tio2 Sputtering Target Titanium Target Silver Titanium Disc Target Sputtering to Medical Applications
In medical applications, high-performance materials are required to meet strict demands for biocompatibility, corrosion resistance, and mechanical properties. Titanium and titanium alloys (such as Grade 2, Grade 5, and Grade 7), when combined with aluminum, form alloys that are widely used in sputtering targets for the deposition of high-purity thin films. These thin films have crucial roles in medical devices, implants, surgical tools, and other biomedical equipment.
Overview of Ti Gr2, Gr5, and Gr7 Titanium Alloys
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Grade 2 Titanium (Ti Gr2):
- Composition: Primarily titanium with small amounts of oxygen, iron, and carbon.
- Properties: Known for its excellent corrosion resistance, ductility, and biocompatibility. It is non-reactive and well-suited for use in body implants and surgical tools.
- Applications: Commonly used for medical implants, including dental implants and orthopedic devices.
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Grade 5 Titanium (Ti Gr5):
- Composition: Titanium alloyed with 6% aluminum and 4% vanadium (Ti-6Al-4V), which significantly improves its strength.
- Properties: Offers high strength-to-weight ratio, good fatigue resistance, and excellent corrosion resistance. Gr5 is ideal for applications requiring strength and durability.
- Applications: Frequently used in orthopedic implants, aerospace, and dental implants.
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Grade 7 Titanium (Ti Gr7):
- Composition: Titanium alloyed with palladium (around 0.12–0.25%), which enhances corrosion resistance, especially in aggressive environments.
- Properties: Improved resistance to chloride-induced stress corrosion cracking and better biocompatibility compared to other titanium grades. Ti Gr7 is often used in highly corrosive environments and in medical applications where the highest corrosion resistance is required.
- Applications: Used in medical implants, especially in environments where patients are exposed to saline solutions or harsh conditions.
| Technical Parameters | Description |
| Product Name | Titanium Disc |
| Material | Titanium Alloy |
| Shape | Round |
| Thickness | 35mm-550mm Or As Your Requirement |
| Diameter | 150mm-1300mm Or As Your Requirement |
| Color | Silver |
| Surface Treatment | Polished |
| Application | Industrial |
| Package | Plywood Case Or According to Your Requirement |
Titanium Aluminum Alloy Sputtering Targets in Medical Applications
The combination of titanium and aluminum in the form of alloy sputtering targets offers several advantages in the deposition of thin films, particularly for medical applications. These films are often used for coatings on medical devices such as implants, surgical instruments, and diagnostic tools.
Benefits of Titanium Aluminum Alloy Sputtering Targets
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Biocompatibility:
- Titanium and its alloys are highly biocompatible, meaning they do not cause significant irritation or rejection when used in the human body. The aluminum content further enhances this characteristic, especially when coated with thin films for implants.
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Corrosion Resistance:
- Titanium’s natural oxide layer provides excellent resistance to corrosion, especially in biological environments. Sputtered thin films of titanium or titanium-aluminum alloys improve this resistance, which is crucial for implants exposed to body fluids, salts, and other corrosive substances.
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Wear Resistance:
- Titanium aluminum alloy sputtering targets are used to deposit thin films with superior wear resistance. This is particularly beneficial for orthopedic implants, dental devices, and surgical instruments, which must endure friction and wear over time.
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Improved Strength:
- Alloying titanium with aluminum can improve the mechanical strength of the films, making them more durable under stress. This is essential in load-bearing implants, like joint replacements or spinal devices, where high strength is required.
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Lightweight and Durable:
- Titanium is naturally lightweight but incredibly strong, which is ideal for implant materials. Thin films produced from titanium-aluminum alloys contribute to maintaining the lightweight nature of the device while ensuring durability.
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Antimicrobial and Anti-Inflammatory Properties:
- Titanium coatings can be engineered to have antimicrobial properties, which reduce the risk of infection post-surgery. The deposition of high-purity titanium or titanium-aluminum alloy thin films can contribute to creating a biologically active surface that encourages osseointegration (the process of bone fusing to an implant).
Specific Medical Applications for Titanium Aluminum Alloy Coatings
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Orthopedic Implants:
- Titanium-aluminum alloys are used for hip and knee replacements, spinal implants, and bone screws due to their strength, lightness, and corrosion resistance. Sputtering these alloys onto implant surfaces creates thin, biocompatible coatings that can resist wear and corrosion over long periods of use.
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Dental Implants:
- Titanium dental implants are coated with thin films made from titanium-aluminum alloys to improve bone integration and reduce the risk of rejection. These coatings also enhance the durability of dental implants in challenging environments (e.g., exposure to saliva, acids, and occlusal forces).
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Surgical Tools:
- Surgical tools that are coated with titanium-aluminum alloy thin films benefit from enhanced wear resistance, corrosion resistance, and biocompatibility. Coatings on tools such as scalpels, forceps, and scissors help them maintain their performance and integrity over time, especially in sterilization cycles.
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Medical Device Coatings:
- Devices like stents, catheters, and vascular grafts can be coated with titanium-aluminum alloys to improve their biocompatibility and corrosion resistance in the body. Such coatings help the devices integrate better with body tissues and reduce the risk of complications or rejection.
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Prosthetic Devices:
- Titanium-aluminum alloy coatings are also applied to prosthetic limbs and joints to improve their durability and comfort. The alloy coating improves the strength, flexibility, and longevity of prosthetics, making them better suited for long-term use.
High-Purity Sputtering Targets for Medical Coatings
High-purity sputtering targets of titanium and titanium-aluminum alloys (such as Ti Gr2, Ti Gr5, and Ti Gr7) are essential for ensuring that the thin films deposited on medical devices meet stringent standards for purity, uniformity, and performance. In the medical industry, where the integrity of coatings is paramount for patient safety and device longevity, high-purity sputtering guarantees that the final coating will:
- Enhance biocompatibility by avoiding impurities that could cause rejection or irritation.
- Maintain mechanical properties such as strength and ductility to ensure the device functions properly under physiological conditions.
- Withstand long-term exposure to bodily fluids without degrading or compromising the device's integrity.
Titanium-aluminum alloy targets are specialized materials used in sputtering processes to deposit thin films with specific properties. These targets are made from a combination of titanium (Ti) and aluminum (Al), and they offer unique characteristics that make them valuable in various industrial applications.
Characteristics of Titanium Aluminum Alloy Targets:
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High Purity:
- Titanium-aluminum alloy targets are produced with high purity, typically 99.5% or higher. This high purity ensures that the thin films deposited during sputtering are free from impurities, providing excellent performance and uniformity in applications that require precise coatings.
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Fine Particle Size:
- The alloy targets are manufactured with a fine particle size, which enhances the efficiency of the sputtering process. Smaller particle sizes enable a more uniform deposition of the film on the substrate, improving the quality of the coating.
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Easy Sintering:
- Titanium-aluminum alloys exhibit good sintering properties, which means they can be easily processed into dense and solid forms. This is crucial for ensuring that the target is durable, reliable, and capable of withstanding the stresses of the sputtering process without degradation.
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Good Formability:
- Titanium-aluminum alloy targets are known for their excellent formability. This characteristic allows them to be manufactured into various shapes and sizes, ensuring compatibility with different sputtering systems and enhancing their versatility in a wide range of applications.
Applications of Titanium Aluminum Alloy Targets:
Titanium-aluminum alloy sputter targets are used in various industries due to their distinct properties, such as wear resistance, corrosion resistance, and the ability to form strong coatings. Some key applications include:
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Cutting Tools:
- Titanium-aluminum alloy coatings are commonly used in cutting tools, where they improve wear resistance, corrosion resistance, and thermal stability. These coatings extend the lifespan of tools like drills, end mills, and lathe tools, making them more efficient in high-speed machining.
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Cemented Carbide Drill Bits and Tools:
- Cemented carbide drill bits and tools benefit from the titanium-aluminum alloy coating as it significantly enhances the tool's performance in abrasive and high-temperature conditions. The coating also improves the tools' cutting ability and resilience when drilling or machining tough materials.
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Cemented Carbide Ceramic Tools:
- These coatings are applied to ceramic tools made from cemented carbide, enhancing their abrasion resistance, toughness, and strength. This is particularly useful in applications that require tools to handle extremely hard materials, such as in aerospace or automotive industries.
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Cemented Carbide Molds:
- Titanium-aluminum alloy coatings are also used in molds made from cemented carbide. These molds, used in the metal casting process, benefit from the enhanced wear resistance and corrosion resistance provided by the titanium-aluminum coatings, which contribute to longer service life and improved product quality.
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Powder Metallurgy Parts of Superhard Materials:
- Titanium-aluminum alloys are essential in producing superhard materials through powder metallurgy. The coatings improve the hardness, thermal stability, and corrosion resistance of the final products, making them suitable for applications in industries such as mining, drilling, and cutting tools.
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Metal Composite Ceramics:
- These alloys are often used as additives in the manufacturing of metal composite ceramics. The combination of metal and ceramic properties provides materials with enhanced strength, heat resistance, and electrical conductivity, making them suitable for demanding applications in electronics and mechanical systems.
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Additives for High-Temperature Resistant Alloys:
- Titanium-aluminum alloys serve as key additives in the production of high-temperature resistant alloys. These alloys are commonly used in applications such as jet engines, gas turbines, and heat exchangers, where thermal stability and strength are critical. The addition of titanium and aluminum improves the overall temperature resistance and structural integrity of the alloy.
Titanium in Medical Uses
Titanium, especially Grade 1 and Grade 2, is highly regarded in medical and biomedical fields for its biocompatibility, strength, and lightweight characteristics. It's commonly used in medical devices because it is not harmful to the body and is not likely to cause allergic reactions.
Key Medical Uses of Titanium:
- Orthopedic Implants: Titanium is commonly used in bone screws, plates, joint replacements, and spinal implants because it mimics the properties of bone.
- Dental Implants: Titanium's biocompatibility and strength make it a perfect choice for dental implants that require high durability and resistance to corrosion.
- Medical Instruments: Due to its corrosion resistance, surgical tools, needles, scalpels, and other medical instruments are often made from titanium or titanium alloys.
- Prosthetics: Titanium is used in the production of prosthetic limbs and implants for its combination of lightweight and strength.
- Cardiovascular Devices: Titanium is used in the production of pacemaker cases, stents, and valves due to its non-reactive nature in the human body.
- Wear-resistant coatings: Titanium sputtering targets can be used to deposit thin coatings on medical devices to enhance wear resistance, reduce friction, and improve biocompatibility.
Titanium Grades:
| Chemical requirements |
| | N | C | H | Fe | O | Al | V | Pd | Mo | Ni | Ti |
| Gr1 | 0.03 | 0.08 | 0.015 | 0.20 | 0.18 | / | / | / | / | / | bal |
| Gr2 | 0.03 | 0.08 | 0.015 | 0.30 | 0.25 | / | / | / | / | / | bal |
| Gr5 | 0.05 | 0.08 | 0.015 | 0.40 | 0.20 | 5.5~6.75 | 3.5~4.5 | / | / | / | bal |
| Gr7 | 0.03 | 0.08 | 0.015 | 0.30 | 0.25 | / | / | 0.12~0.25 | / | / | bal |
| Gr12 | 0.03 | 0.08 | 0.015 | 0.30 | 0.25 | / | / | / | 0.2~0.4 | 0.6~0.9 | bal
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Titanium is a highly versatile metal, and it is categorized into various grades based on its composition and properties. These grades are generally classified into three main categories: Commercially Pure (CP) Titanium, Titanium Alloys, and Specialty Titanium Alloys. Here’s an overview of the most common titanium grades:
1. Commercially Pure (CP) Titanium
Commercially Pure titanium is the most basic form of titanium with minimal alloying elements. It is typically used in applications requiring excellent corrosion resistance and biocompatibility, but it does not have the high strength of titanium alloys.
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Grade 1 (CP1):
- Composition: Minimum 99.5% titanium, with very small amounts of iron and oxygen.
- Properties: Grade 1 is the softest and most ductile of the commercially pure grades. It offers excellent corrosion resistance, especially in highly corrosive environments like seawater.
- Applications: Chemical processing, marine applications, medical implants, aerospace components.
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Grade 2 (CP2):
- Composition: Minimum 99.2% titanium.
- Properties: Grade 2 has slightly higher strength than Grade 1, while still retaining excellent corrosion resistance. It is the most widely used commercially pure titanium grade.
- Applications: Heat exchangers, aerospace, medical devices (implants, surgical instruments), and marine applications.
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Grade 3 (CP3):
- Composition: Minimum 99% titanium.
- Properties: Offers higher strength than Grade 2 but with slightly reduced formability.
- Applications: Chemical processing, marine, power generation, and medical applications.
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Grade 4 (CP4):
- Composition: Minimum 98.5% titanium.
- Properties: The strongest of the commercially pure grades, offering excellent strength-to-weight ratio. It has a slightly lower corrosion resistance compared to Grade 2 but is still excellent for most industrial and medical uses.
- Applications: Aerospace, chemical industry, marine, medical implants, automotive components.
2. Titanium Alloys
Titanium alloys are generally stronger than commercially pure titanium and have enhanced properties, such as improved strength, better fatigue resistance, and sometimes superior corrosion resistance. These alloys are typically categorized by the elements alloyed with titanium, such as aluminum, vanadium, molybdenum, iron, or zirconium.
Alpha Alloys
These titanium alloys are primarily alloyed with aluminum and offer excellent strength and corrosion resistance at high temperatures. They have a high alpha phase content.
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Grade 5 (Ti-6Al-4V):
- Composition: 90% titanium, 6% aluminum, 4% vanadium.
- Properties: One of the most widely used titanium alloys, Grade 5 offers an excellent balance of strength, light weight, and corrosion resistance. It is also heat-treatable to further enhance its mechanical properties.
- Applications: Aerospace (aircraft, rockets), medical implants (orthopedic and dental), marine, power generation, and sports equipment.
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Grade 6 (Ti-5Al-2.5Sn):
- Composition: 5% aluminum, 2.5% tin, and the balance titanium.
- Properties: Offers better weldability than Grade 5 and is used for high-temperature applications where some corrosion resistance is still required.
- Applications: Aerospace components, high-temperature applications, gas turbine engines.
Beta Alloys
Beta alloys have higher amounts of beta-phase stabilizers (such as vanadium, molybdenum, or chromium), which improve their strength, formability, and resistance to high-temperature oxidation. They are generally used in applications requiring high strength.
Alpha-Beta Alloys
These alloys are a mix of both alpha and beta phases and offer a balance of strength, formability, and corrosion resistance. The alpha-beta alloys are the most commonly used titanium alloys in structural and high-performance applications.
- Grade 23 (Ti-6Al-4V ELI):
- Composition: 6% aluminum, 4% vanadium, with extra low interstitial elements such as carbon, oxygen, and nitrogen.
- Properties: This is the extra low interstitial (ELI) version of Grade 5. It offers improved biocompatibility, making it particularly useful for medical implants. Grade 23 is known for its excellent strength-to-weight ratio and superior fatigue resistance.
- Applications: Orthopedic implants, aerospace, dental implants, and sports equipment.
3. Specialty Titanium Alloys
These alloys are specifically developed for niche applications that require very specific properties.
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Grade 7 (Ti-0.15Pd):
- Composition: Titanium with 0.12-0.25% palladium.
- Properties: Known for its superior corrosion resistance in highly acidic environments, especially in chloride-containing environments. It’s also more biocompatible than other alloys, making it suitable for medical applications.
- Applications: Medical devices, aerospace, chemical processing, and marine applications.
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Grade 11 (Ti-0.3Pd):
- Composition: 0.3% palladium, and the balance titanium.
- Properties: Similar to Grade 7, with slightly higher palladium content for enhanced corrosion resistance. It is typically used in more demanding environments.
- Applications: Aerospace, chemical processing, and marine environments.
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Grade 13 (Ti-0.3Ni):
- Composition: 0.3% nickel and titanium.
- Properties: Offers good corrosion resistance and is used in applications that require high strength and excellent performance in certain chemical environments.
- Applications: Marine applications, chemical processing.
| Tensile requirements |
| Grade | Tensile srength(min) | Yeild strength(mm) | Elongation(%) |
| | KSI | MPa | Ksi | MPa | |
| 1 | 35 | 240 | 20 | 138 | 24 |
| 2 | 50 | 345 | 40 | 275 | 20 |
| 5 | 130 | 895 | 120 | 828 | 10 |
| 7 | 50 | 345 | 40 | 275 | 20 |
| 12 | 70 | 438 | 50 | 345 | 18
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Conclusion:
Titanium alloy sputtering targets, including TiAl alloys, are versatile materials widely used for coating applications in industries ranging from aerospace to electronics and biomedical. These materials provide exceptional properties such as strength, corrosion resistance, biocompatibility, and wear resistance, making them ideal for demanding applications that require durable, high-performance thin films. When choosing a titanium sputtering target, factors like alloy composition, purity, and target geometry must be considered to achieve optimal results in the sputtering process.
