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Nickel Powders from the Carbonyl Process

Nickel Powders from the Carbonyl Process

Metal powder is the base materials for the production of metallic component through

the conventional powder metallurgy route or the emerging field of additive manufacturing. In any of these process routes, the properties of

the finished product depends on the character of the base powder from which it is produced which is equally dependent on the process of production of the

base powder. Therefore, there are different methods for producing metal powders with each method offering different particle morphology and purity.

These methods include crushing (for brittle material), machining, mechanical pulverization, slotting, electrolysis, atomization of liquid metal

using water, nitrogen, argon, or a combination of these, and reduction of metal oxides in hydrogen or using carbon. These metal oxides could

be materials such as iron ore or iron oxide generated from pickling plants, in steel strip mills. Other methods include reduction of

metal oxide with higher carbon containing, metal powder, chemical decomposition of metal carbonyls, and electrolytic processing of cathodic

deposition from molten metal salts; and in some instances, recycling (Sharma, 2011). Each of these methods provides different particle morphology and

characteristics. An illustration of typical powder shapes produced from some of these processes is shown in Figures 1 and 2.

New materials that can be tailored for individual applications are in constant demand. As the range of uses for powder metallurgy, hard metals and

electronic materials expands, customer requirements are causing materials companies to come up with new products that have the necessary properties. Nickel

can bring a number of benefits to these and other industries. It can improve the mechanical and fatigue properties of alloy steels, enhance conductivity and

magnetic properties of electronic materials, act as a binder for holding together particulate materials and be used in filtration components in the form of

high porosity products. These applications rely on high purity fine nickel powders and other special nickel forms being adapted to meet specific materials

needs, for which a versatile production and processing technology is needed. The nickel carbonyl gas process fulfils these needs.