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For the 8 major planets, the length of the year (period of revolution) in Earth time:

Mercury = 88 days (0.25 Earth years) - 2.9 months

Venus = 224.7 days (0.67 Earth years) - 7.4 months

Earth = 365.25 days (1 Earth year) - 12 months

Mars = 687 days (1.88 Earth years) - 1 year, 2.5 months

Jupiter = 4332.6 days (11.86 Earth years) - 11 years, 10.3 months

Saturn = 10759 days (29.46 Earth years) - 29 years 5.5 months

Uranus = 30799 days (84.3 Earth years) - 84 years, 3.6 months

Neptune = 60190 days (164.8 Earth years) - 164 years, 9.6 months

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11y ago
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10y ago

The revolution period of a planet is the time it takes to travel around the Sun. The revolution period of Mercury is 58.65 Earth days, for Venus is 224.7 days, Mars is 686.93 days, Jupiter is 11.86 Earth years, Saturn is 29.46 years, Uranus is 83.75 years, and Neptune is 163.72 years.

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5mo ago

Mercury: 88 Earth days Venus: 225 Earth days Earth: 365.25 days Mars: 687 Earth days Jupiter: 11.9 Earth years Saturn: 29.5 Earth years Uranus: 84 Earth years Neptune: 165 Earth years

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14y ago

define "revolution" more in detail please

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Q: What is the revolution of each planet?
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Related questions

What is the direction of each planet's revolution around the sun called?

anti clockwise


How many days in a revolution?

There are 365.25 days in the Earth's revolution around the Sun. Hence, leap years. Each planet has its own period of revolution.


How is the temperature and period of revolution of each planet related to its distance from the sun?

because the sun go to the earth


Is the period of revolution dependent on the size of the planet?

No. The period of revolution depends on the size of the orbit of the planet.


The planets revolution from the sun?

Each planet in our solar system revolves around the sun in an elliptical orbit. The time it takes for a planet to complete one revolution around the sun is known as its orbital period. This period varies for each planet based on its distance from the sun.


What is meant by rotation and revolution of a planet?

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.


How would you define revolution of Planets in the solar system?

The revolution of planets in the solar system refers to the motion of a planet in its orbit around the Sun. Each planet follows an elliptical path with the Sun at one of the foci. The time it takes for a planet to complete one revolution is known as its orbital period.


How do you find the number revolution days of each planet?

To find the number of revolution days of a planet, you can use the formula: revolution days = orbital period / rotation period. The orbital period is how long it takes for the planet to complete one orbit around the sun, while the rotation period is how long it takes for the planet to rotate on its axis. This formula will give you the number of days it takes for the planet to complete one full rotation around its axis.


Does the length of the revolution vary from planet to planet?

Yes.


How does planet distance from the sun affect the period of revolution?

How does a planet's distance from the sun affect its period of revolution?


What is a planet's revolution?

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.


What is the relationship between a planets movement and a planets rotation and revolution?

A planet's rotation is its spinning on its axis, which determines day and night cycles. Its revolution is its orbit around the sun, which determines its year length. Both rotation and revolution are independent of each other, but they work together to create the planet's overall movement and the changing seasons.