Cadmium Stannate Nanoparticles
Cadmium Stannate Nanoparticles
| Cadmium Stannate Nanoparticles | |
| Product No | NRE-5038 |
| CAS No. | 12185-56-7 |
| Formula | Cd2SnO4 |
| APS | <100 nm (Can be Customized) |
| Purity | 99.9% |
| Color | White |
| Molecular Weight | 407.49 g/mol |
| Density | NA |
| Melting Point | NA |
| Boiling Point | NA |
Cadmium Stannate Nanoparticles
Applications
Photovoltaic Devices and Solar Cells
Due to their semiconducting and optical properties, CdSnO₃ nanoparticles are being investigated for use in photovoltaic devices. The ability of CdSnO₃ to absorb UV and visible light makes it a promising material for solar cells, especially in thin-film solar cells or quantum dot-based solar cells.
CdSnO₃ can be incorporated into solar cell electrodes to improve their efficiency, potentially contributing to next-generation solar technologies.
Gas Sensors and Chemical Sensors
CdSnO₃ nanoparticles have been explored for use in gas sensors, particularly for the detection of toxic gases or pollutants in the environment. Due to their high surface area and semiconducting properties, these nanoparticles can change their electrical conductivity in the presence of specific gases, such as ammonia, methane, or carbon monoxide.
They are also used in chemical sensors for monitoring various chemicals in industrial processes, healthcare, and environmental monitoring.
Catalysis and Environmental Remediation
Catalysis is another area where CdSnO₃ nanoparticles show potential. Their high surface area and semiconducting properties make them effective in photocatalysis, where they can facilitate the breakdown of pollutants under light irradiation. This property is useful in water purification, air quality improvement, and the degradation of organic contaminants.
CdSnO₃ nanoparticles can also be employed in heterogeneous catalysis, aiding in chemical reactions such as dehydrogenation and oxidation processes.
Energy Storage
CdSnO₃ nanoparticles are studied for their potential in energy storage devices, including supercapacitors and batteries. Their semiconducting properties and chemical stability can enhance the performance of these devices by improving the charge/discharge cycles and energy efficiency.
These nanoparticles can be incorporated into the electrode materials for batteries and supercapacitors, helping to improve their energy density and power output.
