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The Solar System - AQAOrbits and speed - Higher

The Sun is our nearest star. It is a relatively small star when compared to other stars in the universe. Our Solar System contains the Sun and everything that orbits it.

Part of Physics (Single Science)Space physics

Orbits and speed - Higher

Orbits and constant speed

When an object moves in a circle at a constant , its direction constantly changes. A change in direction causes a change in velocity. This is because is a quantity - it has an associated direction as well as a magnitude. A change in velocity results in , so an object moving in a circle is accelerating even though its speed may be constant.

An object will only accelerate if a acts on it. For an object moving in a circle, this resultant force is the that acts towards the middle of the circle. Gravitational attraction provides the centripetal force needed to keep planets and all types of satellite in orbit.

Orbits and changing speed

The gravitational attraction between two objects decreases with distance. This means that the closer the two objects are to each other, the stronger the force of gravity between them. If the force between them is greater, a greater acceleration will occur.

The greater the acceleration, the greater the change in velocity - this causes the object to move faster. This means that objects in small orbits travel faster than objects in large orbits.

The graph shows how the orbital speed of a planet changes with its distance from the Sun.

Graph plotting speed in metres per second (m/s) against distance from the sun in millions of kilometres (km). Graph plots Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus then Neptune.
Figure caption,
Planets further from the sun orbit more slowly

Artificial satellites travel in one of two different orbits:

  • polar orbits
  • orbits

Polar orbits take the satellites over the Earth鈥檚 poles. The satellites travel very close to the Earth (as low as 200 km above sea level), so they must travel at very high speeds (nearly 8,000 m/s).

Geostationary satellites take 24 hours to orbit the Earth, so the satellite appears to remain in the same part of the sky when viewed from the ground. These orbits are much higher than polar orbits (typically 36,000 km) so the satellites travel more slowly (around 3 km/s).

Types of orbit. Image shows a satellite in geostationary orbit and a satellite in polar orbit around Earth.