Application Fields of 316L Stainless Steel Powder

Stainless Steel Powder 316L Stainless Steel Powder Applications

316L stainless steel Powder This metal powder is used widely in many fields because of its outstanding corrosion resistance. Here is a detailed guide to using 316L stainless-steel powder in various fields.

1. Aerospace field

316L stainless powder is widely used in aerospace for the manufacture of high-strength components that are corrosion resistant. The 316L stainless powder's excellent resistance to oxidation and high temperatures allows it to perform well in harsh environments, such as high pressure and temperature. This ensures the safety and reliability of aircraft. In the production of jet engines for instance, 316L steel powder is employed to produce high-temperature parts such as combustion chambers, turbine blades, etc. that can withstand up to 600°C and high pressure airflow.

Additionally, 316L powder is used for manufacturing structural components of high strength in aerospace vehicles. These include beams and frames. Due to the excellent welding and processing capabilities, it is easily transformed into various structural components that ensure dimensional accuracy.

2. Petrochemical Industry

In the petrochemical industries, 316L stainless powder is widely used for manufacturing high-strength corrosion-resistant pipelines and equipment. The 316L stainless steel powder has excellent corrosion resistance and can resist various chemical substances. This ensures the equipment's long-term stability. For example, when manufacturing petrochemical machinery, 316L stainless powder is used to make high-temperature high-pressure pipelines and containers. This can withstand corrosion from various chemicals, while ensuring its sealing and strength.

Additionally, 316L stainless powder is used for manufacturing filters, separators, catalyst carriers, and other components within the petrochemical industry. Its high-temperature and corrosion-resistant properties can help ensure that equipment will operate reliably for a long time and increase production efficiency.

3. Medical field

316L stainless-steel powder is used widely in the medical field to produce high-standard medical implants and devices. Its non-toxic, harmless, and biocompatible effects on human bodies, along with its high biocompatibility can guarantee the stability and safety of a product for a long time. This is why it's widely used to make medical devices and human implants. In manufacturing artificial joints and prostheses as well as other implants, 316L Stainless Steel Powder is used for support structures and connectors. It ensures strength and stability as well as corrosion and wear resistance.

316L powder is used extensively in the medical industry to manufacture surgical instruments and medical devices of high standards. The good processing and weld performance of 316L stainless steel powder allows the production of various complex-shaped devices, which improves the reliability and safety medical equipment.

4. Industrial sector

In the industry, 316L stainless powder is widely used for manufacturing high-strength corrosion-resistant equipment and components. You can use it to make high-quality mechanical elements such as bolts, springs, chemical equipment and ship components. The excellent corrosion resistance and anti-oxidant performance of this material can help to ensure that the equipment will operate smoothly for a long time and increase production efficiency.

The power and electronic industries are also major users of 316L powder. For example, when manufacturing electronic components and battery shells, 316L steel powder can be used. It improves the quality and safety.

Summary: 316L stainless-steel powder has many uses in various fields.

About KMPASS

KMPASS is a global supplier and manufacturer of high-quality nanomaterials, chemicals, and other materials. We have over 12 year experience. The company export to many countries, such as USA, Canada, Europe, UAE, South Africa, Tanzania,Kenya,Egypt,Nigeria,Cameroon,Uganda,Turkey,Mexico,Azerbaijan,Belgium,Cyprus,Czech Republic, Brazil, Chile, Argentina, Dubai, Japan, Korea, Vietnam, Thailand, Malaysia, Indonesia, Australia,Germany, France, Italy, Portugal etc. KMPASS, a leader of nanotechnology manufacturing, dominates the market. Our professional team offers perfect solutions to improve the efficiency of different industries, create value and cope with various challenges. Send an email to Sales2@nanotrun.com for 316L powder.

What is Zinc Sulfide

Zinc Sulfide:

Its chemical formula is ZnS. Its molecular weight, 134.72. It is created by interacting through ionic interactions with zinc ions, (Zn2+), and sulfur ions, (S2-). In the crystal, the sulfur ions form a tetrahedron with a zinc ion in the center. The sulfur ion occupies the center of the tetrahedron. This structure can also be described as a face centered cubic crystal system where zinc and sulfur are at the vertex of the lattice and face centered.

Zinc Sulfide (also known as Zinc Sulfide) is an insoluble, white solid. It is not soluble in water. However, it is soluble with bases and acids. Zinc sulfide's density is 3.98 g/cc, with a melting point of 1350 degrees C. and a boiling point of 1650 degrees C. It is also transparent and has good optical properties. The light transmission is between 200 and 400nm. Zinc sulfide has relatively stable properties, but under certain circumstances it can also undergo reactions. Zinc sulfide is oxidized, for instance, when it comes into contact with an oxidizing substance. In an environment that is alkaline, zinc sulfide will react with hydroxide molecules to produce zinc hydroxide.

Application Of Zinc Sulfide

Zinc sulfide, also known as zinc sulfur, is an important compound. The unique crystal structure and chemical and physical characteristics of zinc sulfide have made it a widely used compound in many fields. We will discuss the various applications of zinc sulfide.

1. Manufacturers of phosphor

Zinc Sulfide has a variety of uses, including in the production of fluorescent screens. Zinc sulfide, used in the manufacture of fluorescent screens, can be made into phosphors, which can then emit light to display an image when they are excited by external lights. When producing fluorescent lights, zinc-sulfide also makes phosphors which emit visible light upon being excited by ultraviolet radiation.

2. Manufacturing of photoelectric conversion materials

Zinc Sulfide, a material used for photoelectric conversion, can also be used in the manufacture of solar cells. In solar cells zinc sulfide converts light energy into electrical power. The photoelectric efficiency of zinc sulfide, combined with its low cost, makes it a material that has wide applications.

3. Drug Manufacturing

Zinc Sulfide, because of its biological activity, has many applications in pharmaceutical production. Zinc sulfide is used in the manufacture of anti-malarials, including zincsulfate as well as zinc acetate. The zinc sulfide used can be used for the production of preservatives and fungicides.

4.

Zinc sulfur acts as a catalyst for the creation of other compounds like zinc acetates, acetones, and methylisobutylketone. Zinc sulfur is a highly active and selective catalyst that can be used in the manufacturing process.

5. Optical device manufacturing

Due to its high transparency, zinc sulfur is used widely in optical devices. Zinc sulfide is used, for instance, in optical fiber communication to produce optical fiber preforms. Additionally, zinc sulfide may be used to make optical devices like optical Windows and lenses.

Method of Production of Zinc Sulfide

1. Method of chemical precipitation

The chemical precipitation method is the most common way to prepare zinc sulfide. The zinc sulfide was obtained by mixing zinc salt with sulfur salts in a liquid solution.

Preparation Solution: Dissolve a suitable amount of zinc salt and sulfur salt into water to create a solution.

Precipitation reaction : the above solution is heated in stirring conditions and an appropriate amount precipitating agent is then added to precipitate both zinc ions (and sulfur ions) to generate zinc-sulfide precipitation.

Filtration : The reaction is filtered in order to obtain a filtrate that contains zinc-sulfide precipitation.

Cleaning: The filtered precipitate of zinc sulfide is cleaned with alcohol in order to remove impurities.

Drying: After washing the zinc sulfide it is precipitated then dried to get zinc sulfide.

Chemical precipitation is easy to do, inexpensive, and produces a product of high purity. The disadvantages of this method are that it requires many detergents and precipitating agents. Also, the waste liquid generated must be treated and disposed before being discharged, which can cause environmental pollution.

2. Synthesis of solid phases at high temperatures

Traditional methods for the preparation of zinc sulfide include high-temperature solid-phase synthesis. A solid reaction between zinc oxides and sulfur-containing elements was used to produce zinc sulfide.

Ingredients: To make raw materials, the appropriate amount of carbon powder, zinc oxide powder, and sulfur dioxide powder is mixed.

Pretreatment - The raw materials undergo a pretreatment at high temperature to ensure that all components react and generate zinc vapor.

Synthesis: Zinc and sulfur vapors are produced at high temperatures.

Collection: The zinc sulfide synthetic powder is collected.

The high-temperature, solid-phase synthesis is characterized by high purity, excellent crystallinity, as well as a relatively straightforward process. The method does require high-temperatures and a lot of carbon and sulfur powder.

3. Solventothermal Method

The solvothermal process is a method that has been developed to prepare zinc sulfide. The method is to dissolve zinc salts and sulfur salts in organic solvents under high pressure and temperature. This produces zinc sulfide by hydrothermal reactions.

Solution preparation: Dissolve the required amount of zinc salt and sulfur in the organic solvent.

High temperature and pressure reaction: In a high temperature and pressure reactor, the above solution is placed and hydrothermal reaction takes place under conditions of high temperature and low-pressure to produce zinc-sulfide-based powder.

Collection: The generated powder of zinc sulfide will be collected and treated as required.

The solvothermal technique has the advantage of a high purity product, a good crystallinity and a relatively straightforward process. The solvothermal method allows the control of product properties by using different organic reagents and conditions. The method is not without its limitations. It requires high-temperature, pressure equipment. And the recovery and disposal process of organic solvents are expensive and require certain technology.

It is important to consider the advantages and limitations of different methods of production of zinc sulfide, and to select the appropriate methods according to actual conditions and needs. During the production, it is important to take into account environmental protection and safety. Adopting appropriate environmental protection technologies and measures will help reduce the harm caused to the environment and humans.

Prospect Markets of Zinc Sulfide ()

1. phosphor market prospects

Zinc sulfur is a widely used material in the manufacture of phosphor. Phosphor can absorb light while emitting different colors. It is used widely in the display, lighting, photovoltaic, and other fields. Due to the constant development of science, phosphors' application fields are expanding. Zinc sulfide has become an important material for phosphors, and the market is growing.

2. Photoelectric conversion materials: market outlook

Zinc sulfur is also widely used for the production of photoelectric materials. Solar cells, the most popular application of photoelectric materials, can convert light into electricity. The demand for solar panels is increasing as renewable energy becomes more important. The cost of photoelectric converter materials has also been steadily decreasing, as technology continues to improve.

3. Market prospects for drug manufacturing

Zinc Sulfide has also been used in pharmaceutical production. The pharmaceutical industry is a massive market. As people become more health-conscious, the demand for drugs increases. Zinc Sulfide can be used for antimalarial drug production and has a biological activity.

4. Prospects for the manufacturing of catalysts

Zinc sulfur is used for some catalyst production. Catalysts are substances that accelerate chemical reaction and have a variety of applications, including in the fields of environmental protection, pharmaceuticals, and chemical industries. As technology continues to develop, so do the demands for catalytic performance and selectivity. This provides more opportunities for using zinc sulfide as a catalyst.

5. The optical device market is expected to grow at a rapid rate.

Zinc sulfur is also widely employed in the manufacture of optical devices. The optical device has multiple applications, including communication, imaging and optical storage. It can modulate and transmit the light. As technology continues to develop, performance requirements for optical products are increasing. This provides more opportunities for zinc sulfide to be used in optical device production.

Zinc Sulfide powder Price:

Many factors influence the price of a product, such as the economic activity in the industry, the demand and supply on the market.

You can contact us for a quotation if you want to know the current price of zinc sulfide.

Zinc Sulfide Powder Supplier :

Technology Co. Ltd., () is an experienced global chemical material manufacturer and supplier with over 12 years' experience. They provide super-high-quality chemicals, such as silicon powders, graphite particles, zinc sulfide or boron powders.

Contact us if you need high-quality zinc oxide powder.

Application Fields of Nickel Based Alloys

Nickel Based Alloys: Applications

Nickel-based alloy Based on nickel, it is made up of various alloying materials. It is used for its high-temperature properties, corrosion resistance and oxidation resistant as well as mechanical properties in the aviation, aerospace and petrochemical industries. This article will give a detailed description of the Applications of nickel-based alloys in different fields such as aerospace, petrochemicals and power energy. It also provides references for Research and Application.

Applications of nickel-based alloys to the aerospace industry

The aerospace sector is one of many important applications of Nickel-based alloys These are the main components used in aerospace to produce high-performance products like aircraft, rockets and satellites.

Aircraft engine components

Aircraft engines include:

* The main equipment used in the aviation industry.

* Material with outstanding high-temperature resistance is required.

* Corrosion resistant.

Mechanical properties

Nickel-based metals exhibit excellent strength at high temperatures, as well as creep and fatigue resistance. The alloys are used for many aircraft engine parts, including turbine blades and discs.

Rocket engine components

Rocket engines are key equipment in the launch of satellites and space probes. They require materials with extreme high-temperature strengths and corrosion resistance. Nickel-based alloys In the manufacture of rocket engines are commonly used key components like combustion chambers. nozzles and turbine disks.

Satellite structural components

Satellites' structural components need materials that have excellent corrosion resistance and high temperature resistance. Many structural components, including solar panels and structural frame frames, are manufactured using nickel-based materials.

Use of nickel-based alloys for the petrochemical Industry

Nickel-based materials are also widely used in petrochemicals. Nickel-based alloys are mainly used in the manufacture of key equipment, such as high temperature and high pressure reactors and pipes, for the petrochemical industries.

High-temperature reactor

High-temperature Reactors are:

* The core equipment of the petrochemical industries.

* Material with outstanding high-temperature resistance is required.

* Corrosion resistant.

Mechanical properties

Alloys based on nickel have excellent high-temperature properties, corrosion resistance and mechanical characteristics. High-temperature reactors like hydrogenation reactors or reforming reactors are made with these alloys.

High-pressure pipeline

In the petrochemical industries, high-pressure pipes are essential equipment. Materials with excellent corrosion resistance and mechanical properties are required. Nickel-based materials are widely used for high-pressure pipe manufacturing because of their excellent high-pressure resistance, corrosion resistance, as well as mechanical properties.

Applications of nickel-based materials in the field power energy

The electric energy sector is another area where nickel-based materials are used. These alloys are used mainly in the manufacture of high-temperature exchangers, and gas turbines.

High-temperature heat exchanger

The high-temperature heat-exchangers in the power and energy industry are essential equipment. Materials with excellent resistance to corrosion, as well as mechanical properties, are required. Nickel-based materials have excellent mechanical, corrosion-resistant, and high-temperature properties. The alloys are widely used for high-temperature exchangers like air preheaters or flue gas exchangers found in coal-fired electricity stations.

Gas turbine blades

Gas turbines can be:

* Equipment for energy conversion and electricity generation.

* Material with outstanding high-temperature resistance is required.

* Corrosion resistant.

* Mechanical properties

In the manufacture of gas turbines such as blades or key components, nickel-based materials are used widely.

Applications of nickel-based alloys to biomedicine

Biomedical applications are another important area for nickel-based metals. These alloys are used to manufacture medical devices like artificial joints and vascular scaffolds.

Artificial joint

Artificial joints can be:

* Medical devices which replace diseased joints.

* Requires materials with excellent corrosion resistance.

* Biocompatibility.

* Mechanical properties

Alloys based on nickel have excellent corrosion resistance and biocompatibility. They are also used to manufacture artificial joints.

Vascular stent

Materials with high corrosion resistance, biocompatibility and flexibility are required for vascular stents. Nickel-based materials are highly corrosion resistant, biocompatible, and flexible and are widely used for vascular devices.

As a summary, nickel-based materials have been extensively used in aerospace and petrochemicals as well as power energy and biomedicine. In the future, with the continued development of technology and the use of nickel-based materials, they will become more widely used, contributing to industrial and technological development.

About KMPASS

KMPASS is a global chemical supplier & manufacturer that has over 12 year experience in providing high-quality Nanomaterials and chemicals. The company export to many countries, such as USA, Canada, Europe, UAE, South Africa, Tanzania,Kenya,Egypt,Nigeria,Cameroon,Uganda,Turkey,Mexico,Azerbaijan,Belgium,Cyprus,Czech Republic, Brazil, Chile, Argentina, Dubai, Japan, Korea, Vietnam, Thailand, Malaysia, Indonesia, Australia,Germany, France, Italy, Portugal etc. KMPASS, a leading manufacturer of nanotechnology products, dominates the market. Our expert team offers solutions that can help industries improve their efficiency, create value and overcome various challenges. You can contact us at sales2@nanotrun.com for Inonel 718 Powder.

CLC blocks and foamed concrete lead the reform of the construction industry

CLC Blocks and foamed Concrete, two new energy-saving materials, are leading the reform in the construction industry.

As environmental awareness continues to improve, the construction industry is now focusing on more energy-efficient and environmentally friendly building materials.

The construction industry has been gradually adopting CLC block as an environmentally friendly, energy efficient, and durable wall material.

CLC block It is an energy-saving material for walls made of fly ash, cement, slags and river sand.

The material is lightweight, strong, has excellent heat insulation properties, good sound insulation qualities, easy and efficient construction and a long life span.

Compare with the traditional clay brick CLC block It has many benefits.

CLC blocks reduce pollution and production costs by using a variety of raw materials. These include cement, slag, and other industrial wastes as well as natural materials like river sand.

The CLC block is also light and strong, which allows it to reduce the weight and improve the performance of the structure.

CLC blocks have excellent thermal insulation as well as sound insulation and thermal resistance, which can help to improve the performance of the building and its comfort.

Construction of CLC block can be convenient and quick, which will greatly reduce construction time.

A new wall material, foam concrete, has also attracted a lot of attention.

The building material is lightweight, strong, and thermally and acoustically insulating. It's made up of raw materials, such as foaming agent, cement and foam agent.

In comparison with traditional concrete, the foam concrete not only has a better thermal insulation and sound insulation, but can also reduce self-weight.

Foamed concrete is made from cement and foaming agent. The foam structure of the foamed material is formed through mixing and foaming.

This foam structure is able to make concrete lighter and soundproof. It can also insulate heat.

The foam concrete can also meet the needs of building structures in terms load bearing, durability and flexibility.

New wall materials have a wide range of applications in the construction industry. CLC block The foam concrete range is quite broad.

You can use them for the exterior and interior walls as well as thermal and sound insulation.

These materials also have characteristics that are compatible with the current trend in the construction industry, such as a simple production process, low costs, and good environmental performance.

The construction industry is gradually becoming more interested in and favoring the new wall materials CLC Block and foam concrete due to their outstanding performance and extensive application potential.

It is expected that, in the future, due to the development of science and technologies, these materials will become more important and play a greater role in the building industry. They are also believed to promote a greener construction industry.

Main applications of molybdenum disulfide

Overview of Molybdenum Disulfide

Molybdenum disulfide (or molybdenum) is an inorganic compound composed of molybdenum and sulfur, insoluble in water, dilute acid and concentrated sulfuric acid, generally insoluble in other acids, alkalis and organic solvents, soluble in aqua regia and boiled concentrated sulfuric acid. Molybdenum disulfide is the main component of molybdenite. It is a black solid powder with metallic luster. The chemical formula of molybdenum disulfide is MoS2, the melting point is 2375°C, the density is 4.80g/cm3 (14°C), and the Mohs hardness is 1.0-1.5. It begins to decompose into metallic molybdenum and sulfur at 1370°C and 1600°C.

Application of Molybdenum Disulfide

Molybdenum disulfide is used as a dry lubricant in greases, dispersions, friction materials and bond coatings. Molybdenum-sulfur complexes can be used in suspension, but are more commonly dissolved in lubricating oils at concentrations of a few percent. MoS2 is used as an additive for greases, friction materials, plastics, rubber, nylon, PTFE, coatings, etc.

1) Widely used in automobile and machinery industry, it is a good solid lubricating material.

2) Lubricants for drill bits, cutting tools and some non-oily and hard alloy steels; lubricant additives and film removers for non-ferrous metals.

3) Preparation of greases and additives for solid lubricating films, nylon filters and catalysts.

4) Synthetic molybdenum disulfide is used as desulfurization catalyst in refineries.

Molybdenum disulfide price

The price of molybdenum disulfide varies randomly with factors such as production costs, transportation costs, international conditions, exchange rates, and supply and demand in the molybdenum disulfide market. Tanki New Materials Co.,Ltd aims to help various industries and chemical wholesalers find high-quality, low-cost nanomaterials and chemicals by providing a full range of customized services. If you are looking for molybdenum disulfide material, please feel free to contact for the latest price of molybdenum disulfide.

Molybdenum Disulfide Supplier

As a global molybdenum disulfide supplier, Tanki New Materials Co., Ltd. has extensive experience in the performance, application and cost-effective manufacturing of advanced engineering materials. The company has successfully developed a series of powder materials (zinc sulfide, tungsten sulfide, bismuth sulfide, etc.), high-purity targets, functional ceramics and structural devices, and provides OEM services.

Overview and wide application of molybdenum disulfide

Prices in the national electricity market averaged $87 per megawatt-hour in the first three months of the year, above the level promised by the federal government. Wholesale electricity prices for industry and large businesses have already exceeded the level promised by the federal government, adding another cost pressure to the economy. Prices in the national electricity market averaged $87 per megawatt-hour in the first three months of this year, up more than two-thirds from the December 2021 quarter, the Australian Energy Market Operator (AEMO) said recently. That's up 141% from the March 2021 quarter.

Because of the ever-changing international situation, the supply and prices of international bulk Molybdenum Disulfide,Overview of Molybdenum Disulfide,Application of Molybdenum Disulfide,Molybdenum disulfide price,Molybdenum Disulfide Supplier are still very uncertain.

Overview of Molybdenum Disulfide

Molybdenum disulfide (or molybdenum) is an inorganic compound composed of molybdenum and sulfur.

Molybdenum disulfide is the main component of molybdenite. It is a black solid powder with metallic luster. The chemical formula of molybdenum disulfide is MoS2, the melting point is 2375°C, the density is 4.80g/cm3 (14°C), and the Mohs hardness is 1.0-1.5. It begins to decompose at 1370°C and at 1600°C into metallic molybdenum and sulfur.

Molybdenum disulfide is insoluble in water, dilute acid and concentrated sulfuric acid, generally insoluble in other acids, alkalis and organic solvents, soluble in aqua regia and boiled concentrated sulfuric acid.

Application of Molybdenum Disulfide

Molybdenum disulfide is used as a dry lubricant in greases, dispersions, friction materials and bond coatings. Molybdenum-sulfur complexes can be used in suspension, but are more commonly dissolved in lubricating oils at concentrations of a few percent. MoS2 is used as an additive for greases, friction materials, plastics, rubber, nylon, PTFE, coatings, etc.

1) Widely used in automobile and machinery industry, it is a good solid lubricating material.

2) Lubricants for drill bits, cutting tools and some non-oily and hard alloy steels; lubricant additives and film removers for non-ferrous metals.

3) Preparation of greases and additives for solid lubricating films, nylon filters and catalysts.

4) Synthetic molybdenum disulfide is used as a catalyst for desulfurization in refineries.

Molybdenum disulfide mixed with some volatile solvents can be sprayed on metal surfaces or added engineering plastics to make lubricating components. Molybdenum disulfide can be directly used in electronics, spraying, electroplating, hardware, screws and other industries.

Molybdenum disulfide is an important solid lubricant, especially suitable for high temperature and high pressure. It is also diamagnetic and can be used as linear photoconductors and semiconductors that display P-type or N-type conductivity, as well as rectification and energy conversion. Molybdenum disulfide can also be used as a catalyst for complex hydrocarbon dehydrogenation.

Molybdenum disulfide is also known as "the king of advanced solid lubricants". It is a solid powder made of natural molybdenum concentrate powder through chemical purification and changing the molecular structure. Molybdenum disulfide is black in color, slightly silver-gray, with metallic luster, greasy touch, and insoluble in water. It has the advantages of good dispersibility and non-adhesion. It can be added to various greases to form a non-adherent colloidal state, which can increase the lubricity and extreme pressure of the grease.

Molybdenum disulfide is suitable for mechanical conditions of high temperature, high pressure, high speed and high load to prolong the life of equipment.

Molybdenum disulfide price

The price of molybdenum disulfide varies randomly with factors such as production costs, transportation costs, international conditions, exchange rates, and supply and demand in the molybdenum disulfide market. Tanki New Materials Co.,Ltd aims to help various industries and chemical wholesalers find high-quality, low-cost nanomaterials and chemicals by providing a full range of customized services. If you are looking for molybdenum disulfide material, please feel free to contact for the latest price of molybdenum disulfide.

Molybdenum Disulfide Supplier

As a global molybdenum disulfide supplier, Tanki New Materials Co., Ltd. has extensive experience in the performance, application and cost-effective manufacturing of advanced engineering materials. The company has successfully developed a series of powder materials (zinc sulfide, tungsten sulfide, bismuth sulfide, etc.), high-purity targets, functional ceramics and structural devices, and provides OEM services.

As imports of natural gas from Russia gradually decrease, the price of natural gas in Germany rises. According to statistics from a German price information portal, according to the current natural gas price, the average annual natural gas cost of the average German household has soared 184%, from 1258 euros last year to 3568 euros, and is likely to continue to soar.

The German government plans to change energy security laws to shift rising costs to all consumers, including natural gas users who have signed fixed-price contracts, Reuters reported. The website estimates that after Germany begins imposing a surtax on households that use natural gas for heating in October, the average annual increase in gas spending per household will be between 357 euros and 1190 euros.

The Saudi Arabian Olympic Committee recently announced that it had formally submitted a bid to the Olympic Council of Asia to host the 2029 Asian Winter Games. Saudi Arabia plans to host the Asian Winter Games in the small town of "TROJENA", the Saudi Olympic Committee said in a statement. If Saudi Arabia succeeds in its bid, it will become the first West Asian and Arab country to host the Asian Winter Games.

The town of "TROJENA" is located within the scope of NEOM New Town in northwestern Saudi Arabia, about 50 kilometers away from the Gulf of Aqaba in the Red Sea.

Luoyang Tongrun Nano Technology is a trusted chemical manufacturer and supplier providing high-quality chemicals and Nanomaterials. If you are looking for the Molybdenum Disulfide,Overview of Molybdenum Disulfide,Application of Molybdenum Disulfide,Molybdenum disulfide price,Molybdenum Disulfide Supplier, please feel free to contact us and send an inquiry.

Wide application of lithium 12-hydroxystearate

Overview of Lithium 12-Hydroxystearate

Lithium 12-hydroxystearate is a white powdery industrial product, which can be prepared by the direct reaction of 12-hydroxystearic acid and equimolar lithium hydroxide monohydrate. Can be used to formulate various greases.

Lithium greases are made from natural fatty acid (stearic acid or 12-hydroxystearic acid) lithium soaps, thickened medium viscosity mineral oils or synthetic oils, while synthetic lithium greases are made from synthetic fatty acid lithium soaps , Thickened medium-viscosity mineral oil.

Lithium 12-hydroxystearate (C18H35LiO3) is a compound belonging to the lithium soap group. In chemistry, "soap" refers to salts of fatty acids. Lithium 12-hydroxystearate is a white solid. Lithium soap is an important ingredient in many greases. Lithium 12-hydroxystearate is a fatty acid salt commonly referred to as "lithium soap". It is the most common soap used to stabilize and thicken oils. Lithium is generally preferable to soaps containing other counterweight ions such as sodium, calcium, and barium.

Lithium 12-hydroxystearate application

Lithium 12-hydroxystearate grease is widely used as lubricating oil, stabilizer, decolorizer and thickener. Lithium-based greases: especially those thickened with lithium 12-hydroxystearate soap. After adding antioxidant, rust inhibitor and extreme pressure agent, it becomes a multi-purpose grease. Alternative long-life general purpose greases calcium and sodium based greases are used for bearing lubrication of aircraft, automobiles, tanks, machine tools and various mechanical equipment.

Lithium 12-hydroxystearate is a fatty acid salt commonly known as "lithium soap" and is most commonly used to stabilize and thicken soap oils. Lithium is generally preferred over soaps containing other counter ions such as sodium, calcium and barium.

Lithium 12-hydroxystearate price

The price of lithium 12-hydroxystearate will change randomly with the production cost, transportation cost, international situation and market supply and demand of lithium 12-hydroxystearate. Tanki New Materials Co.,Ltd aims to help various industries and chemical wholesalers find high-quality, low-cost nanomaterials and chemicals by providing a full range of customized services. If you are looking for Lithium 12-Hydroxystearate Grease, please feel free to send an inquiry for the latest price Lithium 12-Hydroxystearate Lithium Grease.

Lithium 12-Hydroxystearate Suppliers

As a global supplier of lithium 12-hydroxystearate, Tanki New Materials Ltd. has extensive experience in the performance, application and cost-effective manufacturing of advanced engineered materials. The company has successfully developed a series of powder materials (molybdenum disulfide MoS2, tungsten disulfide WS2, boron nitride BN, boron nitride), high-purity target materials, functional ceramics and structural devices, and provides OEM services.

Physical and Chemical Data of Lithium 12-Hydroxystearate

Properties of Lithium 12-Hydroxystearate

Is CuO a copper oxide?

Copper oxide overview

Copper oxide is an inorganic substance. The chemical formula of copper oxide is CuO. It is a black oxide of copper. Slightly bisexual, slightly hygroscopic. Insoluble in water and ethanol, easily soluble in acid, thermally stable, and decomposes into oxygen at high temperature.

What is copper oxide?

Copper Oxide or Copper(II) Oxide

Properties of copper oxide CuO powder

Copper oxide is insoluble in water and ethanol, but soluble in acid, ammonium chloride and potassium cyanide solutions. It is slowly soluble in ammonia solution and can react with strong bases. Copper oxide is mainly used in the manufacture of rayon, ceramics, glazes and enamels, batteries, petroleum desulfurization, pesticides, hydrogen production, catalysts, green glass, etc.

Is CuO a copper oxide?

Yes. There are two different forms of copper oxide: copper oxide (CuO) and cuprous oxide (Cu2O).

Application of copper oxide CuO powder

Copper oxide is an important p-type semiconductor material with a narrow band gap (1.2-1.5 eV) due to its unique properties such as good thermal and photochemical stability, high temperature superconductivity and high electrochemical activity, toxicity, and low cost . In terms of preparation, copper oxide has been widely used in catalysis, sensing materials, superconducting materials, thermoelectric materials, glass, ceramics, lithium-ion batteries and even medicine.

Copper oxide is used as a catalyst. It is a metal oxide that can be used as a hydrogen peroxide catalyst, but manganese dioxide is more active than copper oxide.

In a chemical reaction, the chemical reaction rate of the reactants can be changed (can be increased or decreased) without changing the chemical balance, and the substances whose quality and chemical properties do not change before and after the chemical reaction are called catalysts (solid catalysts are also called catalysts). According to statistics, more than 90% of industrial processes such as chemical, petrochemical, biochemical, and environmental protection use catalysts.

1. It can be used as organic synthesis catalyst, analytical reagent (for nitrogen determination), oxidant, catalyst and petroleum desulfurization. It can also be used to determine carbon in organic compounds.

2. It is used as a colorant in the glass, enamel and ceramic industries, as an anti-Zou agent in coatings, and as a polishing agent in optical glass. For the manufacture of dyes, organic catalyst supports and copper compounds. Used in the rayon manufacturing industry as a desulfurizer for oils and fats. It is used as a raw material for the manufacture of other copper salts, and as a raw material for the manufacture of artificial gemstones.

Copper oxide CuO powder price

The price of copper oxide CuO powder will change randomly due to factors such as production cost, transportation cost, international situation, market supply and demand of copper oxide CuO powder. Tanki New Materials Co., Ltd. aims to help various industries and chemical wholesalers find quality products. Provide high-quality, low-cost nanomaterials and chemicals by offering a full range of customized services. If you are looking for copper oxide CuO powder, please feel free to send an inquiry to get the latest price of copper oxide CuO powder.

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What is a polycarboxylate superplasticizer

In 2023, the China Greater Bay Area Concrete Industry High-Quality Development Seminar and the Expo on Concrete Equipment and Technology will take place at the Guangzhou Canton Fair Complex. Guangzhou Canton Fair Complex. The conference's theme will be "Gathering Talents and Gathering Power, Talking about Smart Concrete," co-sponsored by the Guangzhou Concrete Industry Association and Guangdong Hongwei International Exhibition, responsible persons from the Guangzhou Municipal Bureau of Housing and Urban-rural Development, Municipal Bulk Cement and Building Energy Conservation Management Center as well as Concrete Industry Experts as well as representatives from downstream and upstream companies participated at the show.

A concrete core sample 200 millimeters in diameter and an overall long 25.3 meters was successfully removed from the RCC gravity dam in the Fengshan Reservoir Project in Qiannan Buyi and Miao Autonomous Prefecture, Guizhou Province, China. The length of the core sample is the longest among water conservancy projects within Guizhou Province, marking that the quality of construction and technology of the dam in the Fengshan Reservoir Project has reached the top standard.

The concrete pouring for the first warehouse at the Qishi Junction of the Pinglu Canal in China has started, which signifies that the three main points of operation for the Pinglu Canal have entered a new phase of building the main structure. This Pinglu Canal is the backbone of the land-sea channel that runs through the west. When it is finished and open to navigators, the canal will let the world's narrowest, most cost-effective, and most efficient ocean channel between Guangxi and Southwest China.

1. What is a polycarboxylate superplasticizer?

Polycarboxylate superplasticizer is used primarily in cement concrete to act as a dispersant. It is composed of polymers containing sulfonic acid group (-SO3H) and carboxyl groups (-COOH) or derivatives of them and features high efficacy, environmental protection, and security.

The role of a polycarboxylate superplasticizer is primarily to disperse cement particles more evenly by adhering to concrete particles' surfaces, decreasing the amount of water needed, and increasing the strength and flexibility of concrete in the process. Compared to traditional water-based water-reducing agents, polycarboxylate agents have a higher water reduction rate and workability that can significantly enhance the performance and strength of concrete.

2. Superplasticizers that are applied to polycarboxylate.

Polycarboxylate Superplasticizer is commonly employed in cement concrete as a dispersant. Apart from its use in bridges, highways, tunnels, dams, high-rise buildings, and various other engineering areas, it is extensively utilized for grouting, pouring material such as anchoring, plugging the waterproof mortar K11 cement self-leveling, prefabricated components, special mortars, and various other construction materials. The applications of polycarboxylate superplasticizers in these areas will be described below.

1. Highway Engineering

In highway engineering, superplasticizers made of polycarboxylate are used to make high-performance highway concrete, which can increase durability and wear endurance on the surface of roads. The superplasticizer polycarboxylate's water-reducing capacity can significantly reduce water consumption in concrete, increase concrete's strength and flexibility, and make the road surface more dense, smoother, other, smoother, and more robust. The use of polycarboxylate superplasticizers in highway engineering will fulfill the highway construction's safety, green, and durability demands.

2. Bridge Engineering

When it comes to bridge design, superplasticizers made of polycarboxylate can be used to create bridge concrete with great strength and fluidity to increase bridges' bearing capacity and service life. The high water-reducing capacity and high workability of the polycarboxylate superplasticizers can significantly enhance Bridge concrete's performance, increase the uniformity and compactness of concrete, lessen the formation of bridge cracks, and consequently increase the longevity and safety of bridges.

3. Dam Project

When it comes to dam design, superplasticizers made of polycarboxylate are used to make high-strength, high-impermeability dam cement to increase the stability and security of the dam. Dams are an essential structure that stores water resources and manages water flow. It also has demanding requirements for the stability and safety that the dam. Utilizing polycarboxylate superplasticizers will increase the resistance and impermeability of concrete dams and effectively stop cracks and leakage, improving the dam's stability and security.

4. Tunnel Engineering

Tunnel engineering is a field where superplasticizers of polycarboxylate are used to make high-strength and high-impermeability tunnel concrete to increase the durability and stability of the tunnel. Tunnels are crucial underground structures used for transport and transport, so the requirements for durability and stability of tunnels are demanding. Using superplasticizers made from polycarboxylate will increase the durability and strength of tunnel concrete. It can effectively stop cracks and leaks, improving the tunnel's durability and stability.

5. High-rise buildings

In high-rise structures, Polycarboxylate superplasticizers are employed to make high-strength, highly-fluidity concrete for high-rise buildings to improve the safety and stability of structures. Because of the number of floors and the high building heights, their requirements for the strength of the structure and seismic performance of buildings are extremely significant. Utilizing polycarboxylate superplasticizers will enhance the strength and flexibility of high-rise concrete. It can significantly improve the strength of structures and the earthquake performance of structures, increasing the stability and security of structures.

6. Material pouring, grouting anchoring, plugging, and many more fields.

Apart from its use in engineering fields like dams, bridges, road tunnels, and high-rise structures, polycarboxylate superplasticizers are extensively used in construction materials, such as grouting agents and pouring materials, as well as anchoring and plugging. In these areas, the function of superplasticizers made from polycarboxylate is mostly by adsorption on the surfaces of cement particles, ensuring that the cement particles become more evenly distributed, thus reducing the quantity of water needed while at the same time improving the quality and consistency in the materials. These applications can fulfill various specific maintenance and construction requirements.

How do you make polycarboxylate superplasticizers?

Polycarboxylate superplasticizer is extensively utilized in cement concrete to act as a dispersant. The process of making it can be broken down into the steps below:

synthetic macromonomer

It is first necessary to create macromonomers. This is one of the primary processes in producing superplasticizers from polycarboxylate. The macromonomer is the primary component of the superplasticizer polycarboxylate that has polymer chains and polar company and can be adsorbed on the surfaces of cement particles to be superplasticizers. The most popular method used is free radicals' polymerization; the primary raw materials include unsaturated acids, such as methacrylic acid, acrylic acid, and maleic acid, and polymers like polypropylene glycol and polyethylene glycol. In the process of synthesis, it is crucial to regulate the temperature of the reaction and time, as well as the proportion of ingredients and other variables, to ensure the yield and quality of the macromonomer.

Polymerization

Once the macromonomer has been synthesized, a polymerization reaction is necessary. The polymerization reaction will react to the macromonomer using an oxidizing agent, such as ammonium persulfate, to create one with a higher level of polymerization. When performing this procedure, it is important to be aware of variables like reaction temperature and the time and quantity of oxidant used to ensure the polymerization process's efficiency as well as the quality of the product.

Post-processing

After the polymerization reaction is complete, post-treatment is needed. The post-treatment process involves dissolving the water and polymer to the ratio specified, adding acidic compounds for neutralization, adjusting the pH that the solution has, and then the addition of a protective colloid as well as other components to produce the final superplasticizer made of polycarboxylate. It is essential to regulate the amount of solution, the pH value, the kind and amount of protective colloid, and other variables to guarantee the quality and effectiveness of the solution.

4. Market prospects analysis of superplasticizer polycarboxylate

Due to the rapid growth in the field of construction, demand for polycarboxylate superplasticizers is growing, and the opportunities are vast. This article will examine the potential market for superplasticizers made from polycarboxylate based on the demand for market products, the policy environment, technological advancement, competition patterns, and the latest trends.

1. Market demand

As urbanization is accelerating and the continued development in infrastructure development, the demand for cement concrete has been growing each year, driving the demand for superplasticizers made of polycarboxylate. Polycarboxylate superplasticizer offers the benefits of an excellent water-reducing capacity, a high working capacity, a lower shrinkage rate, and so on. It can also significantly enhance the performance and durability of concrete. This is why it is extensively used in engineering areas such as bridges, roads, dams, tunnels, and high-rise structures. A lot of people use it. As the years progress, due to the constant advancement in infrastructure construction and the constant improvement in the quality of buildings, the need for polycarboxylate superplasticizers will continue to increase.

2. Policy environment

After the pandemic struck the world, various policies for improving the construction industry have been introduced, and across the globe are now recognizing the importance of infrastructure to spur economic development. One of them is the Chinese "Outline for the Modernization of the Construction Industry," which recommended that by 2030, the size of the construction industry would reach the target of around 20% of the nation's GDP. In the meantime, China's standards for environmental protection and conservation of energy are getting strict, and this provides an incentive for policymakers to develop superplasticizers that are made of polycarboxylate. Similar policies have been enacted across China to encourage and facilitate the manufacturing and utilization of polycarboxylate superplasticizers. Also boosting demand for superplasticizers made of polycarboxylate.

3. Development of technology

With the constant advancement of new technology and science, polycarboxylate superplasticizers' manufacturing technology and performance are constantly upgraded. Today, superplasticizers made by polycarboxylate manufacturers from around the globe are continuously pursuing technological research, development, and development and have introduced an array of brand new superplasticizers made of polycarboxylate including high water-reducing models and high slump retention varieties and those with low shrinkage. Wait. Introducing these products will further expand the scope of polycarboxylate superplasticizers' applications and market spaces.

4. Competitive landscape

The polycarboxylate superplasticizer market has developed into a remarkably competitive pattern of fierce competition. Certain well-known and well-known foreign construction materials firms are using the market for polycarboxylate superplasticizers and launching various items and products. However, smaller companies are also gaining entry into the market, and competition is growing increasingly fierce. In today's competitive market, businesses must continue to increase their service and product quality levels and cut production costs to gain market share.

5. Trends

Shortly, due to the constant growth within the industry of building the market for superplasticizers made from polycarboxylate will be able to present these trends.

High performance In developing engineering requirements, the performance of polycarboxylate superplasticizers has to be continually improved to meet the needs of high-performance concrete.

Protection of the environment: As environmental protection requirements and energy efficiency are becoming increasingly demanding, polycarboxylate superplasticizers must be more eco-friendly and energy-efficient.

Customization Diverse concrete fields and industries require different kinds of superplasticizers made of polycarboxylate to ensure that consumers will accept personalized polycarboxylate products.

Intelligent: With the advancement of technologies for information and intelligence, the next polycarboxylate superplasticizer will be more sophisticated and capable of achieving automatic production and intelligent use.

In the end, the potential for market share growth for superplasticizers made of polycarboxylate is huge. However, it is necessary for businesses to constantly improve the quality of their services and products to satisfy the changing demands of the market and to adapt to changes. In the meantime, continuous technological research, as well as innovation and advancement, are vital to meet the market's needs and predict future growth trends.

Why does properly poured concrete end up cracking

It is very easy to cause concrete cracking if the construction or maintenance are not done correctly. What are then the five main causes of cracking concrete?

1. The cement problem: Some workers in construction will add more water for a more fluid concrete. However, this will result in an increase in water-cement, causing the concrete to harden too quickly, and cause cracking.

2. Transport and mixing issues: If mixing and transporting concrete takes too much time, the water in the concrete will evaporate quickly. concrete . This leads to a concrete that is weaker on the construction site, unable to meet construction specifications.

3. Construction speed

4. Maintenance is unreasonable. During the period of maintenance, if late watering isn't maintained, the result will be the Cracking phenomenon Later in the year, concrete will be used. Concrete is used in the future. Concrete Surface Watering You can water the concrete often to speed up the drying process. Concrete will shrink if it is not watered. Late cracking occurs when concrete strength is decreased.

5. Environmental factors: If the environment at the construction site is relatively dry and there is high temperature, wind, or both, then the concrete surface evaporation is accelerated. This results in cracking on the concrete's surface. Concrete constructions are most likely to crack in the winter or summer because of the temperature differences.

Add a composite anti-cracking agents, which are made of inorganic materials, to prevent foam concrete from cracking. Add 2 to 3 kilograms per cubic foot.

What is Molybdenum disulfide MoS2 powder

Description of Molybdenum diulfide

Molybdenum disulfide (also known as MoS2) is a transition metal sulfide. It is dark grey, or black solid. The layers of the crystal structure are made up of alternate arrangements of sulfur and Molybdenum. Molybdenum disulfide This material is known for its chemical and thermal resistance. It can be easily reacted to acids or bases. It is a widely used ingredient in lubricants. As an excellent oil, molybdenum diulfide offers a high load bearing capacity, low friction coefficient and good friction resistance. This is why it's widely used by the machinery, petrochemicals and automobile industries. In extreme environments such as high temperature, high loads and fast speeds, molybdenum diulfide plays a lubricating and reducing friction role. This can extend the service of equipment. Molybdenum diulfide, when used in fuels, can increase the efficiency of combustion and reduce pollutants. This additive plays a major role in protecting the environment, as it reduces air pollutants and improves energy efficiency.

Use of Molybdenum diulfide

Molybdenum diulfide is a compound that has outstanding chemical and physical properties. It is widely used in many fields. It has excellent chemical and mechanical properties. Following are some of the most important applications for molybdenum sulfide.

Lubricants - Molybdenum Disulfide, a lubricant that is excellent for its high load carrying capacity, low friction coefficient, and good resistance to friction. It has a high lubrication capacity in high-temperature, high-load and high-speed environments. This is why it's widely used in the machinery industry, automobile manufacturing, and petrochemical industries. Molybdenum Disulfide Lubricant is also used to produce lubricating grease, lubricating film and lubricating oil.

Additive - Molybdenum Disulfide, when used as a fuel additive, can increase the efficiency of combustion and reduce emissions. This additive plays a major role in protecting the environment by reducing air pollution and improving energy efficiency. As an additive, molybdenum can be added to rubber, plastics or coatings in order to improve their properties.

Composite materials. Molybdenum disulfide, when combined with rubber, resins and other materials, can produce high-performance materials such as composite fibres or reinforced plastics. These composites offer excellent mechanical properties, corrosion resistance and can be used in many industries including automotive, electronics and aerospace.

Electronic Industry Molybdenum disulfide It can be used for the electronic vapour deposition of thin MoS2 films. These thin films have excellent electrical conductivity, and transmit light well. This thin film material is suitable for optoelectronics applications, including solar cells and displays. The molybdenum-disulfide material can also be used to create transistors, Field-Effect Transistors and other electronic components. These electronic components have excellent semiconductor performance and good electronic mobility.

Production Methods of Molybdenum Diulfide

Molybdenum diulfide, a compound with excellent chemical and physical properties, is used in numerous fields. The production process can be done in many ways, including double decompositions, flotation and electroplating. Synthesis is the most commonly used method for producing molybdenum.

The synthesis is a way to make nano MoS2 using a molybdenum, tungsten source. This method can produce sulfides of high purity with fewer impurities. This method can produce sulfides to meet a variety of functional requirements. The steps in the synthesis include preparation of raw materials, chemical reactions, product separation, and purification.

In the stage of raw material preparation, it is necessary to prepare a tungsten source or a molybdenum one. Tungsten, molybdenum or metal powders are the most common sources. While sulfur can be either elemental sulfur or sulfide. The purity, chemical properties and reactions conditions of the raw materials are important factors to consider when selecting tungsten and molybdenum or sulfur sources.

In the chemical reactions stage, tungsten is Molybdenum Sources The molybdenum is disulfide produced in biochemical reactions that occur at high temperatures. Specific conditions for the reaction include temperature, reaction time, and reaction atmosphere. The temperature and reaction time of the reaction have an important effect on particle size and product purity. Reaction atmosphere has a similar impact.

In the separation and purification phase, molybdenum must be separated from the reaction products. Separation and purification techniques are required. Precipitation, filtration and distillation are some of the most common separation and purification processes. These methods can be used to separate the molybdenum diulfide from impurities and obtain molybdenum products with high purity.

Other methods are available to produce molybdenum sulfide. These include the double decomposition technique, the flotation method, and the electroplating technique.

The compound decomposition technique produces molybdenum by reacting ammonium motate or ammonium tantate with ammoniumsulfide. The method is able to produce molybdenum sulfide even at lower temperatures. It can also prepare different molybdenum sulfide products, such as those with different particle sizes and morphologies.

Flotation is the process of extracting molybdenum diulfide by using organic agents and grinding tungsten, molybdenum or other sources with minerals like pyrite or Sphalerite. This method is able to produce molybdenum products with high purity, but requires a more complicated production process and more organic agents.

Electroplating is the process of electroplating molybdenum on a metal surface. By using this method you can create molybdenum-disulfide films that have excellent properties. However, the chemicals and waste liquids in the electroplating will pollute the surrounding environment.

Different production methods offer different advantages and drawbacks. You should choose the best method for your needs. It is also important to consider environmental protection and safety during the production process.

Prospect Market of Molybdenum Diulfide

Molybdenum diulfide is an important chemical compound that has excellent chemical and physico-chemical properties. It's widely used in machinery, industry, electronics, aviation, and other fields. Demand for molybdenum diulfide has increased due to the growth of high-tech industries and the constant development of the world economy. Molybdenum Disulfide Market has a wide range of prospects for the future.

Molybdenum Disulfide, as a highly-performance lubricant used in a variety of fields, including machinery manufacturing and automobile manufacturing. As industrialization continues and mechanical equipment becomes more precise and automated, the demand for lubricants will increase. Molybdenum diulfide has a high performance and is in great demand.

In the second place, molybdenum dioxide can be added to fuels as an additive that will improve combustion efficiency, reduce pollution, reduce air pollutants and increase energy efficiency. As environmental awareness continues to grow and environmental policies are strengthened, the use of molybdenum dioxide as a green additive will continue to be promoted.

Molybdenum diulfide, when combined with other materials such as resins, fibres composites, rubbers and others, can also be used to produce high-performance materials. These composites have excellent mechanical and corrosion-resistant properties and are widely used by the automotive, electronics, aerospace and other industries. High-performance materials are in high demand due to the rapid growth and development of the high-tech industry. Molybdenum is one component and will see its demand increase.

The molybdenum-disulfide compound can be used for new applications such as energy storage and solar cells. As new energy technologies continue to be developed, demand for molybdenum will increase. This will provide new momentum for the development of the market.

In addition, as the production costs are reduced and the process is continuously improved, the price for molybdenum will continue to fall, which will encourage further growth in the market. In parallel, as environmental awareness increases and technological progress continues, new production technologies and processes will be introduced to the production process of molybdenum. This will further promote the growth of the market for molybdenum.

According to a recent report from a market-research company, global molybdenum sulfide sales will grow at ten percent per year in the coming years. Globally, it is estimated that the molybdenum-disulfide industry will surpass $1 billion in 2025. China is a big producer and user of molybdenum, so the market will continue to grow rapidly.

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What is Boron carbide

Boron carburide is a high-performance carbon compound, which is composed primarily of boron, carbon, and other elements. The chemical formula for B4C is B4C. It is a carbon compound with excellent properties, mainly composed of boron and carbon elements, with the chemical formula B4C. This article will give a detailed description of the physical properties and chemical composition, as well as preparation methods, performance characteristics, and applications fields, for use in research and other fields.

Physical properties

Boron carbide, a non-metallic inorganic material with a density of 2.52g/cm3, is a dense material. It has a cubic lattice structure, a dense black crystal and a 0.243nm lattice constant. Boron carbide exhibits a low electrical conductivity of only 10-6S/m, and has excellent insulation. It has a thermal conductivity of 97W/m*K. This is lower than metals, silicon and ceramics but higher than glass and other materials.

Chemical properties

Boron carbide exhibits chemical stability, and it is not reactive to acids and alkalis. B4C is reactive with O2, H2O and other substances. High temperatures can generate B2O3, CO etc. B4C has anti-oxidant and corrosion resistance. This makes it suitable for use over a long period of time in high-temperature, corrosive environments.

Preparation method

Preparation methods for boron carbide The main methods are the carbon thermal decomposition method, arc melting and chemical vapour deposit method.

Methode de réduction du carbothermal

Carbon thermal reduction (CTR) is widely used to prepare boron carbide . This method generates carbon dioxide and boron carburide by melting boric black and carbon. The reaction formula is B2O3+3C + B4C+CO. The reaction temperature ranges from 1500 to 1700°C. The method has the advantage of being simple, low-cost, and easy to use. However, the boron carbide produced is not of high purity.

Arc melting method

In the arc melting process, graphite electrodes are heated and melted in an arc with boric acid to create boron carbide. The reaction equation is: B2O3+3C + B4C. Reaction temperature is usually 18002000 degrees. The boron-carbide prepared using this method is high in purity, with fine particles. However, the process is complicated and expensive.

Chemical vapour deposition method

Chemical vapour deposition uses the reaction of gaseous carbon black and borane at high temperature to create boron carburide. The reaction formula is B2H6+6C B4C+6H2. The reaction temperature ranges between 1000-1200°C. This method yields boron-carbide with superfine particles and high purity, but is costly and complex.

Performance Characterization

The performance characterisation of boron carbide The term primarily includes chemical, physical and mechanical characteristics.

Physical property

Density, conductivity, thermal resistance, etc. are the main physical properties of Boron carbide. The density is 2.52g/cm3, conductivity 10-6S/m, and thermal conductivity 97W/m*K.

Chemical Property

Boron carbide exhibits chemical stability, and it is not reactive to acids and alkalis. B4C is reactive with O2, H2O and other substances. High temperatures can generate B2O3, CO etc. B4C has anti-oxidant and corrosion resistance. This makes it suitable for use over a long period of time in high-temperature, corrosive environments.

Mechanical property

Boron carbide's high hardness, melting temperature, and heat transfer make it a popular material in many industries. Hardness of 3500kg/mm2, melting point 2450, and heat transfer rate 135W/m*K are among the characteristics that make boron carbide so popular in industries, military, aerospace, and other fields.

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