Abstract
The unclear miscibility of CuNi alloys was investigated with atom probe tomography (APT). Multilayered thin film samples were prepared by ion beam sputtering (IBS) and focused ion beam (FIB) shaping. Long-term isothermal annealing treatments in a UHV furnace were conducted at temperatures of 573, 623, and 673 K to investigate the mixing process. The effective interdiffusion coefficient of the nanocrystalline microstructure (including defect diffusion) was determined to be Deff = 1.86 × 10−10 m2/s × exp(−164 kJ/mol/RT) by fitting periodic composition profiles through a Fourier series. In nonequilibrium states, microstructural defects like grain boundaries and precipitates were observed. While at the two higher temperatures total mixing is observed, a clear experimental evidence is found for a miscibility gap at 573 K with the boundary concentrations of 26 and 66 at%. These two compositions are used in a subregular solution model to reconstruct the phase miscibility gap. So, the critical temperature TC of the miscibility gap is found to be 608 K at a concentration of 45 at% Ni.
Highlights
CuNi alloys are well-known materials in industry and well investigated
The unclear miscibility of CuNi alloys was investigated with atom probe tomography (APT)
Multilayered thin film samples were prepared by ion beam sputtering (IBS) and focused ion beam (FIB) shaping
Summary
CuNi alloys are well-known materials in industry and well investigated Because of their high corrosion resistance, low macrofouling rates, and good fabricability, they are a good candidate for marine applications like naval condensers and piping. Their ductility at low temperatures makes them interesting for components in cryogenic processing and storage compounds (CDA, 2020). Some attempts were made to clarify this issue by indirect experimental measurements and by computational methods which all support the phase separation tendency and the existence of a miscibility gap (Vrijen & Radelaar, 1978; Tomiska & Neckel, 1984; Srikanth & Jacob, 1989; Asta & Foiles, 1996). The main difficulties are achieving thermodynamic equilibrium in reasonable times and using high-resolution composition sensitive measurements
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