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The Properties And Application of Titanium nitride

The titanium nitride structure (TiN), which is similar to that of NaCl, has a lattice constant, a = 0.4241 nm. Titanium-atoms are found at the corners tops of this face-centered cubic. TiN has a nonstoichiometric composition, which is TiN0.37 - TiN1.16. Changes in nitrogen content are possible within a specified range, without affecting the structure of TiN. The TiN powder has a yellowish-brown color, while ultrafine powders are black and the TiN crystals have a golden yellow colour. TiN has an excellent thermal shock resistance, a melting temp of 2950degC and a density of 5-4.44g/cm3. TiN has a much higher melting temperature than most of the transition metals, but it also has a lower density. This makes TiN a heat-resistant metal. The TiN crystal is very similar to TiC. However, the C atoms are replaced with N atoms.
Nature Introduction

TiN is an extremely stable compound. It will not reacted with metals, such as iron and chromium at high temperature. Also, TiN crucibles won't react with acidic Slag in CO and N2 atmospheres. It can be used with alkaline or acidic slag. TiN, when heated under vacuum, loses nitrogen and becomes titanium nitride that has a lower nitrogen content.

TiN is attractively golden in color. It also has a very high melting temperature, a good chemical stability, and a low wetting ability to metals. It is a superconductor with high electrical conductivity. It is also superconducting material.

Tech Co., Ltd. () is an experienced Titanium nitride manufacturer and supplier with over 12 year experience in research and product development. You can send us an email if you're looking for Titanium Nitride of high quality.

2023-08-06

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Application of silicon carbide nanomaterials

Silicon carbide is a nanomaterial that has many outstanding properties. These include high thermal conductivity; strong thermal stability; oxidation resistance and chemical corrosion resistance. It also has a low thermal expansion factor, high thermal and electrical conductivity at critical temperatures, a large electric field, and a small dielectric constant. Silicon carbide single-crystal devices are widely applicable in various special environments, including aerospace, radar communications and automobiles. They also have applications in high-temperature radiation and oil drilling. Its optical, electrical, and mechanical properties, which are unique, have a wide range of potential applications. 1. The mechanical properties and application of nanosilicon carbide composite materials

Silicon carbide whiskers possess excellent properties, including high strength and hardness, as well as heat resistance, corrosion resistant, and stable chemical characteristics. It has found wide application in the chemical, chemical, and aerospace industries. It is also called "King of Whiskers". Scientists are able to calculate and measure the mechanical properties of one whisker at a microscopic level. Studies have shown the linear silicon-carbide ceramics are superior to bulk silicon-carbide ceramics in terms of tensile and bend strength. The carbide silicon nanowires have excellent performance and can be used to reinforce high molecular materials such as ceramics, metals, and polymers.

The use of silicon carbide in ceramic composite materials improves the heat resistance of the ceramic material and its high-temperature brittleness.

2. Nanosilic carbide as a catalyst carrier

It has always been important to examine the high specific surface areas of the carrier catalyst. High specific surface area silicon carbide has a better performance when used as a carrier for catalysts due to its excellent material performance. Comparing SiC to traditional carriers alumina, silica oxide, etc. the SiC material's superiority is mainly shown in the following: 1) high heat resistance and thermal conductivity; 2) high chemical stability; 3) strong mechanical strength; not easily broken; 4) low rate of thermal expansion.

3. Field emission properties nano-silicon carbide

SiC Nanowire Array has low turn-on and threshold voltages, high current densities, stable field emissions performance and is ideal for field emission cathodes. It is widely used for microelectronics due to its chemical stability, high temperature, high pressure, and corrosion resistance.

4. Nano-Silicium Carbide: Optoelectronic Properties

The luminescent properties of silicon carbide were also discovered earlier. In a low-temperature environment, silicon carbide can emit blue light. Silicon carbide's wide bandgap is used by people to make light emitting diodes that look blue. The low luminous efficiency and weak blue light of silicon carbide are due to the indirect bandgap properties. In order to increase the luminous efficacy of silicon carbide, many improvements were devised. This includes the preparations of amorphous silica carbide as well as porous single crystal silicon carbide.

(aka. Technology Co. Ltd., a trusted global chemical supplier and manufacturer of high-quality Nanomaterials with over 12 year's experience, is a trusted source for super high quality chemicals. Silicon carbide manufactured by our company is of high purity with fine particles. Contact us if you need to.

2023-08-06

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The Properties and Main Application Fields of Microsilica

What is micro silica vapor?
Micro-silica Also known as silica or condensed fume, fume is a form of silica. The mine thermoelectric oven produces many gases, including SiO2 and Si, when ferroalloys (iron alloys) are used to smelt ferrosilicon or industrial silicon. It is formed through rapid oxidation. This by-product is produced during industrial smelting. It is necessary to recycle this entire process with the help of dust removal equipment and environmental protection gear. Encryption equipment is needed because of the low density.

What are the main applications of microsilica?

It is used widely in the refractory industries because it has excellent properties like high refractoriness. It is used for preparing high-temperature ceramics and ladle materials. Wang Tao et al. By using micro-silica and Al2O3 powder in a 3:2.5 ratio and a 1450degC sintering heat, they prepared high-purity mullite porous ceramics. Its compressive strength is 260.93MPa. The porosity of the material is 21%. The micro-silica can improve bulk density, strength, cohesion, and high temperature performance of refractory products. It can also be used to extend the service life and achieve internal digestion of dust produced by ferrosilicon or industrial silicon smelting companies.
Other North American companies also use pellets of silica and microsilica fume mixtures for the reduction of electric furnaces and the smelting silicon. The unit energy consumption of the product is unchanged, but the silicon recovery rate appears to be normal. Elkem in Norway will agglomerate micro-silica with water into pellets about 4 cm long, which are then reduced and smelted directly in an electrical furnace without any roasting or drying. Sintered ore can be produced at a higher temperature without any problems such as bursting. In a Russian factory, micro-silica fumes and liquid waste from paper pulp are mixed into pellets. They then undergo reduction smelting using an electric furnace. This production shows that pellets can be transported without breaking because they're stronger than normal materials. In Northern Europe a ferrochromium firm used the microsilica powder slurry from the electric furnace silica smelting method wet as the return source of silicon and mixed it together with chromium ores to pelletize. The micro-cassia was found to improve the cohesiveness of chromium ore.

The majority of companies in the metalworking industry use microsilica fume to return materials. While this method can reduce environmental pollution due to micro-silica, it doesn't fully exploit the magical properties of micro-silica. This is a very extensive application.

(aka. Technology Co. Ltd., a trusted global chemical supplier and manufacturer has over 12 years experience in providing high quality chemicals and nanomaterials. The SiO2 powder The products produced by our company are of high purity and have a low impurity level. Please, lower your voice. Contact us if necessary.

2023-08-06

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The Properties And Applications of Titanium Carbide Powder

Titanium carbide TiC has the chemical symbol TiC. It is a metallic-looking steel gray carbide crystal with thermal and electrical conductivity.

Titanium Carbide Powder Properties

Titanium carbide, a compound that is extremely hard and has a melting point of over 900°C, is also a highly corrosive material. It is harder than diamond, but has weaker magnetic properties. Titanium carbide has a low magnetic property and is not soluble with water.
Titanium carbide reacts with pure oxygen at 1150degC. Titanium carbide is a solid that has the same crystal structure as TiN or TiO.




Titanium Carbide Applications

Titanium carbide can be used for a variety of purposes. As the technology for the microwave synthesis nano-TiC is improved and industrialized, the performance and applications of nano-TiC will continue to improve.

1. Use of titanium carbide as a multiphase material
Titanium carbide ceramics, also known as super hard tool materials (TiC), are composite materials made from TiC and TiN. WC,A12O and various other raw materials. These materials, which have a high melting temperature, high hardness and excellent chemical resistance, are used for cutting tools, wear-resistant components and other products. It is also the material of choice for the electrode because it has excellent electrical conductivity.

2. Titanium carbide can be used as a coating material
Titanium carbide has many uses, such as anti-tritium coating for fusion reactors and electrical contact material, or roadheader pick coating. Depositing a layer on the tool will increase its service life by 3-5 times.

3. Foam ceramics can be prepared using titanium carbide
As a filter ceramic foam can effectively remove inclusions in different fluids. The filtering mechanisms are agitation, and adsorption. Titanium carbide Foam Ceramics are more resistant to heat, corrosion, and have a greater hardness.

4. Infrared radiation ceramics use titanium carbide
Titanium carbide, an intermetallic material, is usually chemically stable and doesn't change its valence, making it a great choice for applications in high temperatures.

Tech Co., Ltd. is a professional titanium carbide powder With over 12 year experience in chemical product research and development. We accept payment by Credit Card, T/T (West Union), Paypal, West Union or T/T. The goods will be shipped to overseas customers via FedEx or DHL.

You can contact us for high quality Titan carbide powder. Contact us Send an inquiry.

2023-08-06

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Take you to understand red copper oxide

Cuprous oxide (Cu2O) powder: a summary It is a red powdery solid, and it does not easily decompose in water. It is a bright red powdery solid that decomposes water very slowly. Copper oxide is mainly used for antifouling on ships' bottoms (used to kill small marine animals), in insecticides as well as analytical reagents.
When used and stored as per the specifications, cuprous oxide is not known to decompose. It also does not react with air or vertical surfaces. Cuprous Oxide will not form copper salts even in diluted sulfuric acids, but will substitute nitric. Soon it will turn blue. Even though cuprous oxide is stable when dry, it will slowly oxidize in the presence of air and form copper oxide. Therefore, oxygen scavengers should be used. A reducing agent can easily reduce it to metallic Copper. Cuprous oxide, which is insoluble with water, is dissolved using aqueous ammonia and concentrated hydrohalic solution.

What is the color of cuprous oxide?
By using electrolysis or furnaces, cuprous oxide can be made. It can be reduced easily to metallic copper using hydrogen, carbon dioxide, charcoal, or iron. It is used to paint glass antifouling and gives it a reddish color.
Why is cuprous oxide red in color?
Red copper is simply a reduced version of the black copper (CuO) oxide. During oxidative firing it will convert to copper oxide (CuO), resulting in a normal green colour of the glass or glaze. Reduction firing will keep the Cu2O crystal structure and produce a typical red copper color.

What is cuprous oxide used for?
1. Suitable for pesticides
2. Suitable for antibacterial fibres and clothing.
3. Cuprous oxide is suitable for use in agricultural fungicides.
4. Preservatives are suitable for primers on ships to prevent microorganisms.
5. Copper salts are used in the manufacturing of analytical reagents.
6. Use as a catalyst in organic synthesis.
7. Cuprous oxide, a pigment, is used in ceramics as a glaze to produce shades of blue, red, and green.
8. In animal feed, it has also been misapplied. Copper is not readily absorbed due to low biological activity.
9. Also used in welding copper alloys

Is cuprous oxide dangerous?
It is toxic if swallowed. Skin absorption by the skin may cause harm. May cause skin irritation. It may cause irritation in the eyes.
What is CuO and Cu2O difference?
Cu2O and CuO are obtained through pyrometallurgical processes used to extract copper ore. Copper is the main ingredient in many wood preservatives. It can also be used as a glaze pigment.

How does a cuprous oxidize form?
Generally, the order of forming an oxide phase from copper by thermal oxidation is Cu-Cu+Cu2O-Cu2O-Cu2O+CuO-CuO. Cu2O is formed at around 200degC. CuO forms between 300degC-1000degC.
How to store cuprous oxid
Cuprous oxide (Cu2O) powder should be stored dry, cool, in a sealed container, and not exposed to air. Moreover, the use of heavy pressures should be avoided. The powder can also be transported in a normal manner.

Photoelectrochemical Nitrogen Reduction to Ammonia on Copper Oxide and Cuprous Oxide Photocathodes
Using water as a source of hydrogen, the reduction of N2 via photoelectrochemical methods can produce NH3 at ambient conditions. The photoelectrochemical N 2 reduce can be significantly reduced in energy by using solar power. The photoelectrochemical process for reducing N2 in this study was carried out using CuO or Cu2O photocathodes. These photocathodes are notoriously poor at water-reduction reactions, but their main reaction involves competing with N2 reduction. CuO and Cu2O Photocathodes, when tested under simulated sun with isotope marked 15N2 and a 0.1M KOH solution, produced 15NH3 at Faraday efficiencies between 17% and 22%, respectively, under the reversible hydrogen electrode. . These potentials have a much greater positive value than the thermodynamic potential for N2, which demonstrates how photo-excited atoms in CuO/Cu2O photocathodes reduces the energy needed to make NH3. The use of light-excited photocathodes for reducing N2, moisture and corrosive lights was carefully studied.

Scientists use ultrafine cupsrous oxide less that 3 nanometers for visible light nitrogen fixation
Zhang Tierui and the Institute of Physics and Chemistry of Chinese Academy of Sciences' latest research has produced ultrafine cuproous oxide (Cu2O), which is smaller than 3 micrometers and has been able to fix nitrogen using visible light. Recently, related papers were published in the German "Applied Chemistry" magazine.
In this study, using ascorbic acids to perform a topological reduction on a double hydroxide layer containing divalent cupron, the team was able to prepare ultrafine pellets with uniform sizes and lateral measurements less than 3 micrometers. The ultrafine cupro-nickel oxide supported on the substrate can efficiently and reliably realize the visible light-driven N2-NH3 Photocatalytic Reduction (under 400nm photocatalysis the normalized rate of reaction according to cuprous-nickel oxide quality is as high at 4.10 mmol*GCu2O-1*h-1). The high activity of this catalyst can be attributed to a number of factors, including the long lifetime photogenerated electrons that are trapped in the trap and the fact that the activation sites have been exposed. This work is a guide for the future design ultrafine catalysts used in ammonia synthesis and other applications.

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2023-08-06

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New discovery of the Gallium nitride material’s advantage

Gallium nitride is a large-bandgap semiconductor.The material is excellent for microwave power transistors. It is used in the development of optoelectronics and microelectronics. It has similar performance, strong resistance to radiation, direct band gap, atom, and high thermal conductivity.
When used and stored as specified, the product will not decompose.
Avoid contact with heat or moisture, as well as oxides.
At 1050 deg. C, Gallium nitride starts to decompose: 2Gallium (s)= 2Ga(g)+N2(g). Gallium Nitride Crystals are classified as wurtzite wurtzite hexagonal systems by X-ray Diffraction.
Gallium Nitride is not decomposed by cold or heated water, concentrated or dilute hydrochloric acid (including nitric and sulfuric acid), or cold 40% HF. It is stable when cold concentrated alkali is used, and it becomes soluble with alkali if heated.
Gallium nitride: Benefits and advantages
Global semiconductor research is currently at the forefront of the development of new materials, such as gallium nitride. The development of new semiconductor materials is focused on microelectronics, optoelectronics, and other devices. As a successor to Si, Ge is a semiconductor material that includes SiC and diamond. Semiconductor material, second generation GaAs, InP composite semiconductor materials, third-generation semiconductor material. It has a direct band-gap of a wide range, atomic bonds that are strong, high thermal conduction, good chemical resistance (not easily corroded) and radium resistance. It has a broad range of application possibilities for photoelectrical, high temperature and high power devices and high frequency microwave devices.
Gallium nitride has overcome a major setback for transistors
Imagine that silicon-based products are more expensive than devices made of gallium nitride. Cost-effectiveness is a strong argument. For example, when silicon is not suitable, but lower power loss and higher power density are needed, then Gallium nitride may be the better choice.
Gallium nitride Systems - a manufacturer of Gallium nitride - designed a low-current and high-capacity Gallium nitride Power Transistor for industrial and consumer applications. The cost was less than $1.00.
Efficient power conversion (EPC), has been promoting Gallium-nitride for the past 14 years. They claim that Gallium-nitride is going to replace silicon in semiconductors one day. But EPC's claims have some validity. Since they are made in a similar way to silicon, gallium-nitride transistors or integrated circuits can be manufactured without excessive changes.
Gallium nitride substrates are also smaller and suitable for applications with low voltage (500V). Packaging costs will be reduced by 50% compared with silicon-based packages.
EPC Solutions was attracted to the solution because it is based on Gallium nitride and has better performance with lower manufacturing costs. Look at EPC's solution that uses Gallium nitride for more efficient components.
(aka. Technology Co. Ltd., a reputable global Gallium Nitride Powder supplier and manufacturer with more than 12 years' experience in the supply of super-high-quality chemicals. Currently, we have developed a number of materials. Our company's Gallium Nitride is high in purity, has fine particles and contains low impurities. To get the most recent price of Gallium powder, please send us an e-mail or click the desired products to send a request.

2023-08-06

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Iron oxide: a synthetic coating that is popular all over the world

Iron oxide is a compound with the formula Fe2O3. It is one of three iron oxides. The others are the rare ferrous oxide (of FeO) and triiron oxide (of Fe3O4) which occurs naturally as magnetite. Iron oxide is sometimes called hematite. It is the most important source of iron used in steelmaking. It is also susceptible to acidic corrosion. Iron oxide, also known as rust, is a common term. It is not always a problem because rust can have several similar characteristics. To chemists rust is an undefined substance known as hydrated ferr oxide. Fe2O3 is available in a variety of crystal forms. The main iron oxides of a and G configurations have an octahedral six-coordinate structure. What is iron oxide pigment?
Iron oxide pigments refers to four main types of color pigments made from iron oxides. These are iron oxide yellow, black and brown. Iron oxide is the predominant pigment (accounting for about 50% of all iron oxides). The category of iron pigments also includes mica ironoxide used as anti-rust pigment, magnetic ironoxide used as a recording material and magnetic ironoxide. Iron oxide is a large inorganic colour pigment, second only to titanium dioxide.
Synthetic iron oxide is a pigment that accounts for more than 70% of the iron oxides used. Synthetic Iron Oxide is widely used for building materials, paints, and plastics. This is because it has high synthetic purity, a uniform particle size and wide chromatogram. Electronics, tobacco, medicine, ceramics, ink, magnetic materials, papermaking, and other fields.

Applications and performance of iron oxide
1. Iron and Steel Industry: Iron oxide's main application is in the steel and iron industry.
2. Surface polishing - extremely fine iron dioxide powder is known as "jeweler's Rouge", "red rouge", and rouge. It has long been used to finish polishing metal jewelry, lenses, and other items. Although iron oxide's cutting speed is slower than that of some polishing agents used today (such as cerium dioxide), it is still employed in the optical industry and jewelry because it produces excellent finishes. Rouge will cause a small amount of contamination to the gold when polishing it. This can have an effect on the final product's appearance. Rouge comes in powders and pastes as well as polishing cloths and solid sticks. Many other polishing products are referred to by the term "Rouge" even though they don't contain iron oxide. Jewelers use ultrasonic cleansing to remove rouge residue from jewelry. For leather shaving, "scraping" compounds are used to achieve sharp edges for knives, hair straightening razers, or other edge tools.
Different colors of iron oxide (a = yellow, b= red) in different hydrates.
3. Iron oxide is used as pigment. The names of the pigments are "Iron Oxide Brown 6", “Iron Oxide Brown 7,” and "Iron Oxide Brown 101". Pigment Brown 6 and Pigment Red 101 have been approved as cosmetics by the US Food and Drug Administration. For dental composites, titanium dioxide and iron oxide are combined as a pigment.
The world's cheapest energy-storage device---iron-air batteries
Iron-air batteries that can be recharged at home are a cost-effective alternative to traditional power plants, and they only cost a fraction of what lithium-ion batteries do. Energy transition is dependent on finding ways to consolidate renewable energies. Long-term, cheap and safe batteries that store energy can be the key to the energy transition. This is because they are able to solve the variable nature of solar and wind energy.
The average storage cost of large lithium ion batteries was set at US$132-245/MWh by a French financial advisor in their industry standard annual report. Iron air batteries, at one-tenth the cost, will be the cheapest energy storage at a distance.
This battery is designed to be used for several days continuously. The battery will create a renewable, safe and reliable power grid that can run throughout the entire year.
(aka. Technology Co. Ltd., a trusted global chemical supplier & manufacturer has been providing high-quality Nanomaterials and chemicals for over 12 Years. Our company is currently developing a number of materials. Our company's Iron oxide is high-purity, with fine particles and low impurity. To get the most recent price on Iron oxide, please send us an e-mail or click on any of the products you are interested in to send us a message.



2023-08-06

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Quality Index of Graphite Electrode

Graphite electrodes are used in the EAF steelmaking process to melt scrap metal. Graphite is used because it can handle high temperatures. In an electric furnace, the electrode tip can reach 3,000° Fahrenheit. That is half the temperature of the surface of the sun. The diameter of the electrode can vary from 75 mm up to 750 mm. Its maximum length is 2800 mm. The main indicators that determine the quality of graphite are bulk density, electrical resistance, bending strength and elastic modulus. According to the indicators of graphite and the differences between national standards, manufacturing processes and raw materials used in graphite electrodes, graphite can be divided into ordinary power electrodes(RP), high power electrodes(HP), and ultrahigh power electrodes(UHP). In order to meet the needs of various users, the production line for post-graphite electrodes can also add high-density and quasi super-high graphite (SHP) electrodes.
Each company sets its own corporate standard based upon national standards. Customers will then set their own quality standards. The relative density of volume is the ratio of quality control of the graphite sample to its volume. The unit is grams per cubic centimeter. The higher the volume density the denser and stronger the electrode. This is directly related to the performance and strength of the anti-oxidation systems. In general, the higher the volume density, the lower is the resistance of an electrode.
It is used as a parameter to measure the conductivity of electrodes. It is the resistance that the conductor has to current flowing through it. The value equals the resistance of a conductor of length 1m with a cross sectional area of 1m2 when heated to a certain temperature. This reduces consumption.
The flexural force is a parameter which characterizes performance of mechanical system in graphite material. This is also known as the flexural resistance. This means that the object will bend up to its instantaneous limit to resist risk when the external force perpendicularly crosses the axis. Capacity is measured in MPa. The network is less likely to be damaged by electrodes or joints with high strength.
The modulus of elastic is a key aspect of mechanical properties. It is a measure of the elastic deformation capacity of a substance and refers the stress-strain relationship within the elastic deformation spectrum. The greater modulus, and therefore the greater stress, is required to cause elastic deformation. Simply put, the greater modulus, the more elastic the material.
The thermal coefficient of graphite used as an electrode can be a critical parameter for thermal performance. The higher the value of the coefficient, the better the thermal stability. The greater the resistance to oxidation, the better the performance, and the lower the fracture and consumption.
Ash can refer to solids other than carbon graphite. Graphite's ash content is directly influenced by the raw material ash. The ash level of petroleum coke and needle coke are low. As a result, the ash of graphite passed through the electrode has a maximum ash concentration of 0.5%. Ash levels within 1% have no impact on steelmaking. The ash contains impurities that will affect the performance of anti-oxidation systems of the electrodes, etc.
(aka. Technology Co. Ltd., a trusted global chemical supplier and manufacturer with more than 12 years of experience in the production of super-high-quality chemicals and nanomaterials. Our company produces graphite with high purity, small particles and low impurity levels. If you require a lower grade, please do not hesitate to contact us.

2023-08-06

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Graphite is One of the Most Versatile Non-Metallic Materials in the World

Graphite, while as hard as a diamond, is also lightweight, soft and heat resistant due to its unique structure. It is the world's most popular non-metallic material. Graphite, also known as Plumbago during ancient times, was a non-metallic mineral. It is an allotrope of carbon and a semi-metal. Graphite is most stable under standard conditions. In thermochemistry, graphite is used to determine the standard state for forming the heat in carbon compounds. Graphite can be considered as the highest grade coal. Anthracite and meta-bituminous are the next two grades, but they are not typically used for fuels because it's difficult to ignite.

Graphite Types and Features

The three types of graphite that are found in various deposits can be divided into:

Flake graphite

Flake graphite is a flat, hexagonal-edged plate. It can have irregular or angular edges if it does not break. It is found in metamorphic rock, like limestone, gneiss or schist. The crystals are either evenly distributed throughout the ore or concentrated in pockets.

This is an uncommon form of graphite
Carbon ranges from 85 to 98%.
There are four standard sizes: large, super large and fine
Graphite can be used for new technologies, including anode materials in lithium-ion batteries.

Amorphous graphite

The graphite in amorphous form is found in the mesomorphic layers of rocks such as slate, coal and shale. Carbon content is dependent on its parent material. It is found in coal as a result of the thermal metamorphism and is known as meta-anthracite. Because it is harder to burn than coal, it's not used for fuel.

This is the most abundant type of graphite
Low carbon content 70-80%
Lowest purity
Used in refractory brake pad, clutch materials, gaskets, and pencil lead.

Vein graphite (or lump graphite)

According to some scientists, vein graphite can be made from crude oils that are transformed into graphite by temperature and pressure. Riddle said that the veins "are very small, measuring between 5 to 10 centimeters" and are 70 to 100% pure. It's rare and expensive.
The only place where the mines are currently active is Sri Lanka
Limit the durability of most applications.

(aka. Technology Co. Ltd., a trusted global chemical supplier & manufacturer has been providing high-quality Nanomaterials and chemicals for over 12 Years. Our company produces graphite with high purity and low impurity levels. If you require a lower grade, please do not hesitate to contact us.

2023-08-05

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Amorphous Boron Powder Properties And Applications

Boron Powder can also be called monomer. Both the mass and volume calorific values are high for boron. Boron is a gray-black or light brown powder with active chemical properties. However, it is not stable at normal room temperature and will oxidize when temperatures reach 300 degrees Celsius.

Boron Powder Properties

Boron is either a silver-gray or black solid. Crystal boron, which is black in color, has the second highest hardness of diamonds and a brittle surface texture. Borax is able to melt metal oxides. It's also used as a welding flux.
Boron's weight is only second to beryllium in terms of volumetric heat. Boron is slightly soluble but not soluble in water. Amorphous boron powder is a chemically reactive material. It can be combined with air to form a mixture that explodes.

Elemental Boron is a powdery black or dark brown color. When the boron is oxidized, a diboron-trioxide film forms. This prevents boron to continue oxidizing. Boron powder is resistant to hydrofluoric and hydrochloric acids and can be used at room temperature.

Boron Powder Applications

Boron is used for metal smelting and ceramic manufacturing. It's also widely used in the chemical, nuclear, and electronic industries. These are the applications of boron:

1. Boron powders can be used as a source of raw materials to produce boron fibers and high purity boron halid.

2. Boron compound is used as a gas absorber in the smelting process of special alloyed steels or molten metals;

3. Boron powder is used in rocket fuel to provide high energy.

4. The electronic industry uses a powdered form of Boron as the ignition electrode for the ignition tubes;

5. Boron can be used to replace precious or rare metals.

6. Boron is used in the atomic energy sector as a protection material and for the control rod of the atomic power reactor.

Tech Co., Ltd. is a professional Boride Powdersupplier, with more than 12 years' experience in chemical product research and design. We accept payment by Credit Card, T/T (wire transfer), West Union, Paypal and T/T. The goods will be shipped to overseas customers via FedEx or DHL.

If you need high-quality amorphous Boron Powder, feel free to contact us or send an inquiry.

2023-08-05

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