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The substance has an extremely high surface area and high conductivity, which allows creating powerful supercapacitors with high capacity and fast charge-discharge.


The material can be used in catalysts to speed up chemical reactions. The large surface area and chemical stability of spheroidal graphite make it attractive for catalytic purposes, for example in electrocatalysts, catalysts capable of converting hydrocarbons, or catalysts for hydrogen energy.

Electrodes in batteries

Spherical graphite can be used as an electrode material in various types of batteries, including lithium-ion batteries. It has high electrical conductivity and a large surface area, which contributes to the efficient storage and release of electrical energy.


Spherical graphite can be used in a variety of electronic devices and components, including transistors, sensors, chips and other devices. Spherical graphite has incredible electronic properties, such as high electrical conductivity, high electron mobility, and high thermal conductivity. This makes it an ideal material for the development of new generations of electronic devices, including sensors, screens and solar cells. Spherical graphite opens up new opportunities for nanoelectronics. Due to its unique properties, it can be used to create nanowires, nanotransistors and other nanoscale components.


Spherical graphite also has the potential to be used in lubricants to improve their performance. Traditional lubricants, such as mineral oil-based lubricants or polymer-based lubricants, can be improved by adding spherical graphite.

Friction reduction

Spherical graphite has a very low coefficient of friction, which means it can reduce frictional resistance between lubricated surfaces. This can lead to reduced wear and improved lubricant performance

Improved lubricity

Spherical graphite has good lubricity, meaning it can form a protective layer between contacting surfaces. This can reduce friction and wear and prevent surface damage.

Increased heat resistance

Spherical graphite has high heat resistance, meaning it can withstand high temperatures without breaking down. This makes it a useful material for lubricants used in high temperature environments or to improve heat dissipation.

Considering these factors, the addition of spheroidal graphite to lubricants can improve their properties and their performance. However, it is important to consider the specific needs and requirements of each specific application and perform appropriate technical studies to determine the optimal concentrations and conditions for adding spherical graphite to lubricants.


The addition of spherical graphite to various types of fuel can have an effect on its combustion efficiency, but the effect depends on the specific conditions and characteristics of the fuel itself. Below are some possible options for such an impact:

- Increased burning rate: Spherical graphite can have high thermal conductivity and promote faster heat distribution in the fuel mixture. This can lead to more efficient combustion of fuel and an increase in its burning rate.

- Improved Combustion Stability: Addition of spheroidal graphite to the fuel can help stabilize the combustion of the fuel by ensuring the uniformity of the distribution of heat and the combustible component. This can prevent both unstable fuel combustion and the occurrence of such problems as flickering or smoke emissions, i.e. flickering (unstable) or smoky burning.

- Emission reduction: Spherical graphite can help reduce emissions of certain harmful substances such as nitrogen oxides or particulate matter. This is due to the ability of spherical graphite to absorb and retain certain fuel components during their combustion.

It is worth noting that the effects of adding spheroidal graphite to fuel can be complex and depend on many factors, including the type of fuel, its composition, the concentration of spheroidal graphite and its combustion conditions. Detailed research and testing of options using spheroidal graphite may be necessary to determine the specific combustion effect of a specific fuel under specific conditions.



The addition of spheroidal graphite to varnishes and paints can have several potential effects.

Here are some of them:

- Increased conductivity: Spherical graphite has high electrical conductivity. Adding it to varnishes or paints can also increase the conductivity of the paint coating, which can be useful in cases where it is necessary to create electrical contacts or antistatic coatings.

- Improved thermal conductivity: Spherical graphite has high thermal conductivity. 

Adding it to varnishes or paints can improve their ability to transfer heat, which can be useful in some additional applications, such as thermal coatings or radiators.

- Improvement of mechanical properties: Spherical graphite has high strength and stiffness. Its addition to varnishes or paints can increase the mechanical strength of the coating and provide better resistance to scratches, impacts or abrasion.

- Providing corrosion protection: Spherical graphite can have properties that help form a protective layer on the coating surface that can prevent corrosion. This can be particularly useful when painting metal surfaces where corrosion protection is an important factor.

It is worth noting that the effects of adding spherical graphite to varnishes and paints can be dependent on specific conditions, including the concentration of the additive, the type of paint or varnish, the application technology and other factors. For each specific application, it is recommended to carry out appropriate studies and tests to determine the optimal conditions of use.


Spherical graphite can be used in lithium-ion batteries to improve energy storage efficiency and increase battery capacity. In addition, spherical graphite can be used in hydrogen fuel cells, where its high conductivity can improve electrolysis and hydrogen storage.

Lightweight nanocomposite materials

Spherical graphite has incredible strength and lightness, making it an ideal candidate for the production of lightweight materials. The use of spherical graphite in nanocomposites can improve the mechanical properties of materials while providing low weight and high strength.


Spherical graphite may have applications in medicine, such as biomedical diagnostics and treatment. Due to its unique properties, it can be used to develop new types of sensors for detecting chemicals or biomarkers. It can be used to create nanomaterials for drug delivery as well as to create implants and biocompatible materials.


Spherical graphite can also find applications in environmental technologies such as water and air purification. It can be used in filters to remove pollutants and harmful gases from the environment.

Water filtration systems

Spherical graphite can be used to create effective water filtration systems. Its porous structure and high surface area allow it to trap pollutants, bacteria and other harmful substances, providing clean drinking water.


Spherical graphite has very low thermal conductivity at low temperatures, making it a potentially interesting material for use in cryogenic systems. It can be used to insulate and reduce heat loss in cryogenic containers and systems.

Flexible Electronics and Wearable Devices

Spherical graphite has a unique flexibility and transparency that allows it to be used in flexible electronics and wearable device manufacturing. It can be used to create flexible touch screens, electronic socks, bandages and other flexible devices.

Aerospace technology

Spherical graphite can find applications in aerospace engineering, particularly in the creation of lightweight and strong components for aircraft, rockets and spacecraft. Its properties of strength and light weight make it an attractive material for use in structures that require maximum efficiency and low weight.

Heat transfer

Spherical graphite has high thermal conductivity and stability at high temperatures, which makes it interesting for use in heat transfer systems. It can be used in the production of heat exchangers for efficient heat transfer in various industrial processes.

Protection against electromagnetic radiation

Spherical graphite has properties of electromagnetic density, which allows it to be used to create screens and protective coatings against electromagnetic radiation. This can be important in the fields of electronics, communications and defense.

High-temperature applications

Spherical graphite has a high resistance to high temperatures, making it a potentially useful material for high-temperature applications. It can be used in the production of furnaces, thermal insulation materials and other systems that work at high temperatures.

Ultra-sensitive detectors

Spherical graphite is highly sensitive to various types of radiation, such as X-rays or particles. This makes it a potential material for creating ultra-sensitive detectors that would find applications in medicine, nuclear research and other fields.

Energy-saving systems

Spherical graphite can be used to develop energy-saving systems. High thermal conductivity allows to improve the efficiency of heat exchangers, thermoelectric devices and other energy conservation systems.

Chemical industry

Spherical graphite can be used in the chemical industry. It can be used in catalysts, electrode materials, membranes and other chemical processes to improve efficiency and save resources.

Creating superconductors

Spherical graphite may have the potential to create superconductors, or materials with high electrical conductivity at low temperatures. This can be important for the development of energy-efficient electrical devices and energy storage systems.


Spherical graphite is just one of the specific types of graphite that have unique properties and potential for a variety of applications. Its use may be limited, but research in this area is ongoing and new opportunities may emerge in the future.

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