Showing 25–32 of 32 results
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- Good Thermoelectric Performance: SnSe offers high thermoelectric efficiency, making it suitable for power generation and solid-state cooling systems.
- Favorable Bandgap: SnSe has a direct bandgap of ~1.3 eV, which is ideal for absorbing sunlight in photovoltaic devices.
- Low Thermal Conductivity: Its ability to maintain a high thermoelectric figure of merit (ZT) due to low thermal conductivity is a key feature in energy conversion materials.
- High Absorption Coefficient: SnSe shows strong absorption in the visible and NIR spectrum, making it useful in light-harvesting applications.
- Stable Thin Films: SnSe can form stable, high-quality thin films via thermal or e-beam evaporation methods.
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- High Purity: ≥ 99.99% purity for optimal thin-film deposition.
- Layered Crystal Structure: Supports efficient film formation and exfoliation.
- Exceptional Thermoelectric Performance: High Seebeck coefficient and low thermal conductivity.
- Broad Application Range: Versatile for electronic, photovoltaic, and thermoelectric uses.
- Customizable Options: Available in various sizes, shapes, and bonding configurations.
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- High Purity: Available with ≥99.9% purity for optimal performance.
- Outstanding Thermoelectric Properties: High ZT values make it ideal for thermoelectric devices.
- Semiconducting Properties: Exhibits excellent electrical conductivity and thermal insulation.
- Environmentally Friendly: Non-toxic and abundant, aligning with sustainability goals.
- Customizable Particle Sizes: Nano and micron-scale powders to meet specific requirements.
- Thermal Stability: Performs effectively at high temperatures.
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- High Purity: ≥ 99.99% purity ensures consistent and efficient thin-film deposition.
- Layered Structure: Promotes easy exfoliation and high-quality thin-film production.
- Exceptional Optical and Electrical Properties: High carrier mobility and excellent absorption coefficients.
- Thermoelectric Efficiency: Strong performance in thermal-to-electric energy conversion.
- Customizable Options: Tailored sizes and shapes to suit diverse applications.
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- High Purity: Ultra-pure WSe₂ for reliable and repeatable performance.
- Layered Structure: Two-dimensional material with strong in-plane bonding and weak interlayer van der Waals forces.
- Exceptional Optical Properties: Ideal for applications requiring precise light absorption and emission.
- Chemical Stability: Resistant to oxidation and degradation in harsh environments.
- Customizable Particle Size: Tailored to specific research or industrial needs.
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- High Purity: ≥99.9% purity for enhanced performance and reliability in advanced applications.
- Layered Structure: Exhibits a two-dimensional structure, similar to graphene, allowing for unique electronic and optical properties.
- Optical Properties: Strong photoluminescence and excellent performance in the infrared (IR) spectrum, suitable for optoelectronic applications.
- Electronic Performance: High electron mobility, making it an ideal candidate for transistors, sensors, and other electronic devices.
- Stable and Durable: Resilient under a variety of environmental conditions, including exposure to moisture and oxygen.
- Scalable Production: Available in different quantities and customizable particle sizes to meet specific application needs.
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- Broad Infrared Transmission: Covers visible to far-IR regions (0.5–22 μm).
- High Refractive Index: Suitable for focusing and imaging applications.
- Low Bulk Absorption: Enables high-power CO₂ laser operation.
- Excellent Thermal Shock Resistance: Suitable for high-power, high-temperature environments.
- Chemical Stability: Resistant to moisture and most chemicals in ambient environments.
- Isotropic Optical Properties: Minimal birefringence effects.
- High Damage Threshold: Ideal for high-power laser optics and windows.
- Good Mechanical Strength: Though softer than sapphire, sufficient for most optical setups.
- Compatible with Anti-Reflection (AR) and Protective Coatings: Enhances performance and durability.
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- Broad Optical Transmission: ZnSe offers high transmission from the visible to the IR range (0.6 µm to 16 µm), making it ideal for infrared optics and laser systems.
- High Laser Damage Threshold: ZnSe can withstand high-power laser radiation, making it a preferred material for CO₂ laser optics and other high-energy laser applications.
- Chemical and Thermal Stability: ZnSe is chemically stable and has good thermal shock resistance, ensuring reliable performance in challenging environments, such as thermal imaging and industrial laser systems.
- High Purity and Low Absorption: ZnSe sputtering targets are available in high purity (up to 99.999%), ensuring minimal absorption and optimal performance in optical coatings and laser optics.
