Iron oxide, a substance made up of iron and oxygen atoms, is used to make iron oxide nanowires, which are one-dimensional nanostructures. They may grow up to several microns in length and have a diameter of a few nanometers to many tens of nanometers.
These nanowires are intriguing because of their distinct physical and chemical characteristics, which make them appropriate for a wide range of applications in industries including electronics, energy, healthcare, and environmental science.
Several techniques, including template-assisted growth, hydrothermal synthesis, and thermal evaporation, can be used to create iron oxide nanowires. The size, shape, and crystal structure of the nanowires may all be precisely controlled using these techniques.
The crystal structure of iron oxide nanowires, which can range from amorphous to highly organized depending on the synthesis process and growth circumstances, strongly influences the characteristics of these materials.
Magnetite (Fe3O4) and hematite (Fe2O3), which have magnetic and semiconducting characteristics, respectively, are the two types of iron oxide nanowires that are most frequently researched.
The Iron Oxide Nanowire accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.
Due to their special qualities and possible uses in a variety of industries, including biomedical engineering, electronics, and energy conversion, iron oxide nanowires have drawn a lot of interest in recent years.
The product name “FeOx NWs” refers to the high-quality iron oxide nanowires that Nanocomposix, a renowned provider of nanomaterials, offers.
FeOx NWs have a diameter of around 20–30 nm, a length that ranges from 1–10 microns, and are very uniform and monodisperse. They are made of two major types of iron oxide: magnetite (Fe3O4) and maghemite (-Fe2O3).
With the aid of an external magnetic field, the superparamagnetic behavior of the nanowires may be readily controlled. For uses like magnetic separation, medication administration, and the hyperthermia therapy of cancer, this feature makes them particularly desirable.
FeOx NWs are also a great choice for catalytic applications due to their large surface area to volume ratio. For a variety of chemical processes, such as the oxidation of organic molecules and the reduction of nitroarenes, they can be utilized as catalysts.
Furthermore, for targeted administration in biological applications, FeOx NWs may be functionalized with a variety of compounds, including peptides and antibodies.
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