Titanium has the highest strength to weight ratio. And one of niobium’s best features is the ability to produce outstanding resistance to corrosion. The 6al 4v titanium device remains capable of providing compatibility in a wide range of applications scenarios. For example, it is utilized for the purposes of coating the metal on joint replacements within the infrastructure of aircrafts’ structural components.
Titanium alloys can be divided into three categories; namely alpha, beta and alpha-beta. Alpha alloys will never be heat treatable. They only contain neutral acting alloy elements. But they do have alpha stabilizers. Beta alloys contain enough beta stabilizers. These allow them to retain a beta phase during quenching. Solution treatments allow them to reach significant levels of strength. And the alpha-beta alloys are heat treatable.
They are made up of a combination of alpha and beta stabilizers. The use of niobium has significant benefits for relevant industries. For one thing, they offer the industrial space very good corrosion resistant capabilities. This usually occurs in concentrated acids and liquid alkaline metals. The niobium compound is also ductile. This results in less chipping in products and materials. High melting points and good heat resistance is possible as well.
Niobium and its related alloys are being applied to chemical processing technologies. These technologies go into the manufacture of electronics, specifically the manufacture of capacitors and superconductors within the nuclear technology industry. Niobium is also applied to the manufacture of metalized coinage and jewelry. This is due to the fact that electrochemically produced niobium oxide can generate what are known as Newton’s Rings.
And there you go. The briefest of features in regard to titanium and niobium products. And bare this in mind, the tip of the iceberg has yet to be reached.