Enhanced magnetoelectric effect in heterogeneous multiferroic (x)CuFe2O4 − (1 − x)KNbO3 nanocomposite

Komalavalli, P.; Banu, I. B. Shameem; Mamat, M. H.; Anwar, M.; Hussain, Shamima; Basha, S. Sathik; Rajesh, R.

doi:10.1007/s42247-022-00382-y

emergent mater.

2022

DOI: 10.1007/s42247-022-00382-y

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Enhanced magnetoelectric effect in heterogeneous multiferroic (x)CuFe2O4 − (1 − x)KNbO3 nanocomposite

P. Komalavalli

I. B. Shameem Banu

M. H. Mamat

et al.

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Cited by 3 publications

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“…New magnetic particle designs that offer signal modulation specific to biochemical and physiological processes can create a new repertoire of readouts for MPI.Developments in the synthesis of magnetoelectric nanoparticles (MENPs) and related structures [26][27][28] have given rise to diverse material traits that could empower MPI with dynamic readouts relevant to physiology and neurophysiology. Recent research on the magnetoelectric effect has predominantly focused on the characterization of new material substrates [29][30][31] and the simulation of lattice interfacial coupling 32,33 . Finite element modeling (FEM) solvers in particular are used to better characterize a diverse range of magnetoelectric geometric arrangements and structures [34][35][36] .…”

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confidence: 99%

In silico assessment of electrophysiological neuronal recordings mediated by magnetoelectric nanoparticles

Bok

Haber

et al. 2022

Sci Rep

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Magnetoelectric materials hold untapped potential to revolutionize biomedical technologies. Sensing of biophysical processes in the brain is a particularly attractive application, with the prospect of using magnetoelectric nanoparticles (MENPs) as injectable agents for rapid brain-wide modulation and recording. Recent studies have demonstrated wireless brain stimulation in vivo using MENPs synthesized from cobalt ferrite (CFO) cores coated with piezoelectric barium titanate (BTO) shells. CFO–BTO core–shell MENPs have a relatively high magnetoelectric coefficient and have been proposed for direct magnetic particle imaging (MPI) of brain electrophysiology. However, the feasibility of acquiring such readouts has not been demonstrated or methodically quantified. Here we present the results of implementing a strain-based finite element magnetoelectric model of CFO–BTO core–shell MENPs and apply the model to quantify magnetization in response to neural electric fields. We use the model to determine optimal MENPs-mediated electrophysiological readouts both at the single neuron level and for MENPs diffusing in bulk neural tissue for in vivo scenarios. Our results lay the groundwork for MENP recording of electrophysiological signals and provide a broad analytical infrastructure to validate MENPs for biomedical applications.

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confidence: 99%

In silico assessment of electrophysiological neuronal recordings mediated by magnetoelectric nanoparticles

Bok

Haber

et al. 2022

Sci Rep

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Enhanced dielectric properties of PVA/PEDOT:PSS/MnO2 based composites for electronic applications

Raja

Ahamed

Hussain

et al. 2022

J Mater Sci: Mater Electron

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Tunability of magnetoelectric coupling in BiFeO3–PbZr0.52Ti0.48O3–CoFe2O4 tri-phase composites for ultra-fast switching applications

Khan

Mustafa

Riaz

et al. 2023

Ceramics International

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Enhanced magnetoelectric effect in heterogeneous multiferroic (x)CuFe2O4 − (1 − x)KNbO3 nanocomposite

Cited by 3 publications

References 20 publications

In silico assessment of electrophysiological neuronal recordings mediated by magnetoelectric nanoparticles

In silico assessment of electrophysiological neuronal recordings mediated by magnetoelectric nanoparticles

Enhanced dielectric properties of PVA/PEDOT:PSS/MnO2 based composites for electronic applications

Tunability of magnetoelectric coupling in BiFeO3–PbZr0.52Ti0.48O3–CoFe2O4 tri-phase composites for ultra-fast switching applications

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