The concentrate based on quasi-crystalline phases is an innovative solution for obtaining filled thermoplastic polymer compositions. Quasi-crystalline phases, having a unique structure, provide the possibility of significantly improving the mechanical and thermal properties of polymers, which makes them ideal for use in various industries.
The method of its production consists of using mechanical and thermal synthesis processes, which allow achieving the necessary homogeneity and stability of the resulting material. At the first stage, a quasi-crystalline structure is formed, which is carried out by controlled heating and mixing of the initial components under inert atmosphere conditions. The next stage is dispersion of the obtained phase in thermoplastic matrices, which allows achieving uniform distribution of the filler and its optimal interaction with the polymer base.
The use of this concentrate contributes to a significant increase in the performance characteristics of final products, such as impact resistance, heat resistance, and also improves processing processes, which makes it indispensable for manufacturers of high-quality polymer products.
Quasicrystals have unique physical and chemical properties, which opens up a wide range of applications. They are used as additives to improve material properties such as strength, wear resistance, and heat resistance. Key applications include the production of lightweight and durable alloys, as well as in electronics to create highly effective thermal barriers.
Concentrates based on quasicrystalline phases can be used to obtain filled thermoplastic polymer composites. These composites have improved mechanical properties and stability at high temperatures.
The method for obtaining such concentrates consists of mechanical mixing of quasi-crystalline powders with thermoplastic matrices, as well as in extrusion processes, which allow achieving a uniform distribution of quasi-crystals in the polymer. This provides improved characteristics, such as reduced thermal conductivity and increased strength of the material. Thus, quasi-crystals open up new horizons in the development of modern composite materials.
Quasicrystals, which have a unique order in their structure and unusual physical properties, are widely used in various industries. In particular, they are used as additives to improve the characteristics of thermoplastic polymers, creating composites with increased strength, rigidity and heat resistance. [BR] A concentrate based on quasicrystalline phases can be obtained through mechanical crushing or mixing methods together with polymer matrices. This approach allows for a uniform distribution of quasicrystalline phases in the polymer, which increases its resistance to deformation and significantly improves heat resistance.
In addition, quasicrystals have a low coefficient of friction and high wear resistance, making them ideal for use in advanced composites used in aviation, automotive, and electronics manufacturing. These properties open up new prospects for the creation of high-performance materials that can be used under extreme temperatures and mechanical loads.
Quasi-crystalline phases are unique structures with anomalous symmetries and properties that can be used to produce highly effective composites based on thermoplastic polymers. Concentrates based on them can significantly improve the mechanical and thermal characteristics of polymeric materials.
Additionally, the use of quasi-crystalline phases in filled thermoplastic polymers opens up new possibilities for improving barrier properties, which is especially relevant for packaging materials. Quasi-crystals have low gas permeability, which allows for a significant extension of the shelf life of products, protecting them from external factors. This quality is ideal for creating packaging that requires minimal environmental impact.
In addition, the use of such compositions in the automotive industry can have a positive effect on the energy efficiency of vehicles. Improved mechanical properties and reduced weight can lead to lower fuel consumption and reduced emissions. Quasi-crystalline fillers can also play an important role in improving vehicle safety by increasing the strength of the structure and improving the behavior of materials under impact loads.
Research in this area is ongoing, and scientists are actively looking for new ways to synthesize and integrate quasi-crystalline phases into polymer matrices. This creates the potential for developing new products that will offer not only improved performance but also more environmentally friendly solutions.