Iron Nanoparticles Nano Fe Powder CAS 7439-89-6

(Iron Nanoparticles Nano Fe Powder CAS 7439-89-6)

Overview of Iron Nanoparticles Nano Fe Powder      

Iron Nanoparticles (Nano Fe Powder) are materials composed of extremely small iron atoms or clusters, typically ranging in size from 1 to 100 nanometers. Due to their extremely small size, these nanoparticles exhibit distinct physical, chemical, and magnetic properties from traditional iron materials. For example, they have a very high specific surface area, which significantly enhances their surface energy, catalytic activity, and magnetic responsiveness. Iron Nanoparticles, as a unique nanomaterial, have broad application prospects in multiple fields due to their excellent performance.

Features of Iron Nanoparticles Nano Fe Powder      

Minimal size: The size of Nano Fe Powder is usually between 1 and 100 nanometers, which is much smaller than traditional iron materials, allowing it to exhibit unique physical, chemical, and magnetic properties.

High specific surface area: Due to its extremely small size, Nano Fe Powder has a very high specific surface area, which enhances its surface energy, catalytic activity, and magnetic responsiveness.

Excellent magnetic properties: Nano Fe Powder exhibits superparamagnetism or high coercivity, making it potentially valuable for applications in magnetic recording, magnetic resonance imaging, and other fields.

High catalytic activity: Due to the nanoscale effect, Nano Fe Powder exhibits extremely high activity in catalytic reactions and can be used as a catalyst for various chemical reactions.

Good biocompatibility: Nano Fe Powder has good biocompatibility, making it widely used in biomedical fields such as drug delivery and imaging.

Easy to prepare and modify: Nano Fe Powder can be prepared by various methods, and its surface is easily chemically modified, thereby expanding its application fields.

Application of Iron Nanoparticles Nano Fe Powder            

Biomedical field: Nano Fe Powder can be used in drug delivery systems to improve drug efficacy and reduce side effects through magnetic targeting. Meanwhile, it can also serve as a contrast agent for magnetic resonance imaging, improving imaging resolution and contrast.

In the field of environmental protection: Nano Fe Powder can be used to treat heavy metal ions and organic pollutants in polluted water sources, and remove pollutants through mechanisms such as adsorption and reduction.

Materials Science: Nano Fe Powder can be used as a raw material for the preparation of high-performance magnetic materials, for the preparation of permanent magnets, magnetic sensors, etc.

Application of Iron Nanoparticles Nano Fe Powder

Electronic Industry: Due to its excellent magnetic and electrical properties, Nano Fe Powder can be used to prepare electronic components such as high-frequency inductors and transformers.

In the field of catalysis: Nano Fe Powder can be used as a catalyst for various chemical reactions, such as hydrogenation, oxidation, reduction, etc., to improve reaction rate and selectivity.

Magnetic recording technology: Due to its high coercivity and good magnetic stability, Nano Fe Powder can be used to prepare high-density magnetic recording media, improving the capacity and stability of magnetic recording.

Company Profile

NANOTRUN(www.rboschco.com) is a trusted global chemical material supplier & manufacturer with over 12-year-experience in providing super high-quality chemicals and nanomaterials, including boride powder, nitride powder, graphite powder, sulfide powder, 3D printing powder, etc.

The company has a professional technical department and Quality Supervision Department, a well-equipped laboratory, and equipped with advanced testing equipment and after-sales customer service center.

If you are looking for high-quality Iron Nanoparticles Nano Fe Powder, please feel free to contact us or click on the needed products to send an inquiry. 

Payment Term

L/C, T/T, Western Union, Paypal, Credit Card etc.

Shipment Term

By sea, by air, by express, as customers request.

FAQ

Q1

What are the key properties of Iron Nanoparticles (Nano Fe Powder) that make them distinct from bulk iron?

Answer: The key properties of Iron Nanoparticles that distinguish them from bulk iron are their extremely small size, high surface area, and unique magnetic properties. These nanoparticles exhibit enhanced surface energy, catalytic activity, and magnetic responsiveness due to their nanoscale dimensions.

Q2

How does the small size of Iron Nanoparticles affect their performance in applications?

Answer: The small size of Iron Nanoparticles significantly affects their performance in applications. Their high surface area enhances catalytic activity, making them effective catalysts for various chemical reactions. Additionally, their unique magnetic properties allow for precise control and targeting in fields like biomedicine and magnetic separation.

Q3

What are the challenges in the synthesis of Iron Nanoparticles and how are they overcome?

Answer: The synthesis of Iron Nanoparticles presents challenges such as controlling particle size, shape, and stability. These challenges are overcome through various synthetic techniques like chemical reduction, solvothermal methods, and microemulsion synthesis. These methods allow for precise control over the nanoparticle properties and ensure their stability in different environments.

Q4

How do Iron Nanoparticles interact with other materials and what are the potential applications of these interactions?

Answer: Iron Nanoparticles interact with other materials through various mechanisms such as adsorption, catalysis, and magnetic coupling. These interactions have numerous potential applications, including composite materials, sensors, and magnetic fluids. For instance, the interaction of Iron Nanoparticles with carbon materials can lead to enhanced electrochemical performance in energy storage applications.

Q5

What are the safety considerations when handling Iron Nanoparticles?

Answer: When handling Iron Nanoparticles, safety considerations include the use of appropriate protective equipment, such as gloves and lab coats, to avoid direct contact with the nanoparticles. Additionally, it's important to work in a well-ventilated area and follow safety protocols for handling nanomaterials to minimize any potential health risks.