Specific Process Knowledge/Thin film deposition/Deposition of Tungsten Nitride: Difference between revisions
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Tungsten nitride (WNₓ, commonly W₂N or δ‑WN) is a refractory ceramic that combines very high melting temperature, extreme hardness, chemical inertness, and good electrical conductivity in a composition‑tunable, CMOS‑compatible matrix. | Tungsten nitride (WNₓ, commonly W₂N or δ‑WN) is a refractory ceramic that combines very high melting temperature, extreme hardness, chemical inertness, and good electrical conductivity in a composition‑tunable, CMOS‑compatible matrix. | ||
Thin films are produced chiefly by reactive magnetron | Thin films are produced chiefly by reactive magnetron sputtering, where nitrogen flow and substrate temperature set stoichiometry and phase, yielding dense layers with controllable resistivity and stress. | ||
In semiconductor process flows, WNₓ acts as a robust Cu diffusion barrier/liner, hard mask, gate or contact material, and precision thin‑film resistor; its high absorption coefficient also makes it the standard absorber layer in EUV lithography photomasks and a candidate for x‑ray mask blanks. | In semiconductor process flows, WNₓ acts as a robust Cu diffusion barrier/liner, hard mask, gate or contact material, and precision thin‑film resistor; its high absorption coefficient also makes it the standard absorber layer in EUV lithography photomasks and a candidate for x‑ray mask blanks. | ||
Optically, WN-based stacks offer durable, high-temperature plasmonic and thermally emissive coatings, mid-IR absorbers, and multilayer structures for soft-x-ray mirrors and synchrotron beamline optics, delivering stability far beyond noble metals under extreme photon flux. | Optically, WN-based stacks offer durable, high-temperature plasmonic and thermally emissive coatings, mid-IR absorbers, and multilayer structures for soft-x-ray mirrors and synchrotron beamline optics, delivering stability far beyond noble metals under extreme photon flux. | ||
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* [[Specific Process Knowledge/Thin film deposition/Deposition of Tungsten Nitride/WN Reactive Sputtering in Cluster Lesker PC3|Deposition of Tungsten Nitride (WN) using reactive sputtering]] in Sputter-System Metal-Nitride(PC3) Source 2 (3-inch target) | * [[Specific Process Knowledge/Thin film deposition/Deposition of Tungsten Nitride/WN Reactive Sputtering in Cluster Lesker PC3|Deposition of Tungsten Nitride (WN) using reactive sputtering]] in Sputter-System Metal-Nitride(PC3) Source 2 (3-inch target) | ||
At the moment (July 2025) we have a 3-inch W target (0.125" thick, bonded to Cu) for PC3 or PC1. | At the moment (July 2025) we have a 3-inch W target (0.125" thick, bonded to Cu) for PC3 or PC1. | ||
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Tungsten Nitride (WNx)
Tungsten nitride (WNₓ, commonly W₂N or δ‑WN) is a refractory ceramic that combines very high melting temperature, extreme hardness, chemical inertness, and good electrical conductivity in a composition‑tunable, CMOS‑compatible matrix. Thin films are produced chiefly by reactive magnetron sputtering, where nitrogen flow and substrate temperature set stoichiometry and phase, yielding dense layers with controllable resistivity and stress. In semiconductor process flows, WNₓ acts as a robust Cu diffusion barrier/liner, hard mask, gate or contact material, and precision thin‑film resistor; its high absorption coefficient also makes it the standard absorber layer in EUV lithography photomasks and a candidate for x‑ray mask blanks. Optically, WN-based stacks offer durable, high-temperature plasmonic and thermally emissive coatings, mid-IR absorbers, and multilayer structures for soft-x-ray mirrors and synchrotron beamline optics, delivering stability far beyond noble metals under extreme photon flux. Beyond electronics and photonics, the material’s wear and oxidation resistance support MEMS springs, high‑temperature sensors, and corrosion‑resistant coatings, while select WN phases become superconducting below roughly 3–5 K, enabling niche low‑loss microwave resonators and detector elements that benefit from its mechanical robustness and diffusion‑barrier capability.
Deposition of Tungsten Nitride
Deposition of WNx can only be done by reactive sputtering using W target.
The tool of choice for this application is the Cluster-based multi-chamber high vacuum sputtering deposition system, commonly referred to as the "Cluster Lesker." The operating process is described in detail.:
- Deposition of Tungsten Nitride (WN) using reactive sputtering in Sputter-System Metal-Nitride(PC3) Source 2 (3-inch target)
At the moment (July 2025) we have a 3-inch W target (0.125" thick, bonded to Cu) for PC3 or PC1.
Comparison of sputter systems for reactive deposition
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