Surface driven exchange bias in nanocrystalline CoCr<sub>2</sub>O<sub>4</sub>

Goswami, Sumanta; Manna, P. K.; Bedanta, Subhankar; Dey, Soumyajit; Chakraborty, M.; De, D.

doi:10.1088/1361-6463/ab87c7

Cited by 11 publications

(6 citation statements)

References 53 publications

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“…Significantly, simultaneous presence of honeycomb (P 63/mmc) plane (022) for graphene and (F m3m) planes (111,200,220,311) for NiO are noted in Fig. 2(b) [18,19,20]. All the planes are well indexed which are in accordance with standard JCPDS.…”

Section: X-ray and Raman Studiessupporting

confidence: 77%

Electro-Magnetic switching in NiO-Graphene film

Goswami¹,

Chakraborty²,

De³

2022

IOP Conf. Ser.: Mater. Sci. Eng.

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Nickel oxide (NiO) thin film is grown via pulse laser deposition (PLD) technique and it is trapped in between conducting graphene films deposited through the same technique. Epitaxial crystalline growth of both NiO and graphene films are confirmed from X-ray diffraction studies. Raman studies propose creation of pure graphene film with acceptable defects. Electrical transport of the NiO film reveal resistance switching properties for an wide range of temperature which is useful for resistive random access memory (RRAM) and electric-switch. Besides electrical switching, the transport properties of the NiO film depict a systematic response in influence of magnetic field. Resistance of the NiO film changed significantly with external magnetic field which makes the system useful as a magnetic-switch.

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Section: X-ray and Raman Studiessupporting

confidence: 77%

Electro-Magnetic switching in NiO-Graphene film

Goswami¹,

Chakraborty²,

De³

2022

IOP Conf. Ser.: Mater. Sci. Eng.

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“…The M – H loop exhibits proper FIM behavior with clear hysteresis at 15 K for all samples, indicating high coercivity due to spiral spin ordering. Additionally, the H C was determined using the formula H C = |( H 2 – H 1 )|/ 2, where H 2 and H 1 are the right and left coercivities, respectively, as reported in refs , . Figure S6 (Supporting Information) illustrates that the H C varies with increased Mg content.…”

Section: Resultsmentioning

confidence: 96%

“…Figure f–j illustrates the ZFC M – H loop at 15 K for all samples exhibiting the exchange bias (EB) effect. Figure k–o presents a magnified view of the M – H loop at 15 K. The exchange bias effect field ( H E ) was determined as H E = |( H 2 + H 1 )|/2 Figure S6 (Supporting Information) displays the EB effect observed in the M – H loop recorded at 15 K between ±60 kOe for all samples.…”

Section: Resultsmentioning

confidence: 99%

“…The study initially investigated the MME in the thermal variation of FC magnetization for CoCr 2 O 4 NPs doped with 0 and 15 mol % Mg. The FC and ZFC protocols for the magnetic memory effect were proposed by Goswami et al In this study, FC and ZFC magnetization measurements were conducted at a constant cooling/heating rate of 1 K/min. The FC memory experiment involved cooling the sample from 300 K while exposed to a static magnetic field of 200 Oe and recording the magnetization ( M ) as a function of temperature ( T ) from 50 to 10 K. Figure a,b depicts the FC memory effect as a function of temperature for both samples, along with the FC Reference and FC cooling/FC waiting curve for comparison.…”

Section: Applications Of Magnetic Propertiesmentioning

confidence: 99%

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Mg-Doped CoCr₂O₄ Nanoparticles: Implications for Magnetic Memory and Magnetocaloric Effect

Manjunatha

Chiu

et al. 2023

ACS Appl. Nano Mater.

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Using the co-precipitate method, Mg-doped CoCr2O4 nanoparticles (NPs) with a particle size ranging from 11 to 22 nm were synthesized, and their structural, surface, vibrational, and magnetic properties were examined through experimental and theoretical approaches. The inherent magnetic inhomogeneity of the NPs was found to be the cause of the observed exchange bias effect. The magnetic memory effect was studied below the spin glass-transition temperature using time- and temperature-dependent magnetization measurements, and the magnetocaloric effect was investigated across the Curie temperature. These NPs show promising potential for magnetic memory and magnetocaloric effect fields.

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“…Nanoscience and nanotechnology fundamentally emerge from the manipulation of matter at the nanoscale and the curiosity to understand various properties of matter at the atomic level. In nanoparticle assemblies, parameters such as size [1], surface structure [2], shape [3], agglomeration [4] or interparticle interactions [5] often influence their properties. At the same time, they lead to the emergence of enriched physico-chemical properties, which distinguish them from their bulk counterparts.…”

Section: Introductionmentioning

confidence: 99%

Dependence of Exchange Bias on Interparticle Interactions in Co/CoO Core/Shell Nanostructures

Goswami¹,

Gupta

Nayak

et al. 2022

Nanomaterials

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This article reports the dependence of exchange bias (EB) effect on interparticle interactions in nanocrystalline Co/CoO core/shell structures, synthesized using the conventional sol-gel technique. Analysis via powder X-Ray diffraction (PXRD) studies and transmission electron microscope (TEM) images confirm the presence of crystalline phases of core/shell Co/CoO with average particle size ≈ 18 nm. Volume fraction (φ) is varied (from 20% to 1%) by the introduction of a stoichiometric amount of non-magnetic amorphous silica matrix (SiO2) which leads to a change in interparticle interaction (separation). The influence of exchange and dipolar interactions on the EB effect, caused by the variation in interparticle interaction (separation) is studied for a series of Co/CoO core/shell nanoparticle systems. Studies of thermal variation of magnetization (M−T) and magnetic hysteresis loops (M−H) for the series point towards strong dependence of magnetic properties on dipolar interaction in concentrated assemblies whereas individual nanoparticle response is dominant in isolated nanoparticle systems. The analysis of the EB effect reveals a monotonic increase of coercivity (HC) and EB field (HE) with increasing volume fraction. When the nanoparticles are close enough and the interparticle interaction is significant, collective behavior leads to an increase in the effective antiferromagnetic (AFM) CoO shell thickness which results in high HC and HE. Moreover, in concentrated assemblies, the dipolar field superposes to the local exchange field and enhances the EB effect contributing as an additional source of unidirectional anisotropy.

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Surface driven exchange bias in nanocrystalline CoCr₂O₄

Cited by 11 publications

References 53 publications

Electro-Magnetic switching in NiO-Graphene film

Electro-Magnetic switching in NiO-Graphene film

Mg-Doped CoCr₂O₄ Nanoparticles: Implications for Magnetic Memory and Magnetocaloric Effect

Dependence of Exchange Bias on Interparticle Interactions in Co/CoO Core/Shell Nanostructures

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Surface driven exchange bias in nanocrystalline CoCr2O4

Cited by 11 publications

References 53 publications

Electro-Magnetic switching in NiO-Graphene film

Electro-Magnetic switching in NiO-Graphene film

Mg-Doped CoCr2O4 Nanoparticles: Implications for Magnetic Memory and Magnetocaloric Effect

Dependence of Exchange Bias on Interparticle Interactions in Co/CoO Core/Shell Nanostructures

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Product

Resources

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Surface driven exchange bias in nanocrystalline CoCr₂O₄

Mg-Doped CoCr₂O₄ Nanoparticles: Implications for Magnetic Memory and Magnetocaloric Effect