NK13181 Nickel Iron Copper Molybdenum Alloy Foil (Ni77/Fe14/Cu5/Mo4)

Nickel Iron Copper Molybdenum Alloy Foil (Ni77/Fe14/Cu5/Mo4) Description

Nickel Iron Copper Molybdenum Alloy Foil (Ni77/Fe14/Cu5/Mo4) is produced by combining approximately 77% Nickel, 14% Iron, 5% Copper, and 4% Molybdenum into a thin metallic foil. This specific formulation is verified through spectroscopic analysis and microscopy to ensure that the alloy's microstructure provides a uniform surface and controlled mechanical properties. The measured alloy composition makes the foil suitable for industrial and research applications that require stable electrical and structural performance.

Nickel Iron Copper Molybdenum Alloy Foil (Ni77/Fe14/Cu5/Mo4) Characteristics

*The above product information is based on theoretical data and is for reference only. Actual specifications may vary.

Nickel Iron Copper Molybdenum Alloy Foil (Ni77/Fe14/Cu5/Mo4) Applications

Industrial Applications
- Used as a component in high-temperature processing equipment to achieve uniform heat distribution by leveraging its controlled alloy composition.

Electronics
- Used as an interconnect foil in circuit assemblies to achieve minimised resistance by leveraging its stable elemental dispersion.

Automotive
- Used as a current collector in battery modules to achieve efficient charge distribution by leveraging its nickel-enriched formulation.

Nickel Iron Copper Molybdenum Alloy Foil (Ni77/Fe14/Cu5/Mo4) Packing

The foil is packaged in anti-static, moisture-resistant pouches and encased within rigid, cushioned containers to prevent mechanical damage and contamination. It is recommended to store the packaged material in a temperature- and humidity-controlled environment. Packaging options can be customised to include labelling, compartmentalisation, and additional protective cushioning as required.

Additional Information

Nickel-based alloys are widely studied for their ability to maintain stability under thermal variation and mechanical stress. Research in metallurgical processes focuses on optimising alloying elements to achieve a microstructure that supports both mechanical and electrical performance in industrial components.

Advances in spectroscopic and microscopic characterisation have improved the understanding of phase behaviour in metallic systems. This scientific approach helps in fine-tuning processing parameters and ultimately enhances the predictability of performance in applications ranging from electronic interconnects to high-temperature industrial components.