International Journal of Nanomaterials and Nanostructures

The magnetic field guided nanoparticles are studied in the viewpoint of diluted magnetic semiconductor. Different structures and properties associated with Zn doped αFe2O3 nanostructures are presented in theoretical formulations. In addition, scientific methods of synthesizing particularly Solvothermal and biological methods of synthesizing Zn0.6Fe1.6O3 nanoparticles are discussed. More emphasis is given to the essence of nanotechnology from non-organic to organic matter namely nanoparticles of Zn0.6Fe1.6O3 to DNA. For in vivo or in vitro applications, properties such as biocompatibility, reactivity, bio sensitivity, magnetic interactions and electrostatic interactions are considered while discussing applicability of Zn substituted αFe2O3 nanoparticles. These properties are first explored to study the biosensing and biomedical application of Zn substituted αFe2O3 nanoparticles. More specifically, the systematic analysis of data formulated indicates that Zn substituted αFe2O3 nanoparticles is visualized as a smart material as it exhibits a multiferroicity. The ferro and nanofluidic characteristics of the stated material will further investigated from the solid-liquid interface regime.to this end the surface and interface effects are dealt. This research, therefore,summarizes the causes, detecting and treatment mechanisms of cancers by the wise use of nanotechnology. This will be done by determining the factors that determine the stability and immunosensitive concerning environmental condition such as temperature, and oxygen pressure, and electric fields. In additions, the impact of nanotechnology, particularly magnetic nanoparticles in nanomedical, therapeutic and technological ease will be demonstrated.

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