Attraction between Particles of Matter: An Introduction
Matters are composed of discrete particles, which could be distinct atoms or molecules. The particles of matter attract each other, this property is known as cohesion and is the reason for the elasticity of the material. The attraction between particles varies in different matters. This attractive force is highest in solids, followed by liquid and gas.
Examples of Forces between Particles
Few examples can demonstrate the existence of the force of attraction between particles and the degree of attractive force between the particles of matter.
If you try to bend iron with your bare hand it will be impossible, however, you can easily break a piece of chalk or pencil. This is because the attraction between iron molecules is much greater than that of chalk pieces.
The elasticity of a rubber band can also be attributed to the cohesive property of the material. When you stretch a rubber band, the external force applied overcomes the attractive force between the molecules, as long as this pull is maintained the band remains stretched, but, once the external force is removed, the intermolecular force of attraction acts to put the rubber band back to its original shape. If the band is pulled beyond a certain limit (breaking point), it can cause permanent rupture and tear the rubber band.
If you move your hand through the water, you will experience resistance, but you can move your hand through air relatively easily. The force of attraction between water molecules is much more than that in air. The particles in liquids are somewhat more compressible than the particles in gases.
The surface tension of water is a property that arises due to the attractive force between the molecules of water. The tension is the result of an attractive force that acts on a water molecule on the surface. The water molecules at the surface experience a pull inward and tangentially on the surface. The tangential force on the molecule on the surface is the surface tension, it makes the surface behave like an elastic membrane.
Types of Molecular Interaction
But, why do particles of matter attract each other? There exists a weak force attraction between two molecules of a substance. This force of attraction is called the intermolecular force of attraction. It gives the substance its unique physical properties. The force of attraction between particles of matter can arise due to a number of interactions such as:
Dipole-dipole interaction
Dipole-induced dipole interaction
Ion-dipole interaction
Ion-induced dipole interaction
Dispersion forces
Hydrogen bonding
Intermolecular Forces
The intermolecular forces due to Dipole-dipole interaction, dipole-induced dipole interaction and dispersion forces are often called Van der Waal forces. It arises due to electrical interaction between two molecules.
The electron cloud around a molecule continuously fluctuates causing temporary polarisation of charges. As the electron cloud shifts from one side to another, the charge difference results in the formation of dipoles. These temporary dipoles of one molecule interact with another molecule close by to give rise to attractive forces.
Polar molecules having permanent dipoles have dipole-dipole interaction. Uncharged molecules develop transient dipoles due to the spontaneous motion of electron clouds; when an instantaneous dipole gets closer to another molecule it induces a charge separation in that molecule and gives rise to an induced dipole. This is Dipole-induced dipole interaction. The poles of the dipoles fluctuate in synchrony to maintain the interaction. The induced dipole moment can influence other molecules, which can influence others, this way the induced dipole can disperse across a large network molecule in a system. This is known as dispersion forces.
Molecules composed of ions can similarly have ion-dipole interaction and ion-induced dipole interaction. An ion that has a distinct charge can interact with polar molecules to give rise to ion-dipole interaction, for example when sodium chloride dissolves in water, the sodium cation or chloride anion is surrounded by the polar water molecules, this is called hydration of ions and leads to the dissolution of sodium chloride crystals.
Ions can also induce permanent dipoles in a nonpolar molecule by perturbing its electron cloud. This results in ion-induced dipole interaction.
Hydrogen Bonding and Van der Waal Forces
When a partially positively charged hydrogen is attracted by another partially negatively charged atom it results in hydrogen bonding. An extensive hydrogen bonding exists in water that gives it its unique property.
The extent of van der Waal forces, hydrogen bonding and other interactions determine the physical property of a substance such as the boiling point and the melting point. Substances with higher van der Waal forces, and hydrogen bonding will have a higher boiling point. More heat will be required to break the interactions between the molecules or the hydrogen bonds and disrupt the order to bring about a change in state.
The magnitude of attraction between the particles of matter is a significant determinant of the chemistry of the substance.
Key Feature
Matters are composed of discrete particles like molecules or atoms
Particles of matter attract each other
The weak force of attraction exists between molecules of a substance
The intermolecular force of attraction determines the physical nature of a substance
Interesting Facts
Dispersion force is also known as London forces
The Force of interaction between polar molecules (having permanent dipole) with non-polar molecules is called Debye forces
FAQs on Particles of Matter Attract Each Other
1. What is the force of attraction between the particles of matter called?
The force of attraction that exists between the particles of matter is known as the intermolecular force of attraction. This force is responsible for holding the particles together and giving a substance its specific physical state (solid, liquid, or gas).
2. How can you demonstrate that particles of matter attract each other with a real-world example?
A simple example is a stream of water from a tap. If you try to cut the stream with your finger, you will notice that the stream of water rejoins after passing your finger. This happens because the water particles attract each other, pulling the stream back into a continuous flow. Similarly, it is difficult to break an iron nail because of the strong forces of attraction between its particles.
3. How does the strength of attraction between particles determine if a substance is a solid, liquid, or gas?
The state of matter is directly related to the strength of intermolecular forces:
- In solids, the force of attraction is very strong, holding particles in fixed positions and giving the substance a definite shape and volume.
- In liquids, the force is moderate, allowing particles to move past each other but keeping them together, resulting in a definite volume but no fixed shape.
- In gases, the force of attraction is negligible, so particles move freely and far apart, resulting in no definite shape or volume.
4. How does the distance between particles affect their force of attraction?
The force of attraction between particles is inversely related to the distance between them. This means that as the distance (intermolecular space) between particles increases, the force of attraction decreases. This is why gases, with large spaces between particles, have very weak forces of attraction compared to solids, where particles are packed tightly together.
5. Why exactly do the particles of matter attract each other?
Particles of matter, which are composed of atoms and molecules, attract each other due to various electromagnetic forces. While the detailed explanation involves complex physics, for a basic understanding, this attraction can be seen as a fundamental property that allows matter to hold its form. Without this force, all particles would drift apart, and matter as we know it—solids, liquids, and gases—would not exist.
6. Compare the force of attraction in an iron nail, a glass of water, and the air in a balloon.
The comparison of attractive forces is as follows:
- Iron Nail (Solid): The force of attraction is the strongest. Particles are tightly packed in a fixed structure, making it rigid and hard to break.
- Water (Liquid): The force of attraction is weaker than in the iron nail but strong enough to keep the particles together. This allows water to flow and take the shape of its container.
- Air (Gas): The force of attraction is the weakest or negligible. Particles are far apart and move randomly, allowing the air to expand and fill the entire balloon.
7. If particles of matter attract each other, why don't they all collapse into one point?
Particles do not collapse into a single point because two other factors are also at play. First, particles are in continuous motion and possess kinetic energy, which causes them to move around and resist being completely static. Second, when particles get extremely close, a strong intermolecular force of repulsion begins to act, pushing them apart. This repulsion balances the attraction, maintaining a stable average distance between particles.
