CuS nanoparticles

Product Name

Name:CuS nanoparticles

^{Product Overview}

Semiconductor nanoparticles have easy to regulate physical, chemical, magnetic, and optical properties, and their importance in applications such as cancer and other diseases detection, treatment, drug delivery, and in vitro biosensing is increasing. Copper sulfide (CuS), as a p-type semiconductor with excellent optical and electrical properties, is also being explored by many researchers for its biological applications. Cu based nanomaterials exhibit photon properties, including PTT and PDT, and chalcogenides (Cu2 xE, E: S, Se, Te, 0 ¡ãCx ¡ãC1) exhibit stoichiometrically dependent local surface plasmon resonance (LSPR) absorption in the NIR range, making them widely studied in photon triggered disease treatment.

^{Technical Parameter}

Appearance：Gray-green colloidal dispersion

Concentration:1mg/ml（Concentrations can be customized up to 10 mg/mL:/span>

Zeta potential:20mV

Note: Zeta potential data is a single measurement data, and it is allowed to float between different batches.

^{Product Features}

Stability: CuS nanoparticles have stable properties and are not prone to chemical changes, which provides a good foundation for their application in various environments.

Optical performance: As a p-type semiconductor, CuS nanoparticles have strong absorption ability for near-infrared light (NIR), which makes them unique in the fields of optoelectronic materials and biomedical applications.

Photothermal effect: CuS nanoparticles can convert received light energy into thermal energy, which provides possibilities for their applications in photothermal therapy, photothermal imaging, and other fields.

Surface modifiability: The surface of CuS nanoparticles can be functionalized, such as modifying carboxyl groups, which provides convenience for their further functional applications.

Low cytotoxicity: As a biocompatible material, CuS nanoparticles have high safety in the biomedical field.

Application Fields

Optoelectronic materials: By utilizing the strong absorption ability of CuS nanoparticles towards near-infrared light, they can be applied to photovoltaic conversion devices such as solar cells and photodetectors to improve the photoelectric conversion efficiency.

Biomedical field: CuS nanoparticles have received widespread attention as photothermal agents in the biomedical field. Photothermal therapy (PTT) is a treatment method that uses NIR light absorbers to absorb near-infrared light and generate heat to ablate cancer cells. CuS nanoparticles have excellent near-infrared optical properties and low cytotoxicity, making them a promising photothermal therapeutic agent.

Environmental governance: CuS nanoparticles can also be used in fields such as water pollution control. Its excellent catalytic performance and stability enable it to play an important role in the degradation and removal of environmental pollutants.

Supercapacitors: CuS nanoparticles are used as electrode materials due to their metal like conductivity and excellent redox reactions with polysulfide electrolytes. Research has shown that supercapacitors prepared by combining CuS with other materials have high energy density, power density, and good cycling stability.

Related Information

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