Chemistry: The States of Matter - dummies

Chemistry: The States of Matter

Look around you. All the stuff you see — your chair, the water you’re drinking — is matter. Matter is the material part of the universe. It’s anything that has mass and occupies space. Matter can exist in one of three states: solid, liquid, and gas.


At the macroscopic level, the level at which you directly observe with your senses, a solid has a definite shape and occupies a definite volume. Think of an ice cube in a glass — it’s a solid. You can easily weigh the ice cube and measure its volume. At the microscopic level (where items are so small that people can’t directly observe them), the particles that make up the ice are very close together and aren’t moving around very much (see Figure 1-a).

The reason the particles that make up the ice (also known as water molecules) are close together and have little movement is because, in many solids, the particles are pulled into a rigid, organized structure of repeating patterns called a crystal lattice. The particles that are contained in the crystal lattice are still moving, but barely — it’s more of a slight vibration. Depending on the particles, this crystal lattice may be of different shapes.

Figure 1: Solid, liquid, and gaseous states of matter.


When an ice cube melts, it becomes a liquid. Unlike solids, liquids have no definite shape, but they do have a definite volume, just like solids do. For example, a cup of water in a tall skinny glass has a different shape than a cup of water in a pie pan, but in both cases, the volume of water is the same — one cup. Why? The particles in liquids are much farther apart than the particles in solids, and they’re also moving around much more (see Figure 1-b.). Even though the particles are farther apart in liquids than in solids, some particles in liquids may still be near each other, clumped together in small groups. Because the particles are farther apart in liquids, the attractive forces among them aren’t as strong as they are in solids — which is why liquids don’t have a definite shape. However, these attractive forces are strong enough to keep the substance confined in one large mass — a liquid — instead of going all over the place.


If you heat water, you can convert it to steam, the gaseous form of water. A gas has no definite shape and no definite volume. In a gas, particles are much farther apart than they are in solids or liquids (see Figure 1-c), and they’re moving relatively independent of each other. Because of the distance between the particles and the independent motion of each of them, the gas expands to fill the area that contains it (and thus it has no definite shape).