Showing 1–12 of 46 results
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- High purity (≥99.99%).
- Outstanding dielectric and ferroelectric properties.
- Suitable for thin-film deposition techniques such as PVD.
- Uniform pellet size for consistent results in industrial and research settings.
- Custom sizes and packaging available.
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- High Dielectric Constant: BaTiO₃ is known for its exceptionally high dielectric constant, making it ideal for capacitors and electro-optic applications.
- Ferroelectric and Piezoelectric Properties: The material exhibits both ferroelectric and piezoelectric behaviors, making it suitable for memory devices, sensors, and actuators.
- Excellent Thermal Stability: BaTiO₃ maintains good thermal stability, ensuring reliable performance in high-temperature environments.
- High Purity and Low Defects: BaTiO₃ sputtering targets are available in high-purity grades (up to 99.999%), ensuring low defect densities in the deposited thin films, which is crucial for advanced electronic applications.
- Custom Composition: Barium Titanate can be tailored with dopants to modify its electrical and thermal properties, optimizing performance for specific applications.
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- High Dielectric Constant: BST has an exceptionally high dielectric constant, which can be adjusted by varying the Ba/Sr ratio, making it ideal for capacitive applications.
- Tunable Properties: The dielectric constant of BST is voltage-tunable, which is valuable in applications that require adjustable electronic properties, such as tunable filters or phased array antennas.
- Ferroelectric and Pyroelectric: BST exhibits both ferroelectric and pyroelectric properties, making it useful in memory devices and sensors.
- Thermal Stability: BST thin films maintain good stability under high temperatures, which is important for applications in electronics and microwave systems.
- Customizable Composition: The Ba/Sr ratio can be tailored to optimize specific properties, such as tunability, dielectric constant, and thermal stability, for different applications.
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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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- High Electrical Conductivity: Copper’s exceptional conductivity is maintained while incorporating titanium’s benefits.
- Enhanced Corrosion Resistance: Titanium adds corrosion resistance, making the alloy suitable for harsh environments.
- Excellent Strength-to-Weight Ratio: The inclusion of titanium provides high strength while maintaining a low weight.
- Customizable Composition: Cu-Ti powder is available in various compositions to meet specific application requirements.
- Improved Durability: Suitable for high-stress, long-life applications due to the toughness of titanium.
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- Balanced Alloy Composition: Combines Fe, Co, Ni, Al, Cu, and Ti for superior performance.
- High Strength and Durability: Exceptional mechanical properties for demanding environments.
- Thermal Stability: Operates efficiently under extreme temperature conditions.
- Corrosion Resistance: Excellent resistance to oxidation and environmental wear.
- Magnetic Properties: Suitable for applications requiring magnetic performance.
- Customizable Particle Sizes: Available in nano and micro scales for various uses.
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- High-Temperature Strength: Maintains excellent mechanical properties at elevated temperatures.
- Oxidation Resistance: Outstanding performance in oxidative environments.
- Thermal Stability: Stable microstructure under cyclic thermal conditions.
- Corrosion Resistance: Effective against chemical and environmental corrosion.
- Process Compatibility: Suitable for 3D printing, thermal spraying, and conventional metallurgy.
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- Exceptional Ionic Conductivity: Enhances energy transfer in battery technologies.
- Stable and Durable: Chemically stable under a wide range of operating conditions.
- High Dielectric Constant: Ideal for electronic and capacitor applications.
- Customizable: Available in multiple sizes, shapes, and purity levels to meet specific application needs.
- Compatible: Works efficiently with various sputtering deposition systems.
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- Mott Insulator Properties: LaTiO₃ exhibits insulating behavior despite having partially filled electronic bands, which makes it valuable in the study of Mott insulators and potential applications in quantum electronics.
- Perovskite Structure: Its perovskite crystal structure enables integration into other perovskite materials and systems, providing flexibility in multilayered thin-film devices.
- Electrical and Magnetic Properties: LaTiO₃ exhibits a combination of electrical and magnetic properties that are useful in advanced electronic devices.
- Optical Transparency: The material is transparent in certain spectral regions, making it suitable for use in optoelectronic devices.
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- High Stability: Li₄Ti₅O₁₂ has excellent chemical and structural stability, making it an ideal material for long-lasting energy storage devices.
- Low Volume Expansion: This material shows minimal expansion and contraction during charge/discharge cycles, improving battery longevity.
- Thermal Safety: Li₄Ti₅O₁₂ has a high thermal stability, reducing the risk of overheating in energy storage devices.
- Fast Charging Capability: The material is recognized for its fast charge/discharge properties, making it suitable for high-performance batteries.
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- High Corrosion Resistance: The addition of zirconium and titanium enhances the alloy’s resistance to corrosion, making it suitable for harsh environments, including semiconductor processing and aerospace applications.
- Thermal Stability: Molybdenum’s high melting point, combined with the stability of zirconium and titanium, allows MoZrTi thin films to maintain performance at elevated temperatures.
- Electrical Conductivity: MoZrTi alloy thin films provide good electrical conductivity, ideal for applications in electronic devices such as transistors and semiconductors.
- Mechanical Strength: The alloy offers a combination of strength and toughness, ensuring durability in wear-resistant coatings and industrial components.
- Oxidation Resistance: MoZrTi thin films resist oxidation, which is critical for maintaining performance over long periods, particularly in high-temperature and oxidative environments.
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- High Dielectric Constant: NbTiO₃ has a high dielectric constant, making it ideal for capacitors and other electronic components requiring high energy density.
- Ferroelectric Properties: The ferroelectric nature of NbTiO₃ enables its use in memory devices and sensors that need stable, reliable performance under varying conditions.
- Optical Transparency: NbTiO₃ thin films provide excellent optical transparency, ensuring their application in optoelectronic devices and displays.
- Chemical and Thermal Stability: NbTiO₃ films are highly stable in both chemical and thermal environments, ensuring long-lasting performance in demanding applications.