Alloy Materials Exploration PDF

Summary

This document explores alloys, which are materials composed of a metallic base and additional metal or non-metal components. It discusses the different types of alloys and how they are created. The text focuses on the properties and adjustments of alloys, highlighting the role of both metal and non-metal additions in altering characteristics.

Full Transcript

What Is an Alloy?

An alloy is a material composed of a metallic base, usually the
large majority component, and additional metal or non-metal
components that are added as property modifiers. Alloys are manufactured
and carefully tuned by experiment to deliver desirable properties that are
not present in the primary material.

Many alloys are made purely of metals, but non-metal additions such as
Silicon, Sulfur, Carbon, Nitrogen, and other light elements are commonly
used as property adjusters.

What Are Alloys Made Of?

Alloys are merged materials composed of a primary base element
combined with various secondary elements. The base element provides the
fundamental structure and typically the solubility medium that disperses the
other components uniformly, while the secondary elements are added in
specific proportions to adjust and bequeath desirable properties of the final
material. The resulting alloy inherits a summary of the characteristics of all
its constituents and in many cases, unexpected cooperative gains that none
of the individual constituents display, leading to selectively improved
performance.

How Are Alloys Made?

Alloys are made by smelting and blending the base metal and additional
elements (metals and/or non-metals) and allowing them to cool. The
admixing is often performed in the melt, but many non-metallic additives
can be worked in after initial solidification, by various methods. Two primary
types of alloys are used; substitutional and interstitial alloys.
In substitutional alloys, like brass and bronze, the atoms of all of the alloying
elements are similar in size. The atoms of the alloying elements substitute
for the same sites the atoms of the base material would occupy in its lattice
structure. This lends distributed property adjustments to the lattice that are
intrinsic to the metals involved. In most cases the substitution disrupts and
stresses the lattice, reducing planar slip potential by blocking.

In interstitial alloys such as steel, the atoms of the alloying elements
(Carbon, Silicon, Nitrogen) are smaller and fit in between the atoms of the
base metal. This placement also acts to disrupt slippage and fracture.
However, some non-metallic elements such as Silicon act as crystal growth
triggers, altering the typical crystal size to add strength and resilience as
more and smaller crystals deliver a tougher material.