Korobi Konwar scite author profile

The aim of the work is to explore structurerelaxivity relationship by observing transverse relaxivity enhancement in magnetic resonance imaging (MRI) of differently organized superparamagnetic complex ensembles of zinc ferrite isotropic/anisotropic nanosystems. We observe that superparamagnetic systems show a correlation of MRI-transverse relaxivity, r 2 /r 1 , with spatial arrangement of nanoparticles, as well as magnetic easy axes and thermal-energy-dependent anisotropy energy landscape. The presence of highly random/partially aligned easy axes with enhanced anisotropy constant leads to modulation in transverse relaxation. As a result, we achieve highest contrast efficiency in compact ensemble of isotropic nanoparticles and hollow core ensemble. Indeed, core−shell ensemble with combined effect of aligned and randomly oriented easy magnetic axes shows a reduction in MRI contrast efficiency. However, we address a hypothesis for transverse contrast efficiency where we depict the correlation among MRI-transverse contrast efficiency with structural complexity of ensembles, differently arranged primary nanoparticles/magnetic easy axes, anisotropy constant, and collective magnetic behavior. In consequence, we simplify the limitation of quantum mechanical outer-sphere diffusion model of magnetic resonance relaxivity by neglecting the contribution of magnetization and introducing an anisotropy constant contribution with complex structure landscape of easy axes.

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Dynamic spin freezing and magnetic memory effect in ensembles of interacting anisotropic magnetic nanoparticles

Konwar

Kaushik

Sen

et al. 2020

Phys. Rev. B

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Easy axes orientation dependent model for collective magnetic behaviour of zinc ferrite nanoparticles assembly

Konwar¹,

Kaushik²,

Deb³

2020

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Multifunctional Iron oxide embedded reduced graphene oxide as a versatile adsorbent candidate for effectual arsenic and dye removal

Pradhan

Konwar

Ghosh

et al. 2020

Colloid and Interface Science Communications

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A Review on Soft Computing Techniques in Nanomagnetism and Its Impact on Biomedical Applications

Konwar¹,

Deb²

2021

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Korobi Konwar

Structure-Correlated Magnetic Resonance Transverse Relaxivity Enhancement in Superparamagnetic Ensembles with Complex Anisotropy Landscape

Dynamic spin freezing and magnetic memory effect in ensembles of interacting anisotropic magnetic nanoparticles

Easy axes orientation dependent model for collective magnetic behaviour of zinc ferrite nanoparticles assembly

Multifunctional Iron oxide embedded reduced graphene oxide as a versatile adsorbent candidate for effectual arsenic and dye removal

A Review on Soft Computing Techniques in Nanomagnetism and Its Impact on Biomedical Applications

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