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Magnetic behaviour of multisegmented FeCoCu/Cu electrodeposited nanowires

Núñez

Pérez

Abuín

et al. 2017

J. Phys. D: Appl. Phys.

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“…An important class of NWs for applications in magnetic devices is the multi-segmented [ 13 , 14 ] one. The combination of multilayers of different materials, both magnetic and non-magnetic, has been spreading much interest due to the magnetic capability to control the interactions and the effect of magnetic anisotropy obtained by only varying the metal type and segment lengths [ 15 , 16 , 17 ].…”

Section: Introductionmentioning

confidence: 99%

“…The combination of multilayers of different materials, both magnetic and non-magnetic, has been spreading much interest due to the magnetic capability to control the interactions and the effect of magnetic anisotropy obtained by only varying the metal type and segment lengths [ 15 , 16 , 17 ]. In this sense, we can highlight some studies on multi-segmented NWs that employed Ni/Au [ 18 , 19 ], Ni/Cu [ 13 , 20 , 21 , 22 , 23 , 24 , 25 , 26 ], CoNi/Cu [ 27 ], NiFe/Cu [ 28 ], FeGa/Cu [ 16 , 17 ], Co/Cu [ 29 , 30 , 31 , 32 ], and Co/Au [ 33 ]. Because of particular advantages, such as their high saturation magnetization [ 34 ] and the large possibility of modulation of their magnetic properties [ 35 ], systems with FeCo alloys (i.e., CoFeB/Cu [ 36 ], CoFe/Au [ 35 ], CoFe/Cu [ 37 , 38 , 39 , 40 , 41 ]) have been well studied.…”

Section: Introductionmentioning

confidence: 99%

The Role of Cu Length on the Magnetic Behaviour of Fe/Cu Multi-Segmented Nanowires

et al. 2018

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A set of multi-segmented Fe/Cu nanowires were synthesized by a two-step anodization process of aluminum substrates and a pulsed electrodeposition technique using a single bath. While both Fe segment length and diameter were kept constant to (30 ± 7) and (45 ± 5) nm, respectively, Cu length was varied between (15 ± 5) and (120 ± 10) nm. The influence of the non-magnetic layer thickness variation on the nanowire magnetic properties was investigated through first-order reversal curve (FORC) measurements and micromagnetic simulations. Our analysis confirmed that, in the multi-segmented Fe/Cu nanowires with shorter Cu segments, the dipolar coupling between Fe segments controls the nanowire magnetic behavior, and its performance is like that of a homogenous Fe nanowire array of similar dimensions. On the other hand, multi-segmented Fe/Cu nanowires with larger Cu segments act like a collection of non-interacting magnetic entities (along the nanowire axis), and their global behavior is mainly controlled by the neighbor-to-neighbor nanodisc dipolar interactions.

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“…It is generally fabricated by etching (plus selected deposition steps) and thus involves relatively straightforward and low‐cost processes. Template materials, such as porous alumina or porous silicon (PSi) which offers a 3D porous structure, are often used for electrodeposition of magnetic metals within the pores. The deposited nanostructures (particles, wires) have been investigated with respect to their magnetization reversal processes with the concomitant domain wall motion and the interactions among them .…”

Section: Introductionmentioning

confidence: 99%

Arrays of Ni/Co Nanoparticles within a Nanostructured Silicon Host

Rumpf

Granitzer

González-Rodríguez

et al. 2020

Physica Status Solidi (a)

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Herein, nanostructured silicon is fabricated with two different embedded magnetic nanostructures (Ni/Co) to exploit the magnetic properties of both metals and discern the behavior of the exchange coupling between the two—especially with respect to their volume ratio. A variation of the size as well as the volume ratio of the two metals modifies the exchange coupling and thus the energy product. Two templates are utilized: one involves the use of porous silicon (PSi) and the other entails porous silicon nanotubes (SiNTs). In the case of Psi, the bimetallic structures (Ni/Co) are electrodeposited, whereas in the case of SiNTs, Co is chemically grown within the tubes followed by the deposition of Ni on the outside. The magnetic properties of the systems strongly depend on the geometry of the deposits, on the volume ratio of the two metals, as well as on the proximity of the deposits. If the distance is small enough magnetic exchange coupling is present. Due to their size and the coupling of the bimetallic structures, the switching behavior of the hysteresis can be varied. Ultimately, nanocomposites with an energy product as high as possible is achieved to give rise to applications as permanent nanomagnets.

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Tuning the magnetic properties of multisegmented Ni/Cu electrodeposited nanowires with controllable Ni lengths

Cited by 45 publications

References 44 publications

Magnetic behaviour of multisegmented FeCoCu/Cu electrodeposited nanowires

Magnetic behaviour of multisegmented FeCoCu/Cu electrodeposited nanowires

The Role of Cu Length on the Magnetic Behaviour of Fe/Cu Multi-Segmented Nanowires

Arrays of Ni/Co Nanoparticles within a Nanostructured Silicon Host

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