Vanadium-palladium alloys

The corrosion behaviour of amorphous alloys has received particular attention since the extraordinarily high corrosion resistance of amorphous iron-chromium-metalloid alloys was reported. The majority of amorphous ferrous alloys contain large amounts of metalloids. The corrosion rate of amorphous iron-metalloid alloys decreases with the addition of most second metallic elements such as titanium, zirconium, vanadium, niobium, tantalum, chromium, molybdenum, tungsten, cobalt, nickel, copper, ruthenium, rhodium, palladium, iridium and platinum . The addition of chromium is particularly effective. For instance amorphous Fe-8Cr-13P-7C alloy passivates spontaneously even in 2 N HCl at ambient temperature ". (The number denoting the concentration of an alloy element in the amorphous alloy formulae is the atomic percent unless otherwise stated.)... 

As an example for the specific case of vanadium alloys with palladium, the trend of the average atomic volume of the alloys is shown in Fig. 4.20 and compared with the phase diagram. These data were obtained by Ellner (2004) who studied the solid solutions of several metals (Ti, V, Cr, Mn, Fe, Co and Ni) in palladium. The alloys were heat treated at 800°C and water-quenched. From the unit cell parameters measured by X-ray diffraction methods, the average atomic volume was obtained Vat = c 14 (see Table 4.3). These data together with those of the literature were reported in a graph, and the partial molar (atomic) value of the vanadium volume in Pd solid solution (Fv)... 

Figure 4.20. Palladium-vanadium system. In (a) the phase diagram is shown the phase sequence at 800°C is indicated. The corresponding trend of the average atomic volume is shown in (b). For pure vanadium the value of the partial atomic volume in Pd solution is indicated (Vv, as obtained by extrapolation from the Pd-rich alloys) and, as a reference, the elemental atomic volume (FatV) of the pure metal.

R.E. Buxbaum, R. Subramanian, J.H. Park, and D L. Smith, Hydrogen Transport and Embrittlement for Palladium Coated Vanadium-Chromium-Titanium Alloys, Journal of Nuclear Material, Part A, 233-237, 1996, pp.510-512. 

Buxbaum, R. E, Subramanian, R, Park, J. H, Smith, D. L. Hydrogen transport and embrittlement for palladium coated vanadium-chromium-titanium alloys. J Nucl Mater. 1996 233-237 510-2. 

The other approach to increase the electronic conductivity of these perovskite-based membranes is to add a metal phase (10-40 vol%). The metal phases studied include palladium, niobium, tantalum, vanadium and zirconium or their binary mixtures [69-72]. In order to nrmirtiize the stress at internal interfaces that can lead to the formation of dislocations and initiation of cracks, the ceramic support materials were chosen so as to be lattice matched to the metals and metal alloys [73]. 

In the patent by Hill, an aUoy of titanium containing 13 wt%vanadium, 11 wt% chromium and 3 wt% aluminum was developed as a hydrogen transport membrane material [12]. In this alloy, the crystal structure of titanium, which is normally hexagonal below 1153 K (880 °C), is stabilized in its high-temperature body centered cubic allotropic form. The body centered cubic crystal lattice is preferred for hydrogen transport. This titanium alloy was found to have hydrogen permeability superior to that of pure palladium in the range 300-450 °C (573-723 K)... 

The group of Nishimura has evaporated 100 nm thick films of palladium onto both sides of foils of vanadium alloyed with nickel, aluminum and molybdenum in an ultra-high vacuum system equipped for physical vapor deposition [62-66]. 

Alternatives to palladium in membranes for hydrogen separation nickel, niobium and vanadium alloys, ceramic supports for metal alloys and porous glass membranes... 

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