12.2: Physical and Chemical

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Jamie MacArthur
Madera Community College

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Learning Objectives

Recognize examples of physical properties of a substance.
Recognize examples of physical changes a substance might undergo.

In this section we will more thoroughly distinguish between physical and chemical in terms of both properties and changes. We will explore those physical properties and changes in more detail in this chapter, and then we will look at the chemical properties and changes in the next chapter.

Physical Properties

A physical property is a characteristic of a substance that can be observed or measured without changing the identity of the substance. Silver is a shiny metal that conducts electricity very well. It can be molded into thin sheets—a property called malleability. Salt is dull, brittle, and conducts electricity when it has been dissolved into water (which it does quite easily). Physical properties of matter include color, hardness, malleability, solubility, electrical conductivity, density, melting point, and boiling point.

For the elements, color does not vary much from one element to the next. The vast majority of elements are colorless, silver, or gray. Some elements do have distinctive colors: sulfur and chlorine are yellow, copper is (of course) copper-colored, and elemental bromine is red.

Density can be a very useful parameter for identifying an element. Of the materials that exist as solids at room temperature, iodine has a very low density compared to zinc, chromium, and tin. Gold has a very high density, as does platinum.

Hardness is a measure of a material's ability to resist plastic deformation (i.e.- scratching or denting the material). Hardness helps determine how an element (especially a metal) might be used. Many elements are fairly soft (silver and gold, for example) while others (such as titanium, tungsten, and chromium) are much harder. Carbon is an interesting example of hardness. In graphite (the "lead" found in pencils) the carbon is very soft, while the carbon in a diamond is roughly seven times as hard.

photograph of a pencil — Figure \(\PageIndex{1}\): Pencil (Credit: Public Domain; Source: wikimedia; License: Public Domain)

photograph of a diamond ring — Figure \(\PageIndex{2}\): Diamond ring (Credit: User:Ikkyu2/Wikimedia Commons; Source:wikimedia; License: Public Domain)

Melting point and boiling point are somewhat unique identifiers, especially in the case of compounds. In addition to giving some idea as to the identity of the compound, important information can be obtained about the purity of the material.

Physical Change

As an ice cube melts, its shape changes as it acquires the ability to flow. However, its composition does not change. Melting is an example of a physical change. A physical change is a change to a sample of matter in which some properties of the material change, but the identity of the matter does not. Physical changes can further be classified as reversible or irreversible. The melted ice cube may be refrozen, so melting is a reversible physical change. Physical changes that involve a change of state are all reversible. Other changes of state include vaporization (liquid to gas), freezing (liquid to solid), and condensation (gas to liquid). Dissolving is also a reversible physical change. When salt is dissolved into water, the salt is said to have entered the aqueous state. The salt may be regained by boiling off the water, leaving the salt behind.

photograph of melting ice — Figure \(\PageIndex{2}\): Melting ice in the Beaufort Sea. (Credit: Courtesy of Rear Admiral Harley D. Nygren, NOAA; Source: wikimedia; License: Public Domain)

When a piece of wood is ground into sawdust, that change is irreversible since the sawdust cannot be reconstituted into the same piece of wood that it was before. Cutting grass or pulverizing a rock are examples of irreversible physical changes. Chopping wood for a fire also represents an irreversible physical change, since the pieces cannot be put back together to form the tree.

Physical Changes vs. Chemical Changes

What is the difference between physical and chemical changes? Watch the video to find out.

Section Summary

A physical property is a characteristic of a substance that can be observed or measured without changing the identity of the substance.
Physical properties include color, density, hardness, melting point, and boiling point.
A physical change is a change to a sample of matter in which some properties of the material change, but the identity of the matter does not.
A physical change can be reversible where the original form of the matter can be restored, or irreversible where the original form cannot be restored.
Melting ice and grinding wood into sawdust are examples of physical changes.
A chemical change produces different materials than the ones we started with.

Glossary

hardness: A measure of a material's ability to resist plastic deformation (i.e.- scratching or denting the material).

physical property: A characteristic of a substance that can be observed or measured without changing the identity of the substance.
physical change: A change to a sample of matter in which some properties of the material change, but the identity of the matter does not.

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