Product Overview
Hiyka's Zn-Cu-In-S/ZnS Quantum Dots (QDs) represent the latest in quantum dot technology, offering a cadmium-free, hydrophilic solution for various high-tech applications. Engineered for safety and performance, these quantum dots are designed to meet the rigorous demands of industries ranging from biomedicine to renewable energy. With their unique optical and electronic properties, our Zn-Cu-In-S/ZnS QDs are poised to revolutionize fields such as bioimaging, diagnostics, solar energy, and optoelectronics.
Key factor
Low Cadmium Content: Provides a safer alternative to traditional cadmium-based quantum dots, minimizing environmental and health risks.
Hydrophilic Surface: Enhanced with a water-affine coating, ensuring excellent dispersibility in aqueous and biological environments.
High Quantum Yield: Delivers bright, stable luminescence for superior performance in imaging and lighting applications.
Tunable Emission: Offers tunable emission wavelengths across the visible to near-infrared spectrum, enabling customization for specific applications.
Robust Chemical Stability: Features a strong chemical resistance and photostability, ensuring long-lasting performance under various conditions.
Applications
Bioimaging and Diagnostics: Ideal for use in fluorescent labeling and tracking within biological tissues, providing clear, vibrant imaging for medical diagnostics.
Solar Energy: Enhances the efficiency of solar cells by extending light absorption into the near-infrared spectrum, improving photovoltaic performance.
Optoelectronics: Applied in LED devices and displays for bright, energy-efficient lighting and high-definition screens.
Environmental Sensing: Utilized in sensors for detecting pollutants and toxins, offering high sensitivity and rapid response times.
Advantages
Enhanced Safety: Low cadmium content reduces toxicity concerns, making these QDs safer for medical and environmental applications.
Superior Optical Properties: Bright luminescence and tunable emission wavelengths enable high precision in imaging and color rendering.
Wide Compatibility: Hydrophilic nature allows for easy integration into various aqueous-based systems, including biological and environmental samples.
Energy Efficiency: Offers potential for high-efficiency solar energy conversion and low-energy lighting solutions.
Innovative Potential: Opens new possibilities for research and development in nanotechnology, biotechnology, and renewable energy.
References
- Fabio Lisi, Jun Sawayama, Shreedhar Gautam, Sergey Rubanov, Xiaofei Duan, Nicholas Kirkwood. Re-Examination of the Polymer Encapsulation of Quantum Dots for Biological Applications. ACS Applied Nano Materials 2023, 6 (5) , 4046-4055.
- İrem Nur Gamze Özbilgin, Tomohiko Yamazaki, Junpei Watanabe, Hong-Tao Sun, Nobutaka Hanagata, Naoto Shirahata. Water-Soluble Silicon Quantum Dots toward Fluorescence-Guided Photothermal Nanotherapy. Langmuir 2022
- Shunsuke Yamashita, Mamoru Tanabe, Takumi Araki, Michinori Shiomi, Toshio Nishi, Yoshihiro Kudo. Nanostructure–Optical Property Relationship in CuInSe2/ZnS Core/Shell Quantum Dots Revealed by Multivariate Statistical Analysis of X-ray Spectrum Images. The Journal of Physical Chemistry C 2022,
10mg, 25mg, 100mg