Product Details
Place of Origin: CHINA
Brand Name: ZMSH
Certification: rohs
Model Number: Magnesium Single Crystal Substrate
Payment & Shipping Terms
Delivery Time: 2-4 weeks
Payment Terms: T/T
Materials: |
Magnesium Single Crystal |
Size: |
5×5,10×5,10×10,15×15,20×15,20×20 |
Thickness: |
0.5mm,1.0mm |
Purity: |
> 4N |
Density: |
D=1.738(g/cm3) |
Work Temperature: |
649 ℃ |
Crystal Orientation: |
<0001>;<11-20>;<10-10>;<1-102> |
Tolerance: |
±1° Or ±2° |
Polished: |
SSP Or DSP |
Surface Roughness: |
Ra<10nm(5×5μm) |
Application: |
Electronic Circuit Substrates |
Materials: |
Magnesium Single Crystal |
Size: |
5×5,10×5,10×10,15×15,20×15,20×20 |
Thickness: |
0.5mm,1.0mm |
Purity: |
> 4N |
Density: |
D=1.738(g/cm3) |
Work Temperature: |
649 ℃ |
Crystal Orientation: |
<0001>;<11-20>;<10-10>;<1-102> |
Tolerance: |
±1° Or ±2° |
Polished: |
SSP Or DSP |
Surface Roughness: |
Ra<10nm(5×5μm) |
Application: |
Electronic Circuit Substrates |
Magnesium (Mg) single crystal wafers, characterized by a hexagonal lattice structure, demonstrate a range of physical and chemical properties that make them valuable for specialized technological applications. These wafers are carefully oriented along specific crystallographic planes—<0001>, <11-20>, <10-10>, and <1-102>—which play a critical role in determining their performance in both research and industrial environments. One of the most notable features of these Mg wafers is their extremely low density, as magnesium is one of the lightest metals, offering significant advantages for weight-sensitive applications such as aerospace and advanced electronics.
The wafers also exhibit excellent thermal conductivity, making them highly suitable for applications that require rapid heat dissipation, such as power electronics and high-performance coatings. With a high purity level of 99.99%, these magnesium substrates ensure that there are minimal impurities, which is essential for applications like thin film deposition and epitaxial layer growth, where precise control over material properties is necessary.
The available sizes, including 5x5x0.5 mm, 10x10x1 mm, and 20x20x1 mm, provide flexibility to meet the needs of various experimental and industrial applications. In addition, the hexagonal crystal structure enhances the wafers’ mechanical strength and contributes to their unique electronic properties, making them an ideal substrate for semiconductor research, corrosion resistance studies, and other advanced material investigations. Their ability to combine high strength with low weight, coupled with their corrosion resistance, positions Mg wafers as a critical component in both cutting-edge research and practical applications.
Magnesium (Mg) single crystal wafers, with a hexagonal crystalline structure, exhibit several unique properties that make them suitable for advanced research and industrial applications. The crystallographic orientation of these wafers, such as <0001>, <11-20>, <10-10>, and <1-102>, significantly influences their physical and chemical properties. Mg wafers are highly appreciated for their lightweight nature, as magnesium is one of the lightest structural metals, which makes them advantageous for applications requiring reduced weight without compromising strength. Furthermore, the thermal conductivity of these wafers is excellent, allowing for efficient heat dissipation in electronics and thin-film applications.
The purity level of 99.99% ensures minimal impurities, providing a high degree of uniformity and stability in experimental conditions. This makes them ideal substrates for epitaxial growth, where precision and material integrity are paramount. The wafer dimensions, available in 5x5x0.5 mm, 10x10x0.5 mm, and 20x20x0.5 mm sizes, offer flexibility for various experimental setups. The hexagonal crystal structure is particularly beneficial in research fields such as surface physics, optoelectronics, and nanotechnology, as it supports unique electronic and optical properties.
Moreover, Mg wafers are highly resistant to corrosion, which enhances their durability in harsh environmental conditions, and their mechanical properties, such as high strength-to-weight ratio, make them suitable for lightweight structural applications. This combination of purity, crystallographic orientation, and material properties make magnesium single crystal wafers a versatile and valuable material for scientific exploration and industrial uses.
Magnesium (Mg) substrates, particularly single-crystal Mg wafers, have gained significant attention due to their unique combination of physical and chemical properties. These substrates play an essential role in various advanced research and industrial applications, offering benefits such as lightweight, excellent thermal conductivity, and specific crystallographic orientations. Here are some of the key applications of Mg substrates:
Mg substrates are widely used in semiconductor research, especially for the deposition of thin films and epitaxial layers. Their high purity and precise crystallographic orientations, such as <0001>, <11-20>, and <10-10>, allow for uniform thin-film growth, which is critical for producing high-performance semiconductor devices. These substrates are commonly utilized in microelectronics and photonic devices, where precise control over material properties is crucial for device functionality.
Mg substrates provide an excellent platform for testing and developing advanced coating materials. Due to magnesium’s natural tendency to corrode, Mg substrates are extensively used in corrosion studies. Researchers apply protective coatings to Mg substrates to test their durability, corrosion resistance, and adhesion properties. This is particularly relevant for industries like aerospace and automotive, where lightweight, corrosion-resistant materials are critical for long-term performance.
Mg substrates are ideal for research in nanotechnology and nanomaterials. Their well-defined crystal structure supports the growth of nanostructures like nanowires, nanotubes, and quantum dots. The high surface quality and crystalline orientation of Mg wafers make them an excellent choice for studies focused on nanoscale phenomena and material behavior. This is crucial in the development of new nanoscale devices and materials.
Thanks to their high thermal conductivity, Mg substrates are employed in thermal management applications, particularly in electronic devices that require efficient heat dissipation. Mg substrates can be used as the base for heat sinks in electronics such as CPUs and power transistors. This helps to prevent overheating and improves the efficiency and lifespan of the device by maintaining optimal operating temperatures.
Mg substrates are gaining attention in the biomedical field due to magnesium’s biocompatibility and biodegradability. Research into biodegradable implants uses Mg substrates to test the material’s behavior in biological environments. Magnesium-based implants are designed to gradually degrade and be absorbed by the body, reducing the need for surgical removal. This has potential applications in bone fixation devices and other temporary medical implants.
Mg substrates are also being explored for their application in lightweight structural materials. Magnesium’s high strength-to-weight ratio makes it a suitable candidate for industries like aerospace and automotive, where reducing weight while maintaining structural integrity is crucial. Mg substrates help researchers develop new alloys and composite materials that can replace heavier metals without sacrificing performance.
In conclusion, Mg substrates are versatile materials used in semiconductor research, nanotechnology, biomedical devices, and corrosion studies, offering solutions in fields that require precision, lightweight materials, and thermal management capabilities.
