Lithium nitride, a metal nitrogen, has the chemical formula Li3N. This solid is purple or red and shows a light-green luster when lit by reflected light. Purity: 99.99%
Particle Size: 100 mesh

Lithium Nitride Li3N: Powder Description
Li3N is a compound name. It is a good idea to use a bilingual translator Lithium Nitride The following are some examples of how to use Trilithium nitride . Lithium nitride has a high conductivity and is a fast-ionic conductor. Many studies have concentrated on the application. Compound of lithium nitride Solid cathode or electrode for batteries.
What is Li3N called in the correct terminology?
Lithium nitride, or Li3N is the correct name. Formulation of lithium nitride It is called Li3N.
As a fast-ion conductor, the material should have a high decomposition voltage and a lower electronic conductivity. However, it must also have a higher ionic conducting capacity, as well as better chemical stability.
Does Lithium Nitride Burn in the Air?
Uniquely, lithium reacts also with nitrogen in the atmosphere to form lithium-nitride. If heated in the atmosphere, Lithium produces a strong red flame. Lithium also reacts with nitrogen in the atmosphere to produce lithium nitride. The above characteristics are found in many of the lithium fast-ion conducting materials. These can be used as a power source for electronic devices, calculators, cameras, watches, and other electronic equipment.
What type of bonding is lithium nitride made up of?
Lithium Nitride Li3N: Ionic bond.
Li3N is it covalent or ionic?
Lithium Nitride is a ionic compound. Li's electronegativity is 0.98 while nitrogen is 3.04. Many people have envisioned using lithium fast ion materials to build large (electric) energy storage reactors. Electricity can be stored in energy storage stations when peak consumption occurs late at night. During times of peak consumption, power should be continuously supplied to the grid. The wide application possibilities of lithium-fixed ion conductors have attracted a lot of interest. To find better lithium-fixed-ion conductors people have carried out extensive and detailed research.
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How is Lithium Nitride Li3N produced?
It was discovered by the end of 19th century. Lithium Nitride can be made easily with a mixture of elements. Zintl und Brauer discovered the hexagonal structure in lithium nitride for the first time in 1935. It is 2. Charge of lithium Nitride . In 1976 Rabenau, and Schultz defined this structure by using single-crystal-X-ray-diffraction.
Research on the reactions between lithium nitride (Li3NH4) and hydrogen started in the early twentieth century. Dafert und Miklauz discovered at 220-250degC that lithium nitride, hydrogen, and a substance called "Li3NH4" are formed. Continue heating the substance to decompose into "Li3NH2", components with higher temperatures (>700degC), substances, and hydrogen. Ruff and Georges discovered later that "Li3NH4" consisted of Li2NH and LiH. "Li3NH2 was LiNH2 and 2 LiH."
In many areas, lithium nitride can be found today. The ionization model can explain Li3N's catalytic action under high temperatures and normal pressure. It also explains its role as a nitrogen source in solvothermal methods.
Li3N is prepared by reacting Li2 with N2 at 500degC. It is an effective catalyst to synthesize cBN in high temperature and pressure. It can also act as a catalyst for the formation of hBN at normal pressure and temperature.

Lithium Nitride Li3N Applications:
Lithium Nitride comes in a brownish red solid, or as a sand like powder. It is used in reducing agents.
What is the purpose of lithium nitride?
Lithium nitride is useful in a variety of fields.
1. Solid electrolyte
Lithium nitride has a higher conductivity than other inorganic sodium salts. The application of lithium as a cathode and solid electrode material in batteries has been the focus of many studies.
As a fast-ion conductor, the material should have better chemical stability, a lower electronic conductivity as well as ionic and decomposition voltages. The above characteristics are found in many lithium fast ion conductors. They can be used for the production of solid-state batteries that have high performance.
It was once thought that lithium fast ion materials could be used to construct large energy storage reactors (electric). Electricity can be stored in energy storage stations when peak consumption hours are late at nights. During peak periods of electricity consumption, the grid is continually supplied with power. The wide application possibilities of lithium fixed-ion conductors have arouse great interest. To find better lithium-fixed ion conductors people have carried out extensive and detailed research.
2. Preparation for cubic boron Nitride
Lithium nitride has many uses, including as an electrolyte. It is also a catalyst that can convert hexagonal Boron Nitride into cubic Boron Nitride.
In 1987 Japanese scientists obtained an N type cBN single-crystal with a diameter 2 mm, an irregular shape. Then, they grew a Be doped P-type crystal on top of it. By cutting and grinding the secondary cBN monocrystalline surface under high-pressure, the uniform PN junction of cBN is finally achieved.
China has also conducted similar synthesis experiments. The experiment took place on the domestic DS029B top press with six sides. To study the effect on the shape of the cBN samples synthesized in high pressure using lithium nitride and lithium hydride as catalysts, this experiment used hBN that was 99% pure as the starting material. This experiment used lithium nitride Li3N and lithium hydride LiH as catalysts, with hBN of 99% purity as the starting material.
As an addition to these experiments, using the phase change method and hexagonal boran nitride, a cubic boron-nitride has been synthesized with different additives. X-ray diffraction and Raman diffraction technologies were used. It is possible to conclude, after analyzing and describing the experimental products that additives have a different effect on the system.
3. Layer of organic light emitting devices with an electron injection layer
The organic light-emitting device (OLED) has a solid-state active light emitting, wide viewing angles, fast response times (1ms), large operating temperatures (-45-+85), flexible substrates, and wide operating temperature ranges (-45-+85). High power consumption and low power unit consumption are considered by the industry to be the benefits of next-generation display and lighting technology. OLED performance has improved significantly with the application of new organic materials and organic device structures.
In order to improve OLED device performance, Lithium Nitride (Li3N), a n-type nitride, is added as a dopant into the eight-hydroxyquinoline (Alq3) layers of aluminum. Li 3N has been reported for electron injection layers and cathodes. A buffer layer can improve the performance. During the process of evaporation Li3N is decomposed into Li2 and N2. Only Li can deposit on the device and N2 is not detrimental to its performance. Experiments have shown that an Alq3 doped with Li3N layer can be effectively used as an electron-injection layer to improve the OLED efficiency and reduce its operating voltage.

Lithium Nitride Li3N Product Performance:
Our lithium nitride is high-purity, ultrafine particles size and larger surface area.

Technical Data for Lithium Nitride Li3N:

Part Name	High Purity Nitride Powder
MF	Li3N
Purity	99.99%
Particle Size	-100 mesh
Useful Information	It is used as a catalyst, or raw material for organic synthesis.

Specification of Lithium Nitride Li3N:


Lithium Nitride Li3N - Powder - Packing & Shipping
The amount of Li3N powder in the packaging will determine which type we use.
Lithium nitride powder Li3N: Vacuum packaging 100g,500g or 1kg/bag or 25kg/barrel or your request.
Shipping of Lithium nitride powder Li3N Once payment has been received, goods can be shipped by air, sea, or express as quickly as possible.


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Properties of Lithium Nitride
Alternative Names	trilithium powder, trilithium azanide and Li3N powder
CAS Number	26134-62-3
Compound Formula	Li3N
Molecular Mass	36.8456
Appearance	Purple or red powder
Melting Point	N/A
Boiling Point	N/A
Density	1.3 g/cm3
Solubility In H2O	N/A
Exact Ma	37.0667
Lithium Nitride Health & Safety Information
Sign Word	Danger
Hazard Statements	H260-H314
Hazard Codes	F. C.
Risk Codes	11-14-29-34
Safety Declarations	16-22-26-27-36/37/39-45
Transport Information	UN 2806 4.3/PG 1,

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