Cas no 12006-84-7 (iron boride)
iron boride Chemical and Physical Properties
Names and Identifiers
-
- iron boride
- AC1L3448
- AR-1I0672
- EINECS 234-489-9
- FERRIC BORIDE
- FERROUS BORIDE
- Iron boride (FeB)
- ironylidyneborane
- boryliron
- Germanium Disulfide (GeS2) Sputtering Targets
- boranylidyneiron
- MFCD00016092
- CS-0144735
- DTXSID9065154
- 12006-84-7
- DTXCID4033556
-
- MDL: MFCD00016092
- Inchi: 1S/B.Fe
- InChI Key: ZDVYABSQRRRIOJ-UHFFFAOYSA-N
- SMILES: [Fe]#B
Computed Properties
- Exact Mass: 63.9525
- Monoisotopic Mass: 66.944
- Isotope Atom Count: 0
- Hydrogen Bond Donor Count: 0
- Hydrogen Bond Acceptor Count: 0
- Heavy Atom Count: 2
- Rotatable Bond Count: 0
- Complexity: 10
- Covalently-Bonded Unit Count: 1
- Defined Atom Stereocenter Count: 0
- Undefined Atom Stereocenter Count : 0
- Defined Bond Stereocenter Count: 0
- Undefined Bond Stereocenter Count: 0
- Surface Charge: 0
- Tautomer Count: nothing
- XLogP3: nothing
- Topological Polar Surface Area: 0A^2
Experimental Properties
- Color/Form: Gray orthorhombic crystals
- Density: 7.15
- Melting Point: 1650°C
- Boiling Point: °Cat760mmHg
- Flash Point: °C
- Water Partition Coefficient: Insoluble in water.
- PSA: 0
- Solubility: Not available
iron boride Pricemore >>
| Related Categories | No. | Product Name | Cas No. | Purity | Specification | Price | update time | Inquiry |
|---|---|---|---|---|---|---|---|---|
| SHANG HAI A LA DING SHENG HUA KE JI GU FEN Co., Ltd. | I302566-100g |
iron boride |
12006-84-7 | 98% | 100g |
¥2574.90 | 2023-09-02 | |
| SHANG HAI A LA DING SHENG HUA KE JI GU FEN Co., Ltd. | I302566-25g |
iron boride |
12006-84-7 | 98% | 25g |
¥717.90 | 2023-09-02 | |
| SHANG HAI A LA DING SHENG HUA KE JI GU FEN Co., Ltd. | I302566-5g |
iron boride |
12006-84-7 | 98% | 5g |
¥237.90 | 2023-09-02 | |
| A FA AI SHA , SAI MO FEI SHI ER KE JI QI XIA GONG SI | 88146-25g |
Iron boride, 98% |
12006-84-7 | 98% | 25g |
107.00 | 2021-05-24 | |
| A FA AI SHA , SAI MO FEI SHI ER KE JI QI XIA GONG SI | 88146-100g |
Iron boride, 98% |
12006-84-7 | 98% | 100g |
380.00 | 2021-05-24 | |
| SHANG HAI MAI KE LIN SHENG HUA Technology Co., Ltd. | I888938-100g |
IRON BORIDE |
12006-84-7 | 98% | 100g |
3,400.00 | 2021-05-17 | |
| SHANG HAI JI ZHI SHENG HUA Technology Co., Ltd. | X85445-100g |
IRON BORIDE |
12006-84-7 | 98% | 100g |
¥2728.0 | 2023-09-05 | |
| SHANG HAI JI ZHI SHENG HUA Technology Co., Ltd. | X85445-25g |
IRON BORIDE |
12006-84-7 | 98% | 25g |
¥778.0 | 2023-09-05 | |
| SHANG HAI JI ZHI SHENG HUA Technology Co., Ltd. | X85445-5g |
IRON BORIDE |
12006-84-7 | 98% | 5g |
¥248.0 | 2023-09-05 | |
| SHANG HAI XIAN DING Biotechnology Co., Ltd. | F-WA627-1g |
iron boride |
12006-84-7 | 98% | 1g |
¥231.0 | 2022-02-28 |
iron boride Related Literature
-
Alvin Tanudjaja,Shinsuke Inagi,Fusao Kitamura,Toshikazu Takata,Ikuyoshi Tomita Dalton Trans., 2021,50, 3037-3043
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3. An all-solid-state imprinted polymer-based potentiometric sensor for determination of bisphenol S?Rongning Liang,Tanji Yin,Ruiqing Yao,Wei Qin RSC Adv., 2016,6, 73308-73312
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J. M. Granadino-Roldán,M. Fernández-Gómez,A. Navarro,T. Pe?a Ruiz,U. A. Jayasooriya Phys. Chem. Chem. Phys., 2004,6, 1133-1143
Additional information on iron boride
Exploring Iron Boride (CAS No. 12006-84-7): Properties, Applications, and Future Trends
Iron boride (CAS No. 12006-84-7) is an inorganic compound composed of iron and boron, known for its exceptional hardness, thermal stability, and corrosion resistance. This material has garnered significant attention in industrial and research communities due to its unique combination of mechanical and chemical properties. In this article, we delve into the characteristics, applications, and emerging trends surrounding iron boride, addressing common queries and highlighting its relevance in modern technology.
The compound iron boride exists in several stoichiometric forms, including FeB and Fe2B, each with distinct properties. FeB exhibits a higher hardness (up to 18 GPa) and brittleness, while Fe2B offers better toughness and is more commonly used in industrial applications. These phases are often synthesized through methods such as powder metallurgy, chemical vapor deposition (CVD), or thermal diffusion processes. Researchers frequently search for "iron boride synthesis methods" or "FeB vs Fe2B properties," reflecting the demand for tailored material performance.
One of the most prominent applications of iron boride is in wear-resistant coatings. Industries such as automotive, aerospace, and manufacturing utilize iron boride coatings to enhance the durability of components exposed to abrasive environments. For instance, engine parts, cutting tools, and drill bits often feature these coatings to extend service life. Searches like "best wear-resistant materials 2024" or "iron boride coating benefits" underscore the growing interest in advanced protective solutions.
Beyond coatings, iron boride is explored for its potential in energy storage and catalysis. Recent studies investigate its role in hydrogen storage systems, leveraging its ability to absorb and release hydrogen under controlled conditions. Queries such as "iron boride hydrogen storage" or "boride-based catalysts" align with the global push toward sustainable energy solutions. This positions iron boride as a material of interest in the transition to greener technologies.
The magnetic properties of iron boride also make it a candidate for specialized electronic applications. Fe2B, in particular, exhibits ferromagnetic behavior at room temperature, prompting research into its use in sensors and magnetic recording devices. With the rise of IoT and smart technologies, searches for "magnetic materials for electronics" or "iron boride in sensors" highlight its relevance in cutting-edge innovations.
Environmental and cost considerations are critical in the adoption of iron boride. Compared to other borides like titanium diboride, iron boride offers a cost-effective alternative without compromising performance. This has led to increased inquiries about "iron boride cost analysis" and "eco-friendly boride materials," reflecting a balance between economic and sustainability goals.
Looking ahead, advancements in nanotechnology are expected to further expand the applications of iron boride. Nano-structured iron boride particles could revolutionize fields like medicine (e.g., targeted drug delivery) or environmental remediation (e.g., pollutant degradation). Searches such as "nano iron boride applications" or "boride nanomaterials 2024" indicate a forward-looking interest in these developments.
In summary, iron boride (CAS No. 12006-84-7) is a versatile material with a broad spectrum of industrial and technological applications. Its unique properties, coupled with ongoing research, ensure its place in discussions about advanced materials. Whether for wear resistance, energy storage, or electronics, iron boride continues to inspire innovation and meet the evolving demands of modern engineering.
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