Erbium nitride is crystalline powder, which is a rare earth metal nitride. It is notable for its magnetic and optical properties. Erbium metal is the raw material. After subliming,it forms ErN crystals.The ErN compound deviated from stoichiometry: the Er:N atomic ratio ranged from 1:1.15 to 1:1.2 according to EDX and XPS elemental analysis.
ErN is a high-performance material that has garnered attention across various high-tech industries due to its exceptional properties and wide range of applications. As a rare earth nitride, ErN exhibits remarkable thermal stability, unique optical characteristics, and impressive electrical conductivity, making it an essential component in the development of advanced technologies.
Erbium Nitride
Purity: Er/RE 99.9% 3N
Particle size: -100mesh, -200mesh
| CAS No.:12020-21-2 | Molecular Formula:ErN | Molecular Weight:181.267 | Density:10.6 |
Applications
One of the primary applications of erbium nitride is in the field of optoelectronics. Its distinctive luminescent properties enable its use in phosphors, which are crucial for display technologies, including LEDs and solid-state lighting. By enhancing light emission and improving color quality, ErN contributes to the creation of energy-efficient lighting solutions and advanced display systems, making it a vital material in both consumer electronics and industrial applications.
In addition to its role in optoelectronics, ErN is also utilized in the semiconductor industry. Its excellent electrical characteristics make it suitable for high-performance electronic components, including transistors and diodes. As the demand for smaller, faster, and more efficient devices continues to rise, ErN’s ability to function reliably under demanding conditions positions it as a key material for next-generation semiconductor technologies.
Furthermore, ErN is being explored for its magnetic properties, particularly in the development of advanced magnetic materials and permanent magnets. Its strong magnetic characteristics can enhance data storage solutions and spintronic applications, which leverage electron spin for improved performance in electronic devices. As industries seek innovative ways to enhance data capacity and processing speed, ErN holds promissing opportunities for driving advancements in this area.
Additionally, ErN’s thermal stability makes it suitable for high-temperature applications, including coatings and protective layers used in harsh environments. Its resilience under extreme conditions contributes to the durability and longevity of components in industries such as aerospace and energy.