Highly Textured FeCo Thin Films Deposited by Low Temperature Pulsed Laser Deposition

Varvaro, G.; Peddis, Davide; Barucca, G.; Mengucci, P.; Rodionova, Valeria; Chichay, K.; Testa, A. M.; Agostinelli, E.; Laureti, S.

doi:10.1021/acsami.5b06030

Cited by 12 publications

(4 citation statements)

References 32 publications

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“…We observed that thin underlayers such as Co or Ni (≈3 nm) help in reducing the grain size and eventually chose CoNi underlayer to achieve the magnetic anisotropy. Figure e shows the hysteresis loop of a sample of the type “substrate/CoNi(3 nm)/FeCo(30 nm)/CoNi(3 nm).” In this structure, top CoNi layer was deposited to protect FeCo from getting oxidized . The bottom CoNi layer plays a crucial role in reducing the coercivity through a reduction of grain size.…”

Section: Resultsmentioning

confidence: 99%

“…In contrast, our simulation indicates that the presence of an anisotropy is a necessary condition to achieve stress-induced domain wall motion for harvesting energy. [40] The bottom CoNi layer plays a crucial role in reducing the coercivity through a reduction of grain size. Nevertheless, to achieve preferred anisotropy in the microwires, it was required that the coercivity must be considerably lower than the anisotropy field.…”

Section: Introductionmentioning

confidence: 99%

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Stress‐Induced Domain Wall Motion in FeCo‐Based Magnetic Microwires for Realization of Energy Harvesting

Bhatti

Liu

et al. 2018

Adv Elect Materials

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domains store information states and the information is read by moving the domains. [11,[14][15][16][17][18] Domain wall movement can also be explored for energy harvesting by converting stress into changes in magnetization and thus into electrical voltage. In the energy harvesting investigations reported so far, domain wall motion is accomplished only in multiferroic structures, where stress was induced by providing an electrical energy to the ferroelectric layers. [19][20][21][22][23][24][25] Employing significant amounts of electrical energy, however, defeats the purpose of energy harvesting. Moreover, ceramic ferroelectric layers, like PZT, require high-temperature deposition or postdeposition annealing (>400 °C) under severe oxidation conditions, which inevitably degrade the magnetic properties. [26] Therefore, stress-induced motion of domain walls in pure magnetic films without the use of ferroelectric layers and a supplied energy is a better approach for self-power generation. In the past, amorphous magnetic materials have been studied for domain wall dynamics under stress. [27,28] Pickup of voltage using a pickup coil was used for sensing the domain wall motion. [29][30][31] An analytical model for stress-induced transverse domain wall movement in ferromagnetic nanostripe has also been proposed. [32] In this article, we report that the domain walls in magnetic microwires made of crystalline ferromagnetic films can be moved by merely applying mechanical stress. The key recipes for the successful observation of such domain wall movement are: (i) a magnetic stack of CoNi/Fe 65 Co 35 /CoNi with which we have controlled the microstructures, (ii) an induced magnetic easy axis that we set by the direction of fringing magnetic field during the deposition (see the Supporting Information), and (iii) the use of flexible substrates with which we could enhance the stress delivered to the device from ambient sources, which is otherwise impossible with rigid substrates like Si. With a prototype device, we have shown in this article, the motion of domain walls under applied stress and have harvested energy.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Stress‐Induced Domain Wall Motion in FeCo‐Based Magnetic Microwires for Realization of Energy Harvesting

Bhatti

Liu

et al. 2018

Adv Elect Materials

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“…Instead of changing the composition of the compounds, similar effects may be achieved by modulating the deposition conditions. As an example, pulsed laser deposition (PLD) is a widely used fabrication techniques for producing high-quality thin solid films (high crystalline degree and extremely smooth surfaces) offering a great degree of flexibility in varying the different process parameters [63][64][65][66][67][68]. In this regard, the effect of the deposition temperature on the EB effect has been recently studied in pulsed laser deposited CoFe/NiO bilayers.…”

Section: Chemical Inhomogeneitiesmentioning

confidence: 99%

The role of chemical and microstructural inhomogeneities on interface magnetism

et al. 2021

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The study of interfacing effects arising when different magnetic phases are in close contact has led to the discovery of novel physical properties and the development of innovative technological applications of nanostructured magnetic materials. Chemical and microstructural inhomogeneities at the interfacial region, driven by interdiffusion processes, chemical reactions and interface roughness may significantly affect the final properties of a material and, if suitably controlled, may represent an additional tool to finely tune the overall physical properties. The activity at the Nanostructured Magnetic Materials Laboratory (nM2-Lab) at CNR-ISM of Italy is aimed at designing and investigating nanoscale-engineered magnetic materials, where the overall magnetic properties are dominated by the interface exchange coupling. In this review, some examples of recent studies where the chemical and microstructural properties are critical in determining the overall magnetic properties in core/shell nanoparticles, nanocomposites and multilayer heterostructures are presented.

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“…Normally, magnetic films are fabricated through many techniques, including vacuum evaporation, 17 molecular beam epitaxy, 18 radio frequency-sputtering, 19,20 electroless-plating, 21,22 electrodeposition, 10,14,23,24 etc. Among the above mentioned methods, electrodeposition is one of the promising methods because of its low capital cost, high deposition rate and facile and reliable process control.…”

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confidence: 99%

The Temperature-Dependent Microstructure and Magnetic Parameters of FeCo Films

Cheng

Cao

et al. 2017

J. Electrochem. Soc.

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The microstructure and magnetic properties of FeCo films fabricated by electrodeposition technique with different deposition temperatures were systematically studied. The results indicate that deposition temperature have the significant impact on the composition, microstructure, thickness and morphology of the films. The static and dynamic magnetic properties of FeCo films reveal that magnetic anisotropy field (H k ) and the damping factor α firstly increased then decreased with the increase of deposition temperature from 18 to 78 • C. The saturation magnetization (4πM s ) value is roughly increased with the improvement of deposition temperatures.

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Highly Textured FeCo Thin Films Deposited by Low Temperature Pulsed Laser Deposition

Cited by 12 publications

References 32 publications

Stress‐Induced Domain Wall Motion in FeCo‐Based Magnetic Microwires for Realization of Energy Harvesting

Stress‐Induced Domain Wall Motion in FeCo‐Based Magnetic Microwires for Realization of Energy Harvesting

The role of chemical and microstructural inhomogeneities on interface magnetism

The Temperature-Dependent Microstructure and Magnetic Parameters of FeCo Films

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