The farther away a planet is from the sun, the longer it takes to make an orbit. It would take more than one year if the planet was farther away from the sun than Earth.
True. The length of time that it takes to complete one orbit around the Sun is directly related to the distance of the orbit from the Sun.
a year is determined on how long the planet takes to orbit the sun. When calculating the year of a planet we use earth days. __________________ Yes, distance counts. The farther a planet is from the sun, the longer it takes that planet to complete one full orbit.
This can be answered looking at Kepler's Third Law: "The square of the orbital period of a planet is directly proportional to the cube of the semi-major axis of its orbit." What this means is that as the distance of a planet to the sun increases, this change is directly proportional to the length of it's year.
I'm not sure if you want a more detailed answer than this, but the farther away a planet is from the sun, the longer it takes to complete its orbit, since a complete orbit traverses far longer distances when a planet is far from the sun. Although planetary orbits are actually elliptical, thinking of them as circles will simplify the principle involved: if the distance from the earth to the sun is a distance of one, and the distance from Jupiter to the sun is five, the "circular" orbit for the earth would be 2(pi)one = about 6.3 units, while the distance for the earth would be 2(pi)five = about 32 units.
That would depend on the speed they are travelling. If they were both going at the same speed then the one nearer would complete its orbit first, as it has a shorter distance to travel.
the planet would have its year shorter
True. The length of time that it takes to complete one orbit around the Sun is directly related to the distance of the orbit from the Sun.
It depend on the distance of planet from sun and size of planet. If distance increases the time ie. Year increases
The period will increase. The relationship is given by Kepler's Third Law.
It decreases as the square of the distance.
It increases.
The tidal effect of a body increases as a cube of the distance.
All 8 planets, including dwarf planet Pluto, orbit the Sun. As their distance from the Sun increases, the time it takes for the planet to complete one revolution around the Sun increases as well. In order from shortest orbital period to longest orbital period:MercuryVenusEarthMarsJupiterSaturnUranusNeptune
As the altitude increases, the temperature in the troposphere will decrease. The troposphere is the lowest portion of planet's atmosphere.
Gravity doesn't change, no matter where you are. One of the characteristics of the forces due to gravity is that they're inversely proportional to the square of the distance between the two masses involved. So as your distance from a planet changes, the mutual forces attracting you and the planet toward each other change in inverse proportion to the square of the distance between you and the center of the planet.
a year is determined on how long the planet takes to orbit the sun. When calculating the year of a planet we use earth days. __________________ Yes, distance counts. The farther a planet is from the sun, the longer it takes that planet to complete one full orbit.
This can be answered looking at Kepler's Third Law: "The square of the orbital period of a planet is directly proportional to the cube of the semi-major axis of its orbit." What this means is that as the distance of a planet to the sun increases, this change is directly proportional to the length of it's year.