The magnetic spinel ferrites, MFe 2 O 4 (wherein 'M' = a divalent metal ion such as but not limited to Mn, Co, Zn, and Ni), represent a unique class of magnetic materials in which the rational introduction of different 'M's can yield correspondingly unique and interesting magnetic behaviors. Herein we present a generalized hydrothermal method for the synthesis of single-crystalline ferrite nanoparticles with 'M' = Mg, Fe, Co, Ni, Cu, and Zn), which can be systematically and efficaciously produced simply by changing the metal precursor. Our protocol can moreover lead to reproducible size control by judicious selection of various surfactants. As such, we have probed the effects of both (i) size and (ii) chemical composition upon the magnetic properties of these nanomaterials using complementary magnetometry and Mössbauer spectroscopy techniques. The structure of the samples was confirmed by atomic PDF analysis of X-ray and electron powder diffraction data as a function of particle size. These materials retain the bulk spinel structure to the smallest size (i.e. 3 nm). In addition, we have explored the catalytic potential of our ferrites as both (a) magnetically recoverable photocatalysts and (b) biological catalysts, and noted that many of our asprepared ferrite systems evinced intrinsically higher activities as compared with their iron oxide counterparts.
Metal oxides represent a set of promising
materials for use as electrodes within lithium ion batteries, but
unfortunately, these tend to suffer from limitations associated with
poor ionic and electron conductivity as well as low cycling performance.
Hence, to achieve the goal of creating economical, relatively less
toxic, thermally stable, and simultaneously high-energy-density electrode
materials, we have put forth a number of targeted strategies, aimed
at rationally improving upon electrochemical performance. Specifically,
in this Perspective, we discuss the precise roles and effects of controllably
varying not only (i) morphology but also (ii) chemistry as a means
of advancing, ameliorating, and fundamentally tuning the development
and evolution of Fe3O4, Li4Ti5O12, TiO2, and LiV3O8 as viable and ubiquitous energy storage materials.
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