Molecular Matter (Cambridge (CIE) IGCSE Physics)

Revision Note

Lindsay Gilmour

Written by: Lindsay Gilmour

Reviewed by: Caroline Carroll

Arrangement & motion of particles

  • All molecules and matter are in motion at room temperature

    • The motion and arrangement of particles must be known for each state of matter

  • In a solid:

    • The molecules are very close together and arranged in a regular pattern

    • The molecules vibrate about fixed positions

  • In a liquid:

    • The molecules are still close together (no gaps) but are no longer arranged in a regular pattern

    • The molecules are able to slide past each other

  • In a gas:

    • The molecules are widely separated - about 10 times further apart in each direction

    • The molecules move about randomly at high speeds

Properties of states of matter

State

Solid

Liquid

Gas

Density

High

Medium

Low

Arrangement of particles

Regular pattern

Randomly arranged

Randomly arranged

Movement of particles

Vibrate around a fixed position

Move around each other

Move quickly in all directions

Energy of particles

Low energy

Greater energy

Highest energy

The forces & distances between molecules

Extended tier only

Intermolecular forces and motion of particles

  • The forces between molecules and matter (or 'particles') affect the state of matter

  • This is because the magnitude of the forces affects the relative distances and motion of the particles

  • This affects the ability of the substance to

    • Change shape

    • Change volume

    • Flow

  • The word particles can refer to:

    • Atoms

    • Molecules

    • Ions

    • Electrons

Solids

  • The molecules in a solid are held in place by strong intermolecular forces

    • They only vibrate in position

    • The distance between them is fixed and is very small

    • This gives the solid its rigid shape and fixed volume

Liquids

  • The molecules in a liquid have enough energy to overcome the forces between them

  • They are still held close together

    • The volume of the liquid is the same as the volume of the solid

  • Molecules can move around (by sliding past each other)

    • This allows the liquid to change shape and flow

Gases

  • The molecules in a gas have more energy and move randomly at high speeds

    • The molecules have overcome the forces holding them close together

  • Because of the large spaces between the molecules

    • The gas can easily be compressed and is also able to expand

    • Gases flow freely

Worked Example

Two states of matter are described below. Identify each of the states of matter.

Substance 1

  • molecules are spaced very far apart

  • molecules move very quickly at random

  • molecules move in a straight line

Substance 2

  • molecules are quite closely packed together

  • molecules move about at random

  • molecules do not have fixed positions

Answer:

Substance 1 

Step 1: Identify the distances between the molecules

  • The molecules are spaced far apart

    • This can only describe a gas

Step 2: Identify the motion of the molecules

  • The molecules move quickly, at random and in a straight line

    • This confirms that substance 1 is a gas

Substance 2

Step 1: Identify the distances between the molecules

  • The molecules are closely packed

    • This could describe either a solid or a liquid

Step 2: Identify the motion of the molecules

  • The molecules move at random and do not have fixed positions

    • This confirms that substance 2 is a liquid

Temperature & energy of particles

  • As the temperature of a gas increases, so does the average speed of particles in the gas

    • At higher temperatures, the particles have more kinetic energy

  • The amount of pressure that a gas exerts on its container is dependent on the temperature of the gas

    • This is because particles gain kinetic energy as their temperature increases

  • There must, therefore, be a temperature at which the particles are stationary

    • This is the lowest possible temperature, as particles cannot travel any slower than 0 m/s

  • The temperature at which all particles are stationary is called absolute zero

    • Absolute zero has a value of −273 °C

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Lindsay Gilmour

Author: Lindsay Gilmour

Expertise: Physics

Lindsay graduated with First Class Honours from the University of Greenwich and earned her Science Communication MSc at Imperial College London. Now with many years’ experience as a Head of Physics and Examiner for A Level and IGCSE Physics (and Biology!), her love of communicating, educating and Physics has brought her to Save My Exams where she hopes to help as many students as possible on their next steps.

Caroline Carroll

Author: Caroline Carroll

Expertise: Physics Subject Lead

Caroline graduated from the University of Nottingham with a degree in Chemistry and Molecular Physics. She spent several years working as an Industrial Chemist in the automotive industry before retraining to teach. Caroline has over 12 years of experience teaching GCSE and A-level chemistry and physics. She is passionate about creating high-quality resources to help students achieve their full potential.