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Mercury Telluride Nanoparticles

Mercury Telluride Nanoparticles

Mercury Telluride Nanoparticles
Product No NRE-5159
CAS 12068-90-5
Purity 99.9%
Molecular Formula HgTe
Molecular Weight 328.19 g/mol
Color Black
Density 8.1 g/cm3
APS <100 nm (can be customized)
Melting Point 670 °C
Boiling Point NA

Mercury Telluride Nanoparticles

These nanoparticles are one of the candidate materials found in disposable photoconductivity/photovoltaic, IR detectors and IR emitters. He applies various methods to the preparation of materials in combination with mercury nanoparticles, including combination of high-temperature elements, molecular precursor methods, and organometallic diversity synthesis.

Applications

Optoelectronics and Photodetectors

Infrared Photodetectors: Mercury telluride (HgTe) nanoparticles are well-known for their strong absorption in the infrared (IR) region of the electromagnetic spectrum. This makes them ideal for use in infrared photodetectors and sensors, which are crucial for applications such as thermal imaging, night vision, and environmental monitoring.

Infrared Sensors: HgTe nanoparticles, because of their tunable bandgap and sensitivity to infrared light, are being researched for use in IR sensors, which are important for military, security, and industrial applications that require precise detection in low-light conditions.

Quantum Dots in Optoelectronics: HgTe nanoparticles can be used as quantum dots due to their size-dependent optical properties. This feature can be utilized in light-emitting devices such as LEDs, as well as in optical communication systems and fiber optics.

Thermoelectrics and Energy Harvesting

Thermoelectric Devices: HgTe nanoparticles exhibit potential in thermoelectric applications, where they can be used to convert heat into electrical energy. These materials could play a role in the development of more efficient thermoelectric devices for energy harvesting, making use of waste heat in industrial processes, automotive systems, or power generation systems.

Energy Storage and Conversion: Due to their semiconducting nature, HgTe nanoparticles could also be used in advanced energy storage systems like supercapacitors or batteries, enhancing the efficiency and performance of energy conversion and storage devices.

Biomedical Applications

Bioimaging: HgTe nanoparticles, particularly in the form of quantum dots, have been explored for use in bioimaging. The unique optical properties of HgTe allow for enhanced imaging in biological tissues.

 

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