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In situ investigation of phase formation during low energy ion nitriding of Ni80Cr20 alloy

The formation of expanded austenite after nitrogen insertion into austenitic stainless steel, CoCr or Ni base alloys is characterised by an unusually high nitrogen content in solid solution representing a diffusion layer. However, the process is still not completely understood. Using in situ X-ray d...

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Published in:Surface & coatings technology 2014-11, Vol.259, p.434-441
Main Authors: Manova, D., Hirsch, D., Gerlach, J.W., Mändl, S., Neumann, H., Rauschenbach, B.
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Language:English
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cited_by cdi_FETCH-LOGICAL-c375t-94776bdb7d2cc5cd9410a2f9692054eb82bd14fdda4f8b298689b4af742d79203
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container_title Surface & coatings technology
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creator Manova, D.
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description The formation of expanded austenite after nitrogen insertion into austenitic stainless steel, CoCr or Ni base alloys is characterised by an unusually high nitrogen content in solid solution representing a diffusion layer. However, the process is still not completely understood. Using in situ X-ray diffraction (XRD) experiments and additional data from SEM, the phase formation and diffusion after low energy nitrogen ion implantation into commercial Ni80Cr20 (Nichrome) are investigated in the temperature range from 350 to 500°C. A compound layer consisting of a phase similar to fct Ni4N is formed on the surface, most likely with a composition of (Ni,Cr)4N, followed by a diffusion zone extending about 1μm into the material. For increasing temperature, the total nitrogen uptake is decreasing. The time evolution shows that a saturation is reached earlier for higher temperatures whereas no saturation has been found for 375°C and 90min. A competition exists between nitrogen loss at the surface and nitrogen supply by the ion beam. This loss process is thermally activated and depends on the surface orientation. Additionally, at 500°C some CrN precipitates are found. •Formation of compound and diffusion layer during nitriding of Ni80Cr20•Formation of textured fct (Ni,Cr)4N•High temperature decay of expanded austenite in diffusion layer into CrN•Gradual loss of nitrogen when increasing process temperature from 350 to 500°C
doi_str_mv 10.1016/j.surfcoat.2014.10.054
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subjects Applied sciences
Cross-disciplinary physics: materials science
rheology
Diffusion
Diffusion layers
Exact sciences and technology
Expanded austenite
Formations
In situ XRD
Insertion
Ion nitriding
Low energy
Low energy ion implantation
Materials science
Metals. Metallurgy
Ni80Cr20 alloy
Nickel base alloys
Other surface treatments
Phase formation
Physics
Production techniques
Saturation
Surface chemistry
Surface treatment
Surface treatments
title In situ investigation of phase formation during low energy ion nitriding of Ni80Cr20 alloy
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