Alloy Geek Alloy CMSX-2 Standard

Your Analysis Type: X-Ray Fluorescence (XRF)
Pedigree: Certified Reference Material (includes certified chemical analysis)
Sale price$250.00


Alloy Geek CMSX-2 Standard

Alloy CMSX-2, a member of the renowned superalloy family, stands as a pinnacle of high-temperature material engineering. Engineered to thrive in the most extreme conditions, this alloy boasts a unique chemical composition and a remarkable set of properties that set it apart in the world of high-performance alloys.

Chemical Composition of CMSX-2:

  • Nickel (Ni): Approximately 50.0%
  • Cobalt (Co): Approximately 6.0%
  • Chromium (Cr): Approximately 10.0%
  • Tungsten (W): Approximately 6.0%
  • Aluminum (Al): Approximately 4.0%
  • Titanium (Ti): Approximately 3.0%
  • Rhenium (Re): Approximately 3.0%
  • Other Elements: Traces of other elements, such as tantalum and hafnium, may be present.

Key Properties:

  1. High-Temperature Strength: CMSX-2 exhibits exceptional strength and stability at elevated temperatures, making it suitable for demanding applications in the aerospace and gas turbine industries.

  2. Oxidation Resistance: This alloy showcases excellent resistance to oxidation at extreme temperatures, ensuring long-term durability even in harsh operating conditions.

  3. Creep Resistance: CMSX-2 offers remarkable resistance to creep deformation, maintaining its structural integrity under prolonged stress.

  4. Corrosion Resistance: It possesses good corrosion resistance, adding to its reliability in aggressive environments.

  5. Excellent Casting Characteristics: CMSX-2 is well-suited for investment casting, allowing for intricate and precise component manufacturing.

Other Names:

  • CMSX-2 is also known by its trade names such as CMSX-2® and CMSX2®.

Unique Features: Alloy CMSX-2 is a member of the CMSX family, known for its outstanding high-temperature performance and resistance to creep and oxidation. What sets CMSX-2 apart from CMSX-3 is primarily its chemical composition. CMSX-2 contains higher levels of tungsten and chromium compared to CMSX-3, which contributes to its superior strength and stability at extreme temperatures. This alloy is favored for applications where the combination of strength and resistance to environmental factors is crucial. While CMSX-3 shares many desirable characteristics, CMSX-2's specific composition makes it uniquely suited for specialized applications where elevated temperature performance is paramount.

XRF Samples are thinner samples approximately 1/4 inch thick. OES Standards are thicker in nature and are approximately 1 inch thick. Please Contact Us if you would like to know the specific dimensions of a sample.

Reference Material (RM): A reference material, or RM, is a material with a known composition or property that is used for informational purposes to look at analytical instruments, methods, or procedures. It serves as a point of comparison to ensure the accuracy and reliability of measurements. Reference materials can vary in terms of their level of characterization and traceability. Some reference materials may have well-defined properties, but they might not have undergone the rigorous testing and certification process that certified reference materials (CRMs) undergo. Reference Material chemical compositions are for information purposes.

Certified Reference Material (CRM): A certified reference material, or CRM, is a type of reference material that has been thoroughly analyzed and characterized using multiple validated methods to determine its composition or properties. The results of these analyses are then used to establish certified values, along with associated uncertainties. CRMs are produced and certified by accredited organizations or laboratories following internationally recognized standards, such as ISO Guide 34 and ISO/IEC 17025. The certification process includes interlaboratory comparison and statistical analysis to ensure accuracy and traceability.

In summary, the main difference between a reference material and a certified reference material lies in the level of characterization, validation, and certification. CRMs have undergone a more comprehensive and rigorous testing process, resulting in certified values and uncertainties that can be confidently used for instrument calibration, quality control, and research. Reference materials, on the other hand, can provide a point of comparison but might not have the same level of certification and traceability as CRMs. When accuracy and traceability are critical, certified reference materials are preferred.

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