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Elementary

Scandium Metal Sc Metal CAS 7440-20-2

About Scandium Metal Sc Metal:
Scandium is a chemical element with the element symbol Sc and an atomic number of 21. Is scandium a metal? A silvery metal that tarnishes in air, burns easily and reacts with water. Scandium is mainly used for research purposes. It has, however, great potential because it has almost as low a density as aluminum and a much higher melting point. Elemental is a soft, silvery-white transition metal, often mixed with gadolinium, erbium and other existence, the yield is very small, in the earth's crust content is about 0.0005%. Why is scandium so expensive? Owing to its scarcity and limited production, scandium is one of the most expensive of all the natural elements.
Is scandium harmful to humans? Health effects of scandium: Scandium is most dangerous in the working environment, due to the fact that damps and gasses can be inhaled with air. This can cause lung embolisms, especially during long-term exposure. Scandium can be a threat to the liver when it accumulates in the human body.
Scandium is commonly used to make special glass, light and high-temperature resistant alloys. Scandium is slightly yellowish or pink when oxidized by air, is easily weathered and slowly dissolves in most dilute acids. However, in strong acids, the surface tends to form an impermeable passivation layer, so it does not react with a 1:1 mixture of nitric acid (HNO3) and hydrofluoric acid (HF). Biomedicalmaterialsprogram is a trusted global Scandium Metal Sc Metal supplier. Feel free to send an inquiry about the latest price of Scandium Metal Sc Metal at any time.

Product Performance of Scandium Metal Sc Metal  CAS 7440-20-2 :

The scandium metal is silver-white, generally distilling crystalline lump (meat-like) metal, and the ingot, sponge block or lens can also be button-shaped as-cast with a clean surface. It has a melting point of 1541 °C and a boiling point of 2831 °C. Scandium metal is easy to dissolve in water and can interact with hot water, making it easy to darken in the air.


Technical Parameter of Scandium Metal Sc Metal :

Product NameMFPurityParticle SizeMolecular WeightDensityColor
Scandium MetalSc99.9%- 99.999%100 mesh44.9562.985 g/cm3Silver White 

 

How is Scandium Metal Sc Metal Produced? 
The pure yield of scandium can reach 94%, the crude scandium contains 92% of scandium, the main impurity Ta_7 ~ 8%, Ca 0.5%. The use times of tantalum crucible were increased by this method. Pure scandium can be prepared by distilling the crude scandium obtained by reduction in a tantalum crucible with a thickness of 1 mm and a diameter of 40 mm. Ta in scandium can be reduced to 0.02%, and the purity of scandium is greater than 99%.
 
Applications of Scandium Metal Sc Metal:
Scandium is used in aluminum-scandium alloys for aerospace industry components and for sports equipment such as bicycle frames, fishing rods, golf iron shafts and baseball bats. Scandium iodide is used in mercury vapor lamps, which are used to replicate sunlight in studios for the film and television industry. What is scandium used for in the world?
Lighting industry
Scandium sodium lamp has the characteristics of high luminous efficiency, good light color, power saving, long service life and strong ability to break fog so that it can be widely used in television camera and square, stadium, street lighting, known as the third generation of the light source. In the metal-insulator-semiconductor silicon photocell and solar cell, scandium is the best barrier metal.
Alloy industrial
Scandium, in its elemental form, has been widely used in the doping of aluminum alloys. As long as a few thousandths of scandium is added to aluminum, a new phase of Al3Sc will be formed, which will have metamorphism on aluminum alloy and make the structure and properties of the alloy change significantly. The addition of 0.2%~0.4% Sc can increase the recrystallization temperature of the alloy by 150~200℃, and the high-temperature strength, structural stability, welding property and corrosion resistance are obviously improved and can avoid the embrittlement phenomenon which is easy to occur in the long-term working at high temperature.
To change the agent
Scandium is also an excellent iron modifier. A small amount of Scandium can significantly improve the strength and hardness of cast iron. In addition, scandium can also be used as an additive in high-temperature tungsten and chromium alloys.
Ceramic materials
The elemental scandium is generally used in alloys, and the oxide of scandium also plays an important role in ceramic materials. Tetragonal zirconia ceramics, such as those that can be used as electrode materials for solid oxide fuel cells, have a very special property in which the conductance of this electrolyte increases with temperature and oxygen concentration in the environment.
The catalytic chemistry
In the chemical industry, scandium is often used as a catalyst, SC2O3 can be used for ethanol or isopropanol dehydration and deoxygenation, acetic acid decomposition, from CO and H2 ethylene and so on. The Pt-Al catalyst containing SC2O3 is used as an important catalyst in the hydrogenation purification and refining process of heavy oil in the petrochemical industry.
Nuclear power industry
Adding a small amount of SC2O3 to UO2 in high-temperature reactor nuclear fuel can avoid lattice transition, volume increase and crack caused by UO2 to U3O8 conversion.
A fuel cell
Similarly, the addition of 2.5%~25% scandium in the nickel base battery will increase the service life.
Agricultural breeding
In agriculture, corn, beet, pea, wheat, sunflower and other seeds can be treated with scandium sulfate (the concentration is generally 10-3~10-8mol/L, different plants will be different). The actual effect of promoting germination has been achieved. After 8 hours, the dry weight of root and bud is increased by 37% and 78%, respectively, compared with that of seedlings.

Storage Condition of Scandium Metal Sc Metal :
The damp reunion will affect Sc metal dispersion performance and using effects, therefore, scandium metal should be sealed in vacuum packing and stored in a cool and dry room, the scandium metal can not be exposure to air. In addition, the scandium metal should be avoided under stress.

Packing & Shipping of Scandium Metal Sc Metal :
It is packed in double plastic bags inside, which can be filled with argon in a vacuum; it can be vacuumed and filled with argon for protection.
Scandium metal Sc metal packing: vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Scandium metal Sc metal shipping: could be shipped out by sea, by air, by express as soon as possible once payment receipt.





 

Scandium Metal Properties

Other NamesN/A
CAS No.7440-20-2
Compound FormulaSc
Molecular Weight44.96
AppearanceSilvery
Melting Point1541
Boiling Point2830
Density2985 kg/m3
Solubility in H2ON/A
Electrical Resistivity61.0 microhm-cm @ 22 °C
Poisson's Ratio0.279
Tensile StrengthN/A
Thermal Conductivity0.158 W/cm/K @ 298.2 K
Thermal Expansion(25 °C) 10.2 µm·m-1·K-1
Vickers HardnessN/A
Young's Modulus74.4 GPa
  
  

Scandium Metal Health & Safety Information

Signal WordN/A
Hazard StatementsN/A
Hazard CodesN/A
Risk CodesN/A
Safety StatementsN/A
Transport InformationNONH

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Boride Powder

Magnesium Diboride MgB2 Powder CAS 12007-25-9

About Magnesium Diboride MgB2 Powder:
Magnesium diboride is an inorganic compound with the molecular formula MgB2. It is a dark gray, insoluble solid. It is an ionic compound with a hexagonal crystal structure. It is an intercalated compound with alternating layers of magnesium and boron. This compound is of interest because it is superconducting at 39 K(−234°C).In terms of composition, MgB2 is markedly different from most transition-metal-based cryogenic superconductors.

Magnesium diboride has been known to scientists for nearly 50 years, but no one has ever studied the material's superconductivity -- whether it can conduct electricity perfectly without resistance when cooled to temperatures close to absolute zero. All that changed in January 2001, when Jun Akimitsu of Aoyama Gakuin University in Tokyo announced that he and his team had found that magnesium diboride became superconducting at 39 degrees Kelvin (-389 degrees Fahrenheit), almost twice the temperature of current intermetallic conductors. The announcement sent experimenters around the world scrambling to replicate and confirm the Japanese findings.

Magnesium boride is converted into a superconductor at a temperature slightly close to the absolute temperature of 40K (-233 ° C). Its transition temperature is nearly twice as high as that of other superconductors of the same type, and its actual operating temperature is between 20 and 30K. This temperature can be achieved by liquid neon, liquid hydrogen, or a closed cycle freezer. These methods are simpler and cheaper than the industry's use of liquid helium to cool niobium alloys (4K). Once doped with carbon or other impurities, magnesium boride is as good at maintaining superconductivity in the presence of a magnetic field or a current as niobium, or better. Feel free to send an inquiry to get the latest price if you would like to buy Magnesium Diboride MgB2 Powder in bulk.

Specifications of Magnesium Diboride MgB2 powder

Magnesium Diboride powder Purity:98.5% or Customized
Magnesium Diboride powder Size:5-15um or Customized
Magnesium Diboride powder Colour:Black
Magnesium Diboride powder CAS No.:12007-25-9
Magnesium Diboride powder EINECS No.:234-501-2

 

FeMnCuCaNiZnPbSn
48ppm0.1ppm0.06ppm0.04ppm7.4ppm0.2ppm0.14ppm

0.4ppm


Magnesium diboride is an ionic compound, with the hexagonal crystal structure. Magnesium diboride at absolute temperature slightly 40K (equivalent to -233 ℃) will be transformed into a superconductor. And its actual operating temperature is 20 ~ 30K. To reach this temperature, we can use liquid neon, liquid hydrogen or closed-cycle refrigerator to finish cooling. Compared to current industry using liquid helium to cool the niobium alloy (4K), these methods are more simple and economical. Once it is doped with carbon or other impurities, magnesium diboride in a magnetic field, or there is a current passing, the ability to maintain the superconducting is as much as niobium alloys, or even better. 
 

How is Magnesium Diboride MgB2 Powder produced?
The preparation method of MgB2 is mainly the reaction synthesis of magnesium powder and boron powder mixed.
MgB2 was obtained by mixing 99.9% magnesium powder with 99% amorphous boron powder at the ratio of 1:2, pressing it into small balls and adding heat in high-pressure nitrogen.

At present, the commonly used method is to mix amorphous elemental boron powder and magnesium powder according to the stoichiometric ratio (or add excessive magnesium), and then put them into a sealed refractory metal container (such as tantalum), and then put them in a quartz tube for vacuum pumping, and then sintered at 700~950for 1~4 h to synthesize MgB2.

Applications of Magnesium Diboride MgB2 Powder:
Potential applications for Magnesium diboride include superconducting magnets, power transmission lines and sensitive magnetic field detectors.

Magnesium diboride is the attention of new materials, the research mainly focused on the synthesis and superconducting element performance for the industrial synthesis and sintering properties, electrical conductivity at room temperature, the liquid aluminum erosion resistance of fluoride such as corrosive resistance study is less, so far no will MgB2 and its composite materials used in aluminum electrolysis cathodic area coverage.

MgB2 is easier to be sintered and densified than TiB2, and its electrical conductivity basically meets the requirements of aluminum electrolysis cathode. Therefore, MgB2 and its composite materials are likely to be widely used as cathode materials for aluminum electrolysis.

Propellants, Explosives, pyrotechnics: Unlike the element boron, which burns incompletely through glass oxide layers that block oxygen diffusion, magnesium diboride burns completely in oxygen or oxidizer mixtures. Therefore, magnesium boride has been proposed as fuel for ramjet jets. In addition, the use of MgB2 in enhanced explosives and propellants has been proposed for the same reason.
 

Storage Conditions of Magnesium Diboride MgB2 powder

This product should be sealed and stored in a cool, drying chamber and should avoid exposure to the air in order to prevent moisture reunion which will affect the dispersion properties and result use. Stress should be avoided.

Packing & Shipping of Magnesium Diboride MgB2 powder:
We have many different kinds of packing which depend on the magnesium diboride MgB2 powder quantity.
Magnesium diboride MgB2 powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Magnesium diboride MgB2 powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.


biomedicalmaterialsprogram Technology Co. Ltd. (Biomedicalmaterialsprogram) 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.
If you are looking for high-quality MgB2 powder, please feel free to contact us and send an inquiry.

 

Magnesium Boride Properties

Other Namesmagnesium boride powder, MgB2, MgB2 powder,
agnesium diboride
CAS No.12007-25-9
Compound FormulaMgB2
Molecular Weight45.927
AppearanceGray to Black Powder
Melting Point830 °C
Boiling PointN/A
Density2.57 g/cm3
Solubility in H2ON/A
Exact Mass46.003653
Monoisotopic Mass46.003653
  
  

Magnesium Boride Health & Safety Information

Signal WordN/A
Hazard StatementsN/A
Hazard CodesN/A
Risk CodesN/A
Safety StatementsN/A
RTECS NumberN/A
Transport InformationNONH for all modes of transport
WGK Germany3

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Elementary

Molybdenum Powder 3N Mo Powder CAS 7439-98-7

About Molybdenum Powder 3N Mo Powder:
The appearance of molybdenum powder is dark gray, the color should be uniform, with no agglomeration, no visible inclusions. Molybdenum powder A black powder consisting of molybdenum particles with a high specific surface area of 1-5 m2/g.Molybdenum is a dark gray or black glossy powder that was once confused with graphite and lead before being identified as a new element. The metal is silvery-white and very hard, but softer and more ductile than tungsten. Molybdenum has a high melting point, good corrosion resistance, excellent wear resistance, good electrical and thermal conductivity. It is valuable for alloying because it improves the hardenability and toughness of tempered steel. Biomedicalmaterialsprogram is a trusted global Molybdenum Powder 3N Mo Powder supplier. Feel free to send an inquiry about the latest Molybdenum Powder priceat any time.

Product Performance of Molybdenum Powder 3N Mo Powder CAS 7439-98-7 :

The characteristics of molybdenum metal powder ( CAS 7439-98-7 ) can manually adjust the color, particle size, surface characteristics, dispersion, rheology, thixotropy and crystal form, etc., and molybdenum powder has high chemical purity, strong chemical inertness, good thermal stability, molybdenum powder at below 400 degrees Celsius will not be broken down. In addition, Mo powder has the advantages of low oil absorption, low hardness, low abrasion value, non-toxic, odorless, odorless, and good dispersion.


Technical Parameter of Molybdenum Powder 3N Mo Powder CAS 7439-98-7 :

Product NameMFPurityParticle SizeMolecular WeightDensityColor
Molybdenum PowderMo99.9%5-10um9610.2 g/cm3Black

 

How is Molybdenum Powder 3N Mo Powder Produced? 
The preparation method of Mo powder includes the crystallization, calcination, hydrogen reduction and sifting of ammonium polymolybdate after dissolution in ammonia water. During crystallization, 60 ~ 450gKOH is added per 1000kg of ammonium polymolybdate.In this way, the molybdenum powder on the screen can be greatly reduced, and the real yield can reach 95%.
 
Applications of Molybdenum Powder 3N Mo Powder:
Metallurgy: The addition of Mo powders to stainless steel and other alloys can improve the corrosion resistance, hardening properties of composite alloys, and bring many other benefits to the final result.
Electronic products: the unique characteristics of molybdenum make molybdenum nanometer powder become the key material for the manufacture of various high-pressure vacuum tubes, heat tubes, X-ray tubes and so on.
Wood processing: Molybdenum powder uses is in wood processing as a supplement to catalysts.
Coatings: Molybdenum is known as the preferred coating for high friction, heavy-duty environments due to the extreme lubrication it provides. Molybdenum provides a simple and effective method for applying this coating with extreme accuracy.
High-temperature lubrication: under the condition that the lubricant needs to withstand high temperature, molybdenum-based synthetic grease is very good. Molybdenum nanoparticles play a crucial role in the manufacture of these high-temperature lubricants.

Storage Condition of Molybdenum Powder 3N Mo Powder CAS 7439-98-7 :
The damp reunion will affect molybdenum powder dispersion performance and using effects, therefore, Mo powder should be sealed in vacuum packing and stored in cool and dry room, the molybdenum powder can not be exposure to air. In addition, the product should be avoided under stress.

Packing & Shipping of Molybdenum Powder 3N Mo Powder CAS 7439-98-7 :
We have many different kinds of packing which depend on the molybdenum powder 3N Mo powder quantity.
Molybdenum powder 3N Mo powder packing: vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Molybdenum powder 3N Mo powder shipping: could be shipped out by sea, by air, by express as soon as possible once payment receipt.





 

Molybdenum Powder Properties

Other NamesMolybdenum particles, Molybdenum microparticles, Molybdenum micropowder,
Molybdenum micro powder, Molybdenum micron powder,
Molybdenum submicron powder, Molybdenum sub-micron powder
CAS No.7439-98-7
Compound FormulaMo
Molecular Weight95.94
AppearanceGray to Black Powder
Melting Point2623
Boiling Point4639
Density10.28 g/cm3
Solubility in H2ON/A
Specific Heat0.25 kJ/kg K
Poisson's Ratio0.31
Tensile Strength485-690 MPa
Thermal Conductivity138 W/m K
Thermal Expansion(25 °C) 4.8 µm·m-1·K-1
Vickers Hardness1530 MPa
Young's Modulus329 GPa
  
  

Molybdenum Powder Health & Safety Information

Signal WordWarning
Hazard StatementsH228
Hazard CodesN/A
Risk CodesN/A
Safety StatementsN/A
Transport InformationUN 3089 4.1/PG 2

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Boride Powder

Tungsten Boride WB2 Powder CAS 12007-09-9

About Tungsten Boride WB2:
Tungsten borides are compounds of tungsten and boron. Their most remarkable property is high hardness. The Vickers hardness of WB or WB2 crystals is ~20 GPa and that of WB4 is ~30 GPa for loads exceeding 3N.
The relative density of tungsten boride is 10.77 and the melting point is about 2900°C. It does not degrade water and can degrade aqua regia.
It is prepared by heating boron and tungsten powder to a high temperature.
Tungsten boride has comprehensive properties such as high melting point, high hardness and chemical stability. It is only a new superhard material with a high melting point. It is an important military bulletproof material.
For more than 50 years, it has been considered that the rich phase diagram of tungsten alloys, the structure of different phases is also ever-changing.
The highest boride is WB4, which has a three-dimensional grid structure of boron atoms. We put the first the principle calculation is combined with the thermodynamic stability, and the thermodynamic stability and mechanical properties of the possible structure of the tungsten carbide system are systematically studied:
The highest boride to identify tungsten should be WB3 composed of two-dimensional plane boron atoms, not WB4 composed of three-dimensional boron atom grids. It was found that the shear modulus in the borate system of tungsten transformed its formation energy. Increase, revealing that the mechanical properties are closely related to their thermodynamic stability.
Due to the free diffusion coefficient of WB2, the total synthesis of dense tungsten diboride is mostly achieved by sintering technology under high temperature and high-pressure conditions. In this way, it is reduced and the cost is too high; instead, because B will volatilize at high temperature.
Therefore, it is difficult to grasp the content of boron to prepare WB2 bulk materials directly from tungsten powder and boron powder.
It may also generate hypoborate during the sintering process, and compact bulk material with WB2 as the main phase cannot be obtained. Feel free to send an inquiry to get the latest price if you would like to buy Tungsten Boride WB2 powder in bulk.

How is Tungsten Boride WB2 produced?
1. Using metal tungsten and boron as raw materials, fully mix and grind the two, heat and react at above 1400 ℃ to obtain tungsten boride, continue to react to form W2B, and then cool and crush to obtain the product.
2. Tungsten is mixed with stoichiometric boron powder at a molar ratio of W: B=2:1 and sintered in a vacuum or argon atmosphere at 1200 to 1300°C to obtain two tungsten boride.
3. Use the solid phase method. Tungsten boride is prepared from metal tungsten and boron. The reaction formula is as follows. The stoichiometric metal tungsten powder and elemental boron are fully mixed, ground, and molded, and heated and reacted at a temperature above 1400°C to obtain tungsten boride. Continue the reaction to generate W2B, which is cooled and crushed to obtain the product.

Tungsten boride WB2 powder Feature 

Tungsten boride powder Molecular formula: WB2

Tungsten boride powder CAS NO:12007-09-9

Tungsten boride powder density:10.77g/cm3

Tungsten boride powder melting point:2900℃

Tungsten boride powder Solubility and Stability

Does not dissolve in water. Dissolved in aqua regia and certain concentrated acid.100 ℃ can be chlorine gas decomposition

Tungsten boride powder Purity: >99%

Tungsten boride powder Particle size: 10-20um


Applications of Tungsten Boride WB2:
Wear-resistant coating for wear parts and semiconductor thin film.
WB series compounds have a high melting point, high hardness, high conductivity, wear resistance, high-temperature resistance and corrosion resistance. They also have comprehensive neutron and gamma-ray shielding properties, so they are widely used in structural materials, wear-resistant materials, and electrodes. Materials and other fields. Tungsten boride is obtained by the direct reaction of metal tungsten and element boron heated by an electric furnace. It has the excellent properties of W-B series compounds and has broad application prospects in the future.
1) Prepare a workpiece with a tungsten boride-rich coating, including a workpiece substrate, and a tungsten layer, a tungsten boride gradient layer, and a tungsten boride coating that are sequentially arranged on the workpiece substrate; In the direction of the thickness of the tungsten layer, the boron content in the tungsten boride gradient layer gradually increases; the unique coating structure can make the bonding strength between the layers high, and the elastic modulus and thermal expansion between the layers The coefficient changes gradually from the substrate to the top film, reducing the overall coating stress to zero and improving the toughness and bonding force of the boride-rich tungsten coating.
2) To prepare a hard material of tungsten diboride, the method first uses a mechanochemical method to synthesize tungsten diboride powder at room temperature with high-purity tungsten (W) powder and boron (B) powder as raw materials, and then in argon Under a protective atmosphere, high-temperature sintering is used to densify the synthesized powder to produce a bulk material of tungsten diboride. This method can obtain compact tungsten diboride bulk material through sintering under normal temperature and pressure conditions. The prepared tungsten diboride bulk material has a series of excellent properties such as certain hardness, good stability and good neutron absorption effect. It has a wide range of applications in corrosion-resistant materials, cutting tools, and new shielding materials.
 
Storage Condition of Tungsten boride WB2 powder:
The damp reunion will affect WB2 powder dispersion performance and using effects, therefore, tungsten boride WB2 powder should be sealed in vacuum packing and stored in cool and dry room, the tungsten boride WB2 powder can not be exposure to air. In addition, the WB2 powder should be avoided under stress.

Packing & Shipping of tungsten boride WB2 powder:
We have many different kinds of packing which depend on the tungsten boride WB2 powder quantity.
Tungsten boride WB2 powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Tungsten boride WB2 powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.

Tungsten Diboride Properties

Other Namestungsten boride, WB2 powder, tungsten boride WB2
CAS No.12007-09-9
Compound FormulaWB2
Molecular Weight205.5
AppearanceGray Black Powder
Melting Point2365 °C
Boiling PointN/A
DensityN/A
Solubility in H2ON/A
Vickers Hardness20 GPa
Exact Mass205.969544 g/mol
  
  
Tungsten Diboride Health & Safety Information
Signal WordN/A
Hazard StatementsN/A
Hazard CodesN/A
Risk CodesN/A
Safety StatementsN/A
Transport InformationN/A

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Elementary

High Purity Graphite Powder Flake Graphite C Powder CAS 7782-42-5

If you want to buy graphite powder, please contact us:sales1@rboschco.com


About High Purity Graphite Powder Flake Graphite C Powder:

The graphite crystals of natural flake graphite are scaly. They are transformed under high-intensity pressure and are divided into large-scale and fine-scale. It is one of the best flotation ore in nature, and high-grade graphite concentrate can be obtained through multiple grinding and selection. The floatability, lubricity and plasticity of this type of graphite are better than other types of graphite. Therefore, it has the greatest industrial value. The required pressure is usually greater than 1 gigapascal (75,000 psi), and the required temperature is usually greater than 750 degrees Celsius (1,380 F).

Since carbon deposits form natural flake graphite when they are under pressure and temperature, graphite is most commonly found in metamorphic rocks, and the deposits are fairly evenly distributed throughout the rock. Graphite has large flakes, large flakes, medium flakes and fine flakes. The graphite powder price is much cheaper.

Depending on the application, the purity and/or size of natural flake graphite may be more important. The spherical industry requires large-size and flake graphite, while the refractory industry mainly focuses on the flake size. Feel free to send an inquiry to get the latest price if you would like to buy Natural Flake Graphite C Powder in bulk.

How is High Purity Graphite Powder Flake Graphite C Powder produced?
The high purity and high carbon
natural flake graphite powder CAS 7782-42-5 is prepared by laser ablation method.

 Natural flake graphite is formed when carbon material is subjected to high pressure and high temperature. The carbon source material can be either organic or inorganic, although most commercially sourced flake graphite comes from organic deposits.

Specification of High Purity Graphite Powder Flake Graphite C Powder
graphite powder (Natural graphite)
graphite powder Purity: 99.985% 
graphite powder APS:1μm,3μm(Can be customized)
graphite powder Ash:<0.016%
graphite powder H2O~0.12%
graphite powder  Morphology: flaky
graphite powder Color: black

 

Item

Purity

APS

Color

Bulk Density

Morphology

SSA

Graphite powder (C) particles

99.985%

1μm

 Black

0.114g/cm3

Flake

26.12m2/g

 

Item

Purity

APS

Color

Bulk Density

Morphology

SSA

Graphite powder (C) particles

99.982%

3μm

 Black

0.115g/cm3

Flake

18.51m2/g


Application of High Purity Graphite Powder Flake Graphite C Powder
Natural Flake Graphite is widely used in the fields of conductive coatings, glass manufacturing, lubricant formation, metallic alloys, nuclear reactors, powder metallurgy, and structural materials.

Natural graphite has found uses as the marking material ("lead") in common pencils, in zinc-carbon batteries, in electric motor brushes, and in various applications.

Aluminum/graphite composites for bearings, pistons, and liners in engines;

Carbon adsorbents for gas chromatography;


Graphite powder for locks;


Cupper/graphite and silver/graphite nanocomposites for electrical brushes and contact strips;

Inorganic filler (graphite/polymer nanocomposites);

Support materials for precision metal powder catalysts Graphite/polymer nanocomposites for enhanced electrical conductivity;

Metal matrix composites for reduced friction.

Flake graphite is also used in vanadium redox batteries and nuclear reactors. Vanadium redox batteries use the chemical properties of 

vanadium and graphite to reliably store excess energy for a long time. Nuclear reactors wrap uranium in large graphite spheres.

Storage Condition of High Purity Graphite Powder Flake Graphite C Powder :
The damp reunion will affect C powder dispersion performance and using effects, therefore, natural flake graphite C powder should be sealed in vacuum packing and stored in cool and dry room, the natural flake graphite C powder can not be exposure to air. In addition, the C powder should be avoided under stress.

Packing & Shipping of High Purity Graphite Powder Flake Graphite C Powder :
We have many different kinds of packing that depend on the natural flake graphite C powder quantity.
Natural flake graphite C powder packing: vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Natural flake graphite C powder shipping: could be shipped out by sea, by air, by express as soon as possible once payment receipt.
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Natural Flake Graphite Powder C Properties

Other Namesnature flake graphite, natural graphite, flake graphite
CAS No.7782-42-5
Compound FormulaC
Molecular Weight12.01
Appearance Black solid
Melting Point3652 - 3697 °C (sublimes)
Boiling Point4200 °C
Density1.8 g/cm3
Solubility in H2O (water)N/A
Electrical ResistivityN/A
Electronegativity2.55 Paulings
Specific HeatN/A
Thermal Conductivity6.0 W/m-K
Thermal Expansion4.9 µm/m-K
Young's Modulus21 GPa
Exact MassN/A
Heat of Vaporization128 K-Cal/gm atom at 4612 °C
  
  

Natural Flake Graphite Powder C Health & Safety Information

Safety WarningN/A
Hazard StatementsN/A
Hazard CodesN/A
Risk CodesN/A
Safety StatementsN/A
RTECS NumberN/A
Transport InformationN/A
WGK GermanyN/A

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Boride Powder

Boron Carbide B4C Powder CAS 12069-32-8

B4C powder MF: B4C

B4C powder CAS No: 12069-32-8

B4C powder EINECS No: 235-111-5

B4C powder Appearance: Grey black powder

B4C powder Particle size: Can be customized according to your requirements. 

 

About Boron Carbide B4C Boride Powder:
Boron carbide formula is b4c, boron carbide properties is low density, high strength, high temperature stability and good chemical stability. Therefore,boron carbide is widely used in wear-resistant materials, ceramic reinforcing phases, especially in lightweight armor, reactor neutron absorbers, etc. In addition, compared with diamond and cubic boron nitride, boron carbide is easy to manufacture and low cost, so it is more widely used. It can replace expensive diamonds in some places and is commonly used in grinding, grinding, drilling and other aspects. If you want to buy boron carbide, please send inquiry to sales1@rboschco.com


Our company also can supply boron carbide rodboron carbide sheet.

B4C powder possesses high purity, small particle size distribution, high specific surface area; B4C powder is a synthetic ultra rigid materials, the hardness is 9.46; 56-6200Kg/mm2 microhardness, proportion was 252 g/cm3, melting is 2,250 degrees Celsius.
Chemical properties, non-magnetic, resistant to high and low temperatures, strong acids and alkalis. In addition, boron carbide can effectively absorb neutrons without emitting gamma rays that are harmful to the human body, and it will not form secondary radiation pollution. Feel free to send an inquiry to get the latest price if you would like to buy Boron Carbide B4C Boride Powder in bulk. The hardness is only less than the diamond. Boron carbide is one of the most stable substances to acid, and it is stable in all concentrated or dilutes acid or alkali aqueous solutions. Boron carbide is basically stable below 800°C in an air environment. The boron oxide formed by its oxidation at a higher temperature is lost in the gas phase, leading to its instability and oxidation to form carbon dioxide and boron trioxide.


How is Boron Carbide B4C Boride Powder produced?
Boron Carbide B4C Boride Powder is produced by reducing boron oxide with carbon at high temperatures in an electric furnace. After grinding, the black powder is solidified by pressing at temperatures exceeding 2,000°C (3,630°F). melting point of boron carbide is approximately 2,350°C (4,260°F).
 

Specifications of Boron Carbide B4C powder

Item

Purity

APS

SSA

Color

Morphology

Zeta Potential

Bulk Density

B4C powder>99%

50nm

42m2/g

Black

hexagonal

-26mV

0.1g /cm3

 

Other size of Boron Carbide B4C powder: 500nm

 

Applications of Boron Carbide B4C Boride Powder:
 
Fine and advanced abrasive materials
Because of the high grinding efficiency of boron carbide, it is mainly used as a grinding medium in the grinding process of materials, such as: grinding, grinding, drilling and polishing of hard materials such as gems, ceramics, knives, bearings, and cemented carbides.

Industrial ceramic materials
Products made of boron carbide powder: sandblasting nozzles, sealing rings, nozzles, bearings, plungers of mud pumps, pestles and rocket launchers, ceramic coatings for warships, helicopters, etc., as a new type of material. It has the characteristics of high melting point, high hardness, high elastic modulus, strong wear resistance, and good self-lubricating properties and is widely used in sandblasting machinery, electronics, information, aerospace, automobile and other industries.

Shielding and control materials for the nuclear industry
Boron carbide powder material has a large thermal neutron capture section, excellent neutron absorption and radiation resistance, and is internationally recognized and recommended as a nuclear reactor control material and shielding material.

Bulletproof armor
Due to its high strength and small specific gravity, it is especially suitable for use in lightweight bulletproof armor, such as the protection of aircraft, vehicles, ships and human bodies.

Improve the life of mechanical parts
Combine boron carbide powder with metal to produce metal-based alloy powder. After special surface treatment of this material, the original mechanical parts are more resistant to wear and corrosion resistance to acid and alkali.

Special absorber provides energy
Boron carbide, also known as "black gold", is used as a power source in powder form as a solid fuel for the rocket.

Chemical industry additives
Due to its stable chemical properties, boron carbide does not react with acid and alkali solutions and has a high chemical potential, so it is widely used in the production of other boron-containing materials, such as zirconium boride and titanium boride.

Advanced refractories
Because of its anti-oxidation and high-temperature resistance, boron carbide is used as a high-grade shaped and unshaped refractory material and is widely used in various fields of metallurgy, such as steel stoves and kiln furniture.


Storage Condition of Boron Carbide B4C powder:
Damp reunion will affect boron carbide ceramics dispersion performance and using effects, therefore, boron carbide B4C powder should be sealed in vacuum packing and stored in cool and dry room, the boron carbide B4C powder can not be exposure to air. In addition, the boron carbide B4C powder should be avoided under stress.

Packing & Shipping of Boron Carbide B4C powder:
We have many different kinds of packing which depend on the boron carbide B4C powder quantity.
Boron carbide B4C powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Boron carbide B4C powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.

Boron Carbide Properties

Other NamesB4C, B4C powder, black diamond, boron carbide powder,
boron-carbon refractory ceramic
CAS No.12069-32-8
Compound FormulaB4C
Molecular Weight55.26
AppearanceGray to Black Powder
Melting Point2763 °C
Boiling Point3500 °C
Density2.52 g/cm3
Solubility in H2OInsoluble
Electrical Resistivity0 to 11 10x Ω-m
Poisson's Ratio0.17-0.18
Tensile Strength350 MPa (Ultimate)
Thermal Conductivity31 to 90 W/m-K
Thermal Expansion4.5 to 5.6 µm/m-K
Vickers Hardness26 Mpa
Young's Modulus240 to 460 Gpa
Exact Mass56.037222
  
  

Boron Carbide Health & Safety Information

Signal WordWarning
Hazard StatementsH332
Hazard CodesXi
Risk Codes20
Safety Statements22-39
RTECS NumberN/A
Transport InformationN/A
WGK Germany3

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Elementary

Amorphous Boron B Powder CAS 7440-42-8

About Amorphous Boron B Powder:
Boron powder is a black or dark brown powder, which can react with fluorine at room temperature and will not be corroded by alkali and hydrofluoric acid aqueous solutions. Boron powder is also called amorphous boron. Boron has a high mass calorific value and volume calorific value. It is a light brown to gray-black powder with relatively active chemical properties, but it is relatively stable at room temperature and will be oxidized when the temperature reaches 300 degrees Celsius. The ignition level is very high, requiring 700 degrees Celsius to ignite. Boron powder can react with oxygen, nitrogen and sulfur, or it can directly combine with certain metals to form certain borides. We supply boron powder for sale.


If you want to know the boron powder price and buy boron powder, please send inquiry to sales1@rboschco.com
 
Amorphous boron powder is a brown powder; amorphous boron is a brown powder. Amorphous boron is a brown powder. Crystalline boron is black, very hard (approximately 9.5 at Mohs hardness), and has a poor conductor at room temperature. Element boron is used as a dopant in the semiconductor industry, and boron compounds play an important role as light structural materials, pesticides and preservatives, and chemical synthesis reagents. Feel free to send an inquiry to get the latest price if you would like to buy Amorphous Boron B Powder in bulk.

Properties of Amorphous Boron B Powder :
Elemental boron CAS 7440-42-8 is a black or dark brown powder, pure boron powder is 95%. When it is oxidized in the air, it will prevent the internal boron from continuing to oxidize due to the formation of a boron trioxide film. It can react with fluorine at normal temperature and is not corroded by hydrochloric acid and hydrofluoric acid aqueous solution. Boron is insoluble in water, powdered boron is soluble in boiling nitric acid and sulfuric acid, and most molten metals such as copper, iron, manganese, aluminum, and calcium.


Amorphous Boron Powder MF:B

 Amorphous Boron Powder MW:10.81

 Amorphous Boron Powder Melting point:2300 ℃ ±2  ℃

 Amorphous Boron Powder Sublimation temperature:2550  ℃

 Amorphous Boron Powder Relative density:2.34-2.37

 Amorphous Boron Powder Solubility: Insoluble in water, hydrochloric acid, ethanol and ether,  soluble in cold 

 concentrated alkali solution decompose into hydrogen, by concentrated sulfuric acid, nitric acid oxidation into boric acid.

 

 Product features of Amorphous Boron powder:

  The quality is stable and reliable.
  This product can be in stored for a long time.
  According to user requirements, processing customized different particle size of products.

Technical Parameter of Amorphous Boron B powder :

Chemical CompositionBPSSiFeMgOC
Test Result (%)950.050.020.110.150.210.150.17

 

How is Amorphous Boron B Powder produced?
There are two main techniques to obtain pure boron powder: via-gas and magnesiothermic reaction. The first technique uses hydrogen gas to reduce gaseous boron trichloride (BCl3), whereas the latter uses a combination of heat and magnesium to reduce the boron trioxide (B2O3) to elemental boron.

Applications of Amorphous Boron B Powder:
Boron powder is commonly used in metal smelting, electronic product manufacturing, ceramic manufacturing, chemical industry and nuclear industry, etc. The specific functions of boron nitride are as follows:

1. Boron powder can be used to make various boron-containing compounds, used as raw materials for the production of boron fibers, and important raw materials for the production of high-purity boron halide;

2. Boron powder is added in the form of a compound as a gas scavenger for the smelting of special alloy steel or molten steel;

3. Boron powder is used as high-energy fuel for rocket spacecraft,

4. Boron powder is used as the ignition pole of the ignition tube in the electronics industry;

5. Boron powder replaces precious or scarce metals;

6. Boron powder is used as a protective material for the atomic energy industry and the control rod in the atomic reactor;

7. Boron powder also can be used as a catalyst for organic chemical reactions.
 

Storage Condition of Amorphous Boron B powder :
Damp reunion will affect B powder dispersion performance and using effects, therefore, amorphous boron B powder should be sealed in vacuum packing and stored in cool and dry room, the amorphous boron B powder can not be exposure to air. In addition, the amorphous boron B powder should be avoided under stress.

Packing & Shipping of Amorphous Boron B powder :
We have many different kinds of packing which depends on the amorphous boron powder quantity.
Amorphous boron B powder packing: vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Amorphous boron B powder shipping: could be shipped out by sea , by air, by express as soon as possible once payment receipt.

20220520095914

 

Amorphous Boron Powder Properties

Other NamesBoron Powder, amorphous boron
CAS No.7440-42-8
Compound FormulaB
Molecular Weight10.811
AppearanceDark Brown
Melting Point2079 °C
Boiling Point2550 °C
Density2.34 g/cm3
Solubility in H2ON/A
Electrical Resistivity1.8 x 1012 microhm-cm @ 0 °C
Poisson's RatioN/A
Specific Heat0.245 Cal/g/K @ 25 °C
Thermal Conductivity0.274 W/cm/K @ 298.2 K
Thermal Expansion5–7 µm·m-1·K-1 @ 25 °C
Young's ModulusN/A
  
  

Amorphous Boron Powder Health & Safety Information

Signal WordWarning
Hazard StatementsH228-H302+H332-H335
Flash PointNot applicable
Hazard CodesN/A
Risk CodesN/A
Safety StatementsN/A
RTECS NumberED7350000
Transport InformationDOT
WGK GermanyNWG

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Boride Powder

Calcium Hexaboride CaB6 Powder CAS 12007-99-7

About Calcium Hexaboride CaB6 Powder:
Calcium hexaboride (calcium boride) is a compound of calcium and boron, with the chemical formula CaB6. Due to its high conductivity, hardness, chemical stability and melting point, it is an important material. It is a black, shiny, chemically inert powder with low density. It has a typical cubic structure of six metal boride, with octahedral units of six boron atoms and calcium atoms.

CaB6 has been investigated in the past due to a variety of peculiar physical properties, such as superconductivity, valence fluctuation and Kondo effects. However, the most remarkable property of calcium boride is its ferromagnetism. It occurs at unexpectedly high temperatures (600K) and with a low magnetic moment. The origin of this high-temperature ferromagnetism is the ferromagnetic phase of the dilute electron gas, linkage to the presumed excitonic state in calcium boride, or external impurities on the surface of the sample. The impurities might include iron and nickel, probably coming from impurities in the boron used to prepare the sample.

CaB6 is insoluble in H2O, MeOH (methanol), and EtOH (ethanol) and dissolves slowly in acids. Its microhardness is 27 GPa, Knoop hardness is 2600 kg/mm2), the Young modulus is 379 GPa, and electrical resistivity is greater than 2·1010 Ω·m for pure crystals. CaB6 is a semiconductor with an energy gap estimated at 1.0 eV. The low, semi-metallic conductivity of many CaB6 samples can be explained by unintentional doping due to impurities and possible non-stoichiometry. Feel free to send an inquiry to get the latest price if you would like to buy Calcium Hexaboride CaB6 Powder in bulk.

Product Performance of Calcium Hexaboride CaB6 Powder:

Calcium boride has the characteristics of high melting point and high hardness. Its physical and chemical properties are quite stable. When calcined in air, sub-micron CaB6 will only gain weight after 800 degrees Celsius and is not easy to oxidize. CaB6 is generally insoluble in hydrochloric acid and sulfuric acid, so technically to remove impurity materials by hot hydrochloric acid, but CaB6 is soluble in nitric acid.


How is Calcium Hexaboride CaB6 Powder produced?
One of the main reactions of industrial production is:
CaO + 3 B2O3 + 10 Mg→CaB6 + 10 MgO
Other methods of producing CaB6 powder include:

Calcium or calcium oxide reacts directly with boron at 1000°C;
Ca + 6B→CaB6
Ca(OH)2 reacts with boron under a vacuum of about 1700°C (carbothermal reduction);
Ca(OH)2 + 7B→CaB6 + BO(g)+ H2O(g)
The reaction of calcium carbonate and boron carbide under vacuum above 1400°C (Carbothermal reduction)
CaO and H3BO3 react with Mg to 1100°C.
Low temperature (500°C) synthesis
CaCl2 + 6NaBH4→CaB6 + 2NaCl + 12H2 + 4Na
As a result, the material quality is relatively poor.

In order to produce, for example, pure
calcium boride single crystals used as cathode materials, the CaB6 powder thus obtained is further recrystallized and purified by zone melting technology. The typical growth rate is 30 cm/h, and the crystal size is about 1x10 cm.
Single crystal CaB6 nanowires (diameter 15-40 nm, length 1-10 microns) can be obtained by pyrolyzing diborane (B2H6) on calcium oxide (CaO) powder at 860-900°C in the presence of Ni catalyst.


Technical Parameter of Calcium Hexaboride CaB6 Powder:

Product NameMFPurityParticle SizeBulk DensityMelting PointColor
Calcium HexaborideCaB699.5%-325 mesh2.33 g/cm32230℃Gray Black

 

Application of Calcium Hexaboride CaB6 Powder:

1. Used as a boron-containing additive for dolomite charcoal and magnesium dolomite charcoal refractories to resist oxidation, erosion and improve the thermal strength.
2. Used as a deoxidizing and degassing agent for highly conductive red copper to improve conductivity and strength.
3. Used as a new type of material for preventing neutrons in the nuclear industry.
4. Used as a new type of semiconductor material in spin electronic components with a temperature of 900K.
5. Used as a raw material for manufacturing boron trichloride (BCl3) and amorphous boron.
6. Used as a raw material for manufacturing high-purity metal borides (TiB2, ZrB2, HfB2, etc.) and high-purity boron alloys (Ni-B, Co-B, Cu-B, etc.).
7. Used to manufacture a mixture of catalyst-containing calcium-boron nitride (Ca3B2N4) and hexagonal boron nitride, and to produce crystal cubic boron nitride with excellent performance.

 

Storage Condition of Calcium Hexaboride CaB6 Powder:
Damp reunion will affect CaB6 powder dispersion performance and using effects, therefore, calcium hexaboride CaB6 powder should be sealed in vacuum packing and stored in cool and dry room, the calcium hexaboride can not be exposure to air. In addition, the CaB6 powder should be avoided under stress.

Packing & Shipping of Calcium Hexaboride CaB6 Powder:
We have many different kinds of packing which depends on the calcium hexaboride CaB6 powder quantity.
Calcium hexaboride CaB6 powder packing: vacuum packing, 1kg/bag, 25kg/barrel, or as your request.
Calcium hexaboride CaB6 powder shipping: could be shipped out by sea , by air, by express as soon as possible once payment receipt.






 

Calcium Hexaboride Properties

Other Nameszirconium boride, ZrB2 powder
CAS No.12007-99-7
Compound FormulaCaB6
Molecular Weight104.944
AppearanceBlack Powder
Melting Point2235 °C
Boiling PointN/A
Density2.3-2.45 g/cm3
Solubility in H2OInsoluble
Exact MassN/A
  
  

Calcium Hexaboride Health & Safety Information

Signal WordWarning
Hazard StatementsH315-H319-H335
Hazard CodesXi
Risk CodesN/A
Safety StatementsN/A
Transport InformationNONH for all modes of transport

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Boride Powder

Zirconium Diboride ZrB2 Powder CAS 12045-64-6

About Zirconium Diboride ZrB2 Powder:
Zirconium boride powder is a chemical substance and its molecular formula is ZrB2. Nature gray hard crystals. Zirconium boride has three components: zirconium monoboride, zirconium diboride, and zirconium tribromide. Only zirconium diboride is stable in a wide temperature range. Industrial production is mainly based on zirconium diboride. Zirconium diboride is a hexagonal crystal, gray crystal or powder, with a relative density of 5.8 and a melting point of 3040°C. High-temperature resistance, high strength at room temperature and high temperature. Good thermal shock resistance, low resistance, anti-oxidation at high temperature. The melting point is about 3000°C. With metallic luster.
 
Zirconium diboride powder(ZrB2) is a highly covalent refractory ceramic material with a hexagonal crystal structure. ZrB2 is an ultra-high temperature ceramic (UHTC) with a melting point of 3246°C. Coupled with a lower density of ~6.09 g/cm3 (the measured density may be higher due to ha impurities) and good high-temperature strength, it is suitable for high-temperature aerospace applications, such as hypersonic flight or rocket propulsion systems, for example, Furnace components, high-temperature electrodes, rocket engines, thermal protection structures for spacecraft with temperature capabilities exceeding 1800°C, and heavy-wear applications.
 
It is an unusual ceramic with relatively high thermal and electrical conductivity and has the same characteristics as the titanium diboride and diboride shares of the same structure. In addition to its fire resistance, good thermal conductivity (>50 W/m/K), inertness to molten metal, good thermal shock resistance, and high electrical conductivity (~105 S/cm), ZrB2 can also pass EDM basic ceramic molding.
 
ZrB2 parts are usually hot-pressed (applying pressure to the heated powder) and then machined to form. The covalent nature of the material and the presence of surface oxides hinder the sintering of ZrB2. The presence of surface oxides will increase the coarsening of crystal grains before densification during the sintering process. Pressureless sintering of ZrB2 is possible. Sintering additives such as boron carbide and carbon will react with surface oxides, thereby increasing the driving force for sintering, but the mechanical properties will decrease compared to hot-pressed ZrB2. Feel free to send an inquiry to get the latest price if you would like to buy Zirconium Diboride ZrB2 Powder in bulk.

Properties of Zirconium Diboride ZrB2 powder CAS 12045-64-6:
Molecular formula: ZrB2
Molar mass: 112.85 g/mol
Appearance: grey-black powder
Density: 6.085 g/cm3
Melting point: 3246 °C
Solubility in water: Insoluble
Crystal structure: Hexagonal, hP3
Space group: P6/mmm, No. 191

Features of Zirconium Diboride ZrB2 powder:
TiB2, ZrB2, HfB2, VB2, NbB, NbB2, TaB, TaB2, CrB2, Mo2B5, W2B5, Fe2B, FeB, CoB, Co2B, NiB, Ni2B, Ni2B, LaB6, UB4, UB2.
Zirconium diboride (ZrB2) is a highly covalent refractory ceramic material with a hexagonal crystal structure. ZrB2 is an ultra high temperature ceramic (UHTC) with a melting point of 3246 °C. This along with its relatively low density of ~6.09 g/cm3 (measured density may be higher due to hafnium impurities) and good high temperature strength makes it a candidate for high temperature aerospace applications such as hypersonic flight or rocket propulsion systems. It is an unusual ceramic, having relatively high thermal and electrical conductivities, properties it shares with isostructural titanium diboride and hafnium diboride.

How is Zirconium Diboride ZrB2 Powder produced?
ZrO2 and HfO2 are reduced to their respective diboron silanes by metal thermal reduction. Use cheap precursor materials and react according to the following reactions:
 
ZrO 2 + B 2 O 3 + 5Mg→ZrB 2 + 5MgO
 
The precursor materials for this reaction (ZrO 2 / TiO 2 / HfO 2 and B 4 C) are cheaper than those required for stoichiometric and boron thermal reactions. Prepare ZrB2 at a temperature higher than 1600°C for at least 1 hour through the following reaction:
 
2ZrO 2 + B 4 C + 3C→2ZrB 2 + 4CO
 
This method requires a slight excess of boron because some boron is oxidized during the boron carbide reduction process. It is also observed that ZrC is the product of the reaction, but if the reaction is carried out under an excess of 20-25% of B4C, the ZrC phase disappears and only ZrB2 remains. The lowest synthesis temperature (~1600°C) will produce UHTC with finer dimensions and better sinterability. Before boron carbide reduction, the boron carbide must be ground to promote the oxide reduction and diffusion process.
 
ZrO2 and HfO2 can be dispersed on the boron carbide polymer precursor before the reaction. in. Heating the reaction mixture to 1500°C results in the formation of boron carbide and carbon in situ, and the subsequent reduction of ZrO2 to ZrB2.
 
The gas phase is used to reduce the vapors of zirconium tetrachloride and boron trichloride when the substrate temperature is higher than 800°C. Recently, alternative ZrB2 films can also be prepared by physical vapor deposition.

Applications of Zirconium Diboride ZrB2 Powder:
Zirconium boride has high hardness, high thermal conductivity, good oxidation resistance and good corrosion resistance. Zirconium diboride is used in special ceramic refractory industries, nuclear industry, aerospace industry and military industries. Zirconium diboride can be used as a surface coating for rolling balls and smooth solid materials.
 
Carbon fiber reinforced
zirconium diboride composites exhibit high density, while silicon carbide fiber-reinforced zirconium diboride composites are brittle and show catastrophic damage.
 
Zirconium diboride (ZrB2) can be used as thin-film electronic components for sensors, actuators and micro-systems operating in high-temperature environments because it has metal-like conductivity and has a melting temperature of 3245°C.
Other applications of Zirconium Diboride ZrB2 Powder:
(1) zirconium diboride powder is used to produce materials for ceramics.
(2) zirconium diboride powder can be used as a neutron absorber.
(3) zirconium diboride powder can be used as an abrasion-resistant coating.
(4) zirconium diboride powder can be used as crucible lining and anticorrosive chemical equipment.
(5) zirconium diboride powder can be used as anti-oxidation compound material.
(6) zirconium diboride powder can be used as a refractory material, especially in the status of anticorrosion of molten metals.
(7) zirconium diboride powder can be used as a thermally enhanced additive.
(8) zirconium diboride powder can be used for high-temperature resistance.
(9) zirconium diboride powder can be used as a special type of dope against high temperature, corrosion and oxidation.

Storage Condition of Zirconium Diboride ZrB2 Powder:
Damp reunion will affect
ZrB2 powder dispersion performance and using effects, therefore, zirconium diboride ZrB2 powder should be sealed in vacuum packing and stored in cool and dry room, the zirconium diboride ZrB2 powder can not be exposure to air. In addition, the ZrB2 powder should be avoided under stress.

Packing & Shipping of Zirconium Diboride ZrB2 Powder:
We have many different kinds of packing which depends on the zirconium diboride ZrB2 powder quantity.
Zirconium diboride ZrB2 powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
Zirconium diboride ZrB2 powder shipping:could be shipped out by sea , by air, by express?as soon as possible once payment receipt.

Zirconium Diboride Properties

Other Nameszirconium boride, ZrB2 powder
CAS No.12045-64-6
Compound FormulaZrB2
Molecular Weight112.8
AppearanceGray to Black Powder
Melting Point3246 °C
Boiling PointN/A
Density6.09 g/cm3
Solubility in H2ON/A
Exact Mass111.923315 g/mol
  
  

Zirconium Diboride Health & Safety Information

Signal WordWarning
Hazard StatementsH228
Hazard CodesF
Risk CodesN/A
Safety StatementsN/A
Transport InformationUN3178 4.1/PG III

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Boride Powder

Aluminum Magnesium Boride BAM AlMgB14 Powder

About AlMgB14 alloy powder:
Aluminum boride or Al3Mg3B56, commonly known as BAM, is a compound of aluminum, magnesium, and boron. Although its nominal formula is AlMgB14, its chemical composition is closer to Al0.75Mg0.75B14. It is a highly wear-resistant ceramic alloy with an extremely low sliding friction coefficient, reaching a record value of 0.04 in the unlubricated AlMgB14-TiB2 composite material, and a record value of 0.02 in the lubricated AlMgB14-TiB2 composite material. BAM was first reported in 1970. It has an orthogonal structure and each unit cell has four icosahedral B12 units. The thermal expansion coefficient of this super hard material is comparable to other widely used materials such as steel and concrete. Biomedicalmaterialsprogram is a trusted global Aluminum-Magnesium Boride BAM AlMgB14 Powder supplierFeel free to send an inquiry about the latest price of AlMgB14 at any time.
 
How is AlMgB14 alloy Powder Produced?
AlMgB14 aluminum magnesium boride material has a better anti-wear property than diamond and is a new type of anti-degradation material. AlMgB14 has a density of only 2.66 g/cm3, which is much lower than other superhard materials (such as diamond and cubic boron nitride), and does not react with carbon steel, stainless steel, or titanium alloy at temperatures up to 1300 °C, and has high thermal stability.
AlMgB14 aluminum magnesium boride has a much higher conductivity than other conventional super hard materials and is basically equivalent to the conductivity of poly-silicon. The most attractive aspect of AlMgB14 is its low price, which is 5 to 10 times lower than diamond and cubic boron nitride. These excellent properties make AlMgB14 not only wearable,
Traditional fields such as protective coatings and cutting equipment manufacturing can also be widely used in advanced scientific fields such as thermoelectric devices, photodetectors, neutron masks, micro machines, and aerospace key components.
 
Applications of AlMgB14 alloy Powder:
BAM is commercially available, and research is being conducted for more potential applications. For example, the pistons, seals, and vanes on the pump can be coated with BAM or BAM + TiB2 to reduce friction between parts and increase wear resistance. The reduction in friction will reduce energy consumption. BAM can also be coated on cutting tools. The reduced friction will reduce the force required to cut the object, extend tool life, and may allow an increase in cutting speed. It has been found that only 2-3 microns thick coating can increase efficiency and reduce cutting tool wear.
Ternary Boride AlMgB14 alloy powder is one of the research hotspots in the field of superhard materials in the world. It has attracted widespread attention from scholars at home and abroad in recent years. Unlike traditional metastable superhard materials such as diamond and cubic boron nitride, AlMgB14 superhard materials are equilibrium materials with high hardness, low density, low coefficient of friction, high thermal stability, and good thermoelectric properties.

Properties and application of AlMgB14 alloy powder:
AlMgB14 aluminum magnesium boride material has a better anti-wear property than diamond and is a new type of anti-degradation material. AlMgB14 has a density of only 2.66 g/cm3, which is much lower than other superhard materials (such as diamond and cubic boron nitride), and does not react with carbon steel, stainless steel, or titanium alloy at temperatures up to 1300 °C, and has high thermal stability.
AlMgB14 aluminum magnesium boride has a much higher conductivity than other conventional superhard materials and is basically equivalent to the conductivity of polysilicon. The most attractive aspect of AlMgB14 is its low price, which is 5 to 10 times lower than diamond and cubic boron nitride. These excellent properties make AlMgB14 not only wearable,
Traditional fields such as protective coatings and cutting equipment manufacturing can also be widely used in advanced scientific fields such as thermoelectric devices, photodetectors, neutron masks, micromachines, and aerospace key components. 

Storage Condition of AlMgB14 Aluminum Magnesium Boride Powder:
The damp reunion will affect AlMgB14 aluminum magnesium boride dispersion performance and using effects, therefore, AlMgB14 aluminum magnesium boride powder should be sealed in vacuum packing and stored in the cool and dry room, the AlMgB14 aluminum magnesium boride can not be exposure to air. In addition, the AlMgB14 powder should be avoided under stress.

Packing & Shipping of AlMgB14 Aluminum Magnesium Boride Powder:
We have many different kinds of packing which depend on the AlMgB14 aluminum magnesium boride powder quantity.
AlMgB14 aluminum magnesium boride powder packing:vacuum packing, 100g, 500g or 1kg/bag, 25kg/barrel, or as your request.
AlMgB14 aluminum magnesium boride powder shipping: could be shipped out by sea, by air, by express, as soon as possible once payment receipt.

Aluminum Magnesium Boride Properties

Other NamesAlMgB14 Powder
CAS No.N/A
Compound FormulaAlMgB14 
Molecular Weight202.64
AppearanceGray to Black Powder
Melting PointN/A
Boiling PointN/A
DensityN/A
Solubility in H2ON/A
Thermal Expansion9×10-6 K-1
Vickers HardnessN/A
Young's ModulusN/A
  
  

Aluminum Magnesium Boride Health & Safety Information

Signal WordWarning
Hazard StatementsH302
Hazard CodesXi
Risk CodesN/A
Safety StatementsN/A
Transport InformationNONH for all modes of transport

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