Inorganic Materials - Nanotechnology

What are Inorganic Materials in Nanotechnology?

Inorganic materials in the context of Nanotechnology refer to materials that do not contain carbon-hydrogen bonds. These materials include metals, metal oxides, and various other compounds that exhibit unique properties at the nanoscale. They are known for their stability, conductivity, and diverse applications in various fields.

Why are Inorganic Nanomaterials Important?

Inorganic nanomaterials are crucial due to their exceptional physical properties such as electrical conductivity, thermal stability, and mechanical strength. These properties make them suitable for a wide range of applications including electronics, medicine, and environmental remediation.

What are Some Examples of Inorganic Nanomaterials?

Some common examples of inorganic nanomaterials include quantum dots, nanowires, nanotubes, and nanoparticles of materials like gold, silver, titanium dioxide, and zinc oxide. Each of these materials has specific properties that make them suitable for particular applications.

How are Inorganic Nanomaterials Synthesized?

There are several methods to synthesize inorganic nanomaterials, including chemical vapor deposition (CVD), sol-gel process, hydrothermal synthesis, and electrochemical deposition. The choice of synthesis method depends on the desired properties and applications of the nanomaterials.

What Applications Do Inorganic Nanomaterials Have?

Inorganic nanomaterials have a wide range of applications. In electronics and semiconductors, they are used to create smaller, more efficient components. In medicine and drug delivery, they are utilized for targeted therapies and imaging. In environmental applications, they help in pollution control and water purification. Additionally, they are used in energy storage devices like batteries and supercapacitors.

What are the Challenges in Working with Inorganic Nanomaterials?

Despite their advantages, there are several challenges in working with inorganic nanomaterials. These include issues related to toxicity, environmental impact, and the high cost of synthesis and processing. Additionally, there are technical challenges in integrating these materials into existing systems and ensuring their stability and performance over time.

What is the Future of Inorganic Nanomaterials?

The future of inorganic nanomaterials is promising, with ongoing research aimed at overcoming current challenges and discovering new applications. Advances in nanofabrication techniques, better understanding of nanomaterial properties, and the development of new materials are expected to drive innovation in this field. The integration of inorganic nanomaterials with other technologies promises to revolutionize industries ranging from healthcare to energy.

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Caught in the Act of Substitution: Interadsorbate Effects on an Atomically Precise Fe/Co/Se Nanocluster.

Issue Release: 2024

Hybrid bilayered vanadium oxide electrodes with large and tunable interlayer distances in lithium-ion batteries.

Issue Release: 2024

Nanotubes from Transition Metal Dichalcogenides: Recent Progress in the Synthesis, Characterization and Electrooptical Properties.

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Recent progress on CO separation membranes.

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Nanocomposite hyaluronic acid adhesive hydrogel with controllable drug release for bone regeneration.

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Over 19% Efficient Inverted Organic Photovoltaics Featuring a Molecularly Doped Metal Oxide Electron-Transporting Layer.

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Insight into hemostatic performance and mechanism of natural mixed-dimensional Attapulgite clay.

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Numerical simulation to optimize power conversion efficiency of an FTO/GO/CsAgBiBr/CuO solar cell.

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Synthesis and properties of anhydrous rare-earth phosphates, monazite and xenotime: a review.

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Synthesis and fabrication of magnetically separable phosphate-modified magnetic chitosan composites for lead(II) selective removal from wastewater.

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Carbon carrier-based rapid Joule heating technology: a review on the preparation and applications of functional nanomaterials.

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Formation of iminium ions during the processing of metal halide perovskites.

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Harnessing plant extracts for eco-friendly synthesis of iron nanoparticle (Fe-NPs): Characterization and their potential applications for ameliorating environmental pollutants.

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Real-Time Diagnosis and Monitoring of Biofilm and Corrosion Layer Formation on Different Water Pipe Materials Using Non-Invasive Imaging Methods.

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Polarity profiling of porous architectures: solvatochromic dye encapsulation in metal-organic frameworks.

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Unravelling arsenic bioavailability in floodplain soils impacted by mining activities.

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Gas Delivery Relevant to Human Health using Porous Materials.

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Crystallographic phase identifier of a convolutional self-attention neural network (CPICANN) on powder diffraction patterns.

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The Development and Atomic Structure of Zinc Oxide Crystals Grown within Polymers from Vapor Phase Precursors.

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Electron-Delocalization Across High Surface Entropy Sub-1 nm Nanobelts Toward Enhanced Electrocatalytic Urea Oxidation.

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