This topic accounts for approximately 14% of your exam marks.
stable
High
Stable14%
Wave equation (v = fλ), transverse vs longitudinal and EM spectrum properties tested consistently.
What a wave is
A wave is a disturbance produced by an oscillating source that transfers energy (and information) from place to place without transferring matter
The particles of the medium oscillate about a fixed position; the wave moves through them, but they do not travel with it
A toy duck floating on water is the classic visualisation: a passing ripple lifts the duck up and lets it back down, but the duck itself stays roughly where it was
Two ways a wave can vibrate
All waves fall into one of two categories, set by which direction the medium vibrates relative to the wave's travel:
Transverse waves: the oscillation is perpendicular to the direction of energy transfer
Longitudinal waves: the oscillation is parallel to the direction of energy transfer
Transverse waves
A transverse wave shows alternating peaks (the highest points above the rest position) and troughs (the lowest points below it)
Transverse waves can travel through solids and along the surface of a liquid, but a mechanical transverse wave cannot travel through the body of a liquid or any gas (the molecules have no lateral spring to vibrate against)
Electromagnetic waves are transverse and can travel through solids, liquids, gases, and a vacuum; they are the only transverse waves not bound by needing a material medium
Everyday examples of transverse waves:
ripples on the surface of a pond
a flicked rope or skipping line
the vibrations of a plucked guitar string
S- in earthquakes (one of the two main seismic wave types)
all (light, radio, X-rays, microwaves and so on)
Longitudinal waves
A longitudinal wave shows alternating compressions (particles bunched closer together than average) and rarefactions (particles spread further apart than average)
The medium's density and pressure rise and fall as the wave passes
Longitudinal waves travel through solids, liquids and gases because the medium can be compressed and expanded along the line of travel; they cannot travel through a vacuum because there are no particles to compress
Everyday examples of longitudinal waves:
sound waves in air, water and steel
P-waves in earthquakes (the faster of the two main seismic wave types)
pressure waves in any fluid (a sudden push on a piston of water)
Side-by-side comparison
Feature
Transverse waves
Longitudinal waves
Direction of oscillation
Perpendicular to energy transfer
Parallel to energy transfer
Visible features
Peaks and troughs
Compressions and rarefactions
Density of medium
Stays roughly constant
Rises and falls as wave passes
Pressure of medium
Stays roughly constant
Exam tip
Transverse vs longitudinal waves
Describing the difference between transverse and longitudinal waves comes up (2–3 marks), so you need to know: in a transverse wave the vibrations are perpendicular to the direction of travel; in a longitudinal wave they are parallel to it. State both directions relative to travel — "up and down" alone isn't enough.