Ion irradiation induced precipitation of γ phase in Cu–Zn–Al–Ni

The structure of a Cu-13.67Al-4.28Ni-0.54Mn-0.14Fe (wt.%) shape memory alloy was analyzed in the initial condition, during a heating-cooling cycle, and during a room temperature loading-unloading mechanical cycle. A fully reversible martensitic transformation was revealed which was associated with a

x-phase particles are precipitated when Ti is added as grain refiner to Cu-Al-Ni shape memory alloys. The size distribution of these precipitates is a function of the thermomechanical history of the alloy. The further addition of Mn to improve the alloy properties causes the appearance of a new set

The structure and microstructure of precipitates obtained by quenching p Cu-Zn-Al alloys have been analysed by electron diffraction and high resolution electron microscopy. Electron diffraction patterns show a spot configuration very close to that of y-brass. However, the superlattice spots are not

Ion beam-induced interdi †usion and phase formation processes in thin Cu-Al and Ag-Al multilayers were investigated with in situ RBS and X-ray di †raction (XRD), respectively. The metal layers were deposited by evaporation on polished glassy carbon and single-crystal silicon substrates. In order to