Hafnium Hydride Nanoparticles
Hafnium Hydride Nanoparticles
| Hafnium Hydride Nanoparticles | |
| Product No | NRE-5100 |
| CAS No. | 12770-26-2 |
| Formula | HfH2 |
| Density | 11.4 g/cm3 |
| APS | <100 nm (Can be Customized) |
| Purity | 99.9% |
| Form | Powder |
| Molecular Weight | 180.505 g/mol |
| Certificate Of Analysis | |
| Hf | 98.8% |
| H | 1.1% |
| Co | 0.02% |
| Mn | 0.03% |
| Fe | 0.02% |
| S | 0.01% |
| Ti | 0.01% |
Hafnium Hydride Nanoparticles
Hafnium hydride is a compound formed when hafnium (Hf) reacts with hydrogen (H₂) under specific conditions. Typically, hafnium hydride exists in a non-stoichiometric form, meaning the ratio of hydrogen to hafnium (denoted as HfHₓ) can vary, and the material can contain hydrogen in different proportions. It is generally prepared by exposing hafnium to hydrogen gas at elevated temperatures or by other reduction processes that facilitate hydrogen absorption.
Hafnium hydride nanoparticles are the nanostructured form of this compound, where the small size (on the order of nanometers) leads to a significantly increased surface area, enhanced reactivity, and distinctive properties compared to bulk materials. These nanoparticles exhibit interesting features such as high hydrogen storage capacity, good thermal stability, and enhanced catalytic properties. Due to these characteristics, hafnium hydride nanoparticles are being explored for a variety of advanced applications in energy, electronics, materials science, and other high-tech industries.
Key Properties of Hafnium Hydride Nanoparticles:
Hydrogen Storage: Hafnium hydride has the ability to absorb large amounts of hydrogen, making it useful for hydrogen storage applications, particularly in energy systems.
High Thermal Stability: HfHₓ nanoparticles are stable at relatively high temperatures compared to other hydrogen storage materials, which makes them suitable for applications in harsh environments.
Catalytic Properties: Hafnium hydride nanoparticles exhibit catalytic properties that can be leveraged in chemical reactions such as hydrogenation or as catalyst supports in various industrial processes.
Electrical Conductivity: In certain forms, HfHₓ nanoparticles may have semiconducting or conducting properties, which makes them promising in certain electronic applications.
High Surface Area: Nanoparticles have a much larger surface area compared to bulk materials, which increases their reactivity and makes them more effective in various applications.
