The rotation periodof Earth is about23 hours and 56minutes.
The revolution period of Earth around the Sun is approximately 365.25 days.
It is the rotation of the planet one complete revolution that determines the length of a day.
All planets in our solar system vary in the time it takes them to complete a revolution. This is due to their differing distances from the sun. As far as rotation goes, the time varies from nine hours and fifty minutes for Jupiter to 244 days for Venus to make a like rotation.
No, the rotation of a planet on it's axis, or it's spin is not really related to the time it takes to orbit or revolve around the sun. For example, Mercury and Venus are the closest planets to the sun, yet they take a long time to rotate on their axis.
The relationship between a planet's size and the length of its rotation is not straightforward and can vary significantly among different planets. Generally, larger planets may have longer rotation periods due to their mass and the angular momentum they possess, but this is not a rule. For example, Jupiter is the largest planet in our solar system, yet it has a very short rotation period of about 10 hours. Conversely, smaller planets like Venus have longer rotation periods, taking about 243 Earth days to complete one rotation. Thus, while there may be some correlations, other factors such as composition, distance from the sun, and historical impacts also play a significant role in determining rotation length.
The length of a planet's day is directly related to its rate of rotation on its axis. A faster rate of rotation results in a shorter day, while a slower rate of rotation leads to a longer day. This relationship is determined by the planet's mass and distribution of mass.
Venus' period of rotation is 243 Earth days. Its period of revolution is 224. 7 Earth days. The revolution period is the length of a year in Earth days on Venus. This planet is a terrestrial planet.
It is the rotation of the planet one complete revolution that determines the length of a day.
A planet's rotation refers to the spinning motion of the planet on its axis. This rotation determines the length of a planet's day and creates day and night cycles as different parts of the planet are exposed to sunlight. Rotation is crucial for maintaining the planet's equilibrium and atmospheric conditions.
All planets in our solar system vary in the time it takes them to complete a revolution. This is due to their differing distances from the sun. As far as rotation goes, the time varies from nine hours and fifty minutes for Jupiter to 244 days for Venus to make a like rotation.
The rotation of a planet refers to the planet spinning like a top; a "revolution" is the time required for the planet's orbit around the Sun.
No, the rotation of a planet on it's axis, or it's spin is not really related to the time it takes to orbit or revolve around the sun. For example, Mercury and Venus are the closest planets to the sun, yet they take a long time to rotate on their axis.
A planet's revolution is its orbit around the sun. A planet's rotation is its movement about its axis. For example, the Earth's revolution around the sun takes 365.26 days, and its period of rotation is 24 hours.
revolution-is the revolving of an object around another object. rotation-is the spinning of an object on its axis. revolution and rotation are two different concepts but, are alike in some way. Rotation- Dominic
The revolution of a planet refers to the entire elliptical "race-track" path that it travels around the sun. Within our solar system, the time for the planets to complete one full revolution ranges from 88 Earth-days to 248 Earth-years. The time it takes for one of the Earth's revolutions around the sun is 1 year.
The difference between the rotation and revoulution is that rotation is the spiinning of the planet on its axis and revoulution is the orbiting of the planet around the sun.
Revolution and rotation
they are both about circular motions but rotation is on an axis and revolving isn't. also revolution is usually revolving around another object.