Showing 13–24 of 36 results
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- High purity (≥99.99%).
- Outstanding thermoelectric and electrical properties.
- Stable crystalline structure.
- Uniform pellet size for consistent deposition outcomes.
- Tailored sizes and shapes available to meet application requirements.
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- High Purity: ≥99.5% purity for optimal thin-film quality.
- Stable Composition: Ensures consistent performance during sputtering.
- Excellent Electrical Conductivity: Suitable for functional thin-film coatings.
- Thermal and Chemical Stability: Performs reliably under various sputtering conditions.
- Customizable: Adaptable to specific equipment and application requirements.
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- Superior Electrical Conductivity: Ensures efficient current flow in electrical applications.
- High Thermal Stability: Performs reliably under extreme temperatures.
- Excellent Wear Resistance: Durable material ideal for high-stress environments.
- Customizable Compositions: Flexible Cu-Cr ratios to meet specific requirements.
- Versatile Particle Sizes: Available in nano and micrometer scales for diverse applications.
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- High Electrical Conductivity: Retains copper’s excellent conductive properties.
- Mechanical Strength: Enhanced by the inclusion of iron, making it suitable for robust applications.
- Customizable Composition: Various Cu-Fe ratios tailored to specific industrial needs.
- Corrosion Resistance: Provides protection against oxidation and wear.
- Uniform Particle Size: Ensures consistency in manufacturing processes.
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- High Solar Absorption Efficiency: CuIn alloy thin films exhibit excellent light absorption properties, contributing to the high efficiency of CIGS solar cells in converting solar energy into electricity.
- Bandgap Tunability: CuIn alloys enable tuning of the material’s bandgap to optimize its performance for specific photovoltaic applications.
- Lightweight and Flexible: CuIn-based thin-film solar panels are lightweight and flexible, making them suitable for both rigid and flexible solar panel designs.
- Thermal and Chemical Stability: The CuIn alloy demonstrates good thermal and chemical stability, ensuring durability in outdoor and harsh environmental conditions, which is essential for long-lasting solar cells.
- Customizable Composition: The ratio of copper to indium in the alloy can be adjusted to meet specific application requirements, ensuring tailored properties for different solar and electronic devices.
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- High Conductivity: Excellent electrical properties ideal for semiconductor applications.
- Thermal Stability: Maintains performance in high-temperature environments.
- Compatibility: Works well with various deposition techniques, including thermal evaporation and sputtering.
- Customizable Composition: Can be tailored with different copper to indium ratios to meet specific application needs.
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- High Efficiency: Offers excellent conversion efficiency in solar cells, making it a preferred choice in renewable energy applications.
- Versatile Composition: The ability to adjust the ratio of copper, indium, and gallium allows for customization of electronic properties.
- Good Thermal Stability: Maintains performance over a wide temperature range.
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- High Solar Conversion Efficiency: CuInGaSe (CIGS) thin films exhibit high energy conversion efficiency, particularly in thin-film photovoltaic cells, making them an ideal choice for modern solar technology.
- Wide Bandgap Tunability: The presence of gallium allows for tuning the bandgap, which improves the absorption spectrum and efficiency of solar cells.
- Lightweight and Flexible: CIGS thin-film solar panels are lighter and more flexible compared to traditional silicon-based panels, enabling their use in various applications, from portable devices to large-scale installations.
- Excellent Absorption Properties: CIGS thin films offer superior absorption of sunlight across a wide range of wavelengths, making them more effective at capturing solar energy, even in diffuse or low-light conditions.
- Stable in Harsh Conditions: CuInGaSe thin films provide stability and performance reliability in a range of environmental conditions, ensuring long-lasting performance in solar panels.
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- Exceptional Electrical Conductivity: Delivers efficient current flow for electrical systems.
- High Thermal Stability: Operates reliably under extreme temperature conditions.
- Excellent Mechanical Strength: Provides durability in demanding environments.
- Customizable Cu-Nb Ratios: Tailored compositions for specific applications.
- Diverse Particle Sizes: Available in nano to micrometer scales for various needs.
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- Excellent Electrical and Thermal Conductivity: The copper base ensures superior electrical and thermal conductivity, making it ideal for electronic applications.
- Corrosion Resistance: The addition of nickel and titanium enhances the alloy’s resistance to corrosion, ensuring the longevity of thin films in harsh environments.
- High Strength and Durability: Titanium adds mechanical strength to the alloy, while nickel contributes to its hardness and wear resistance, making it suitable for demanding applications.
- Thermal Stability: CuNiTi alloys maintain their properties at elevated temperatures, making them ideal for high-temperature processes and environments.
- Customizable Properties: The ratio of copper, nickel, and titanium can be adjusted to tailor the alloy’s specific properties for a wide range of applications.
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- Narrow Bandgap: CuO is a p-type semiconductor with a narrow bandgap (~1.2-1.7 eV), making it suitable for absorbing visible light, ideal for solar energy and semiconductor applications.
- High Absorption: CuO exhibits excellent light absorption in the visible range, enhancing its efficiency in photovoltaic cells and other optical applications.
- Chemical Stability: CuO thin films are highly stable, offering long-lasting performance in various environmental conditions.
- Customizable: CuO sputtering targets can be tailored in size, shape, and purity to fit specific deposition systems and applications.
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- Semiconducting Properties: CuO is a p-type semiconductor, making it valuable for use in electronic devices.
- High Absorptivity: CuO has excellent light absorption properties, which is beneficial for solar energy applications.
- Chemical Stability: CuO coatings are chemically stable and can withstand environmental exposure, enhancing the durability of the films.
- Good Adhesion: CuO thin films demonstrate strong adhesion to various substrates, including glass, silicon, and metals.
- Easy Processing: CuO can be easily deposited using standard PVD techniques like thermal evaporation or electron-beam evaporation.