Nano Strontium Zirconate - for Catalysts, dental applications

Nano Strontium Zirconate, a material with unique properties, has a wide range of applications due to its high thermal stability, chemical inertness, and excellent mechanical properties. It is particularly useful in the following areas:

1. Solid Oxide Fuel Cells (SOFCs): Nano Strontium Zirconate is used as an electrolyte material in SOFCs due to its high ionic conductivity at lower temperatures, which enhances the efficiency of the fuel cell .

2. Thermal Barrier Coatings: The material's high melting point and thermal insulation properties make it suitable for use in thermal barrier coatings for aerospace and automotive industries, where it protects against high-temperature degradation .

3. Catalysts: Its catalytic properties are utilized in various chemical reactions, particularly in the petroleum and chemical industries for processes such as cracking and reforming .

4. Refractory Materials: Due to its resistance to high temperatures and chemical corrosion, Nano Strontium Zirconate is used in the manufacture of refractory materials for furnace linings and other high-temperature applications .

5. Optical Applications: The material's optical transparency and low thermal conductivity make it suitable for use in optical devices and thermal imaging technologies .

6.Pharmaceutical and Biomedical Applications: Nano Strontium Zirconate is being researched for its potential use in drug delivery systems and as a biomaterial in medical implants due to its biocompatibility .

7. Environmental Applications: It can be used in water treatment processes to remove heavy metals and other pollutants, taking advantage of its adsorption properties .

8. Energy Storage: Nano Strontium Zirconate is also being explored for its potential in energy storage devices such as batteries and supercapacitors, owing to its electrochemical properties .

These applications highlight the versatility of Nano Strontium Zirconate and its importance in various industries. Ongoing research continues to explore new methods of synthesis and applications to fully exploit its potential.