Any metal whether ferrous, iron or steel, or non-ferrous aluminium, copper, brass, etc. has a base characteristic that is more or less predetermined by the way the atoms and molecules in the metal structure are arranged and how they are bonded together. If you alter one, say hardness, as this increases by whatever means, usually by heat or mechanical working, the ductility will decrease as a result. Ductility, along with malleability, is the property that allows the metal to be worked without breaking. Avoiding getting too bogged down in structures at atomic level, it is the metallic bond that allows the free valence electrons to be shared between atoms; this allows the metal particles to slide over one another, rather than to snap apart as in other bond structures.

The iron–carbon phase diagram gives a graphic illustration as to what, in simple terms, is happening to the crystal structure within the steel at certain temperatures and varying amounts of carbon. It shows that steel with 0.76 per cent carbon has the lowest critical temperature at which all the ferrite and cementite has converted to austenite; this is known as eutectoid steel, the critical temperature is 724°C, and at this point the steel will have become non-magnetic. It also illustrates that as the carbon percentage increases, and to some extent as the carbon percentage decreases, a higher temperature will be needed to reach the critical temperature at which the maximum amount of all the various crystal structures convert to austenite. Of course, if the heated steel with its austenite was left to cool slowly, as the critical temperature was passed, the austenite would transform into ferrite and cementite once again, leaving the steel in an annealed condition. Quench the steel above the critical temperature and the austenite will transform into its hard form of martensite, leaving the steel glass hard.

The hardenability is primarily down to alloying element carbon, but there are many other alloying elements that are added to steels and each or a combination of these various elements is what alters some of the other characteristics of the steel. For example, silver steel, which is a water-hardening steel normally designated as W1 steel, contains 1 per cent carbon, 0.4 per cent chromium, 0.35 per cent manganese and 0.3 per cent silicon. The chromium and manganese impart extra toughness and wear resistance than would otherwise be obtained with a plain carbon alloy. The silicon, although less effective than the manganese, helps the hardness. High percentages of silicon will have a detrimental effect on the surface finish, although in steels destined for the manufacture of transformers and motor armatures the inclusion of silicon helps the metal electrically.