88% of what it is here ; so 28.2 feet /sec 2
On the surface of Venus, the acceleration of gravity, and therefore the weight of any object, is 90.3 percent of what it is on the surface of Earth.
The gravity present on a planet is usually denoted by the acceleration an object would experience due to gravity on that planet's surface. If we stick to Newtonian gravity (which should be adequate for our present purpose) the acceleration due to gravity on a planet is given by: a = G*M / R^2 Where G is Newton's gravitational constant, M is the mass of the planet, and R is its radius (remember we are standing on the surface). (Note: Here I have neglected the vector qualities of acceleration, this will not matter at present, the acceleration will be pointing down, towards the center of the planet.) From this formula we can see that the acceleration increases if the mass of the planet increases. This is to be expected; gravity (in Newtonian gravity) is caused by mass, and thus a bigger mass means a stronger gravitational field. Since Venus is less massive than Earth we might expect the surface gravity on Venus to be less than on Earth. However, we also have the R^2 in the denominator. This means the surface gravity on a planet will increase if the radius decreases (and the mass stays the same). This is also clear; if the radius is less then you stand deeper into the gravitational field. Venus is about the same size as Earth so this effect should not play as much a role as the difference in mass does. Thus, just by using these arguments we can already conclude that the surface gravity on Earth is larger than the surface gravity on Venus. Let us now look at some numbers. Earth's surface gravity is about 9.81 m/s^2 (it varies slightly from location to location). And Venus' surface gravity is 8.87 m/s^2, which is less, as expected. This means that if you weigh 70 kg on Earth you will weigh 70*(8.87/9.81) = ~63 kg on Venus.
The force of gravity at the surface of Venus is 8.87 meters per second per second, or 8.87 meters per second squared. If you weighed 100 pounds on Earth, you would weigh approximately 91 pounds on Venus.
The gravitational field strength on Venus is about 8.87 m/s^2, which is about 91% of Earth's gravitational field strength. This means that objects on Venus would feel slightly lighter compared to on Earth.
Venus has weaker gravity than Earth. The surface gravity on Venus is about 91% of Earth's gravity.
On the surface of Venus, the acceleration of gravity, and therefore the weight of any object, is 90.3 percent of what it is on the surface of Earth.
It hasn't. The acceleration of gravity on or near the surface of Venusis about 91% of what it is on or near the surface of the Earth.(That's less than what it is here.)
The acceleration of gravity on or near the surface of Venus is 8.87 m/s2 . . .about 91% of its value on or near the surface of Earth.
The acceleration of gravity on or near the surface of Venus, and therefore the weight of objects located there, is about 9.7 percent less than on Earth.
The acceleration due to gravity on the surface Venus is 8.9m/s2 That's about 90% of Earth's.
The gravity present on a planet is usually denoted by the acceleration an object would experience due to gravity on that planet's surface. If we stick to Newtonian gravity (which should be adequate for our present purpose) the acceleration due to gravity on a planet is given by: a = G*M / R^2 Where G is Newton's gravitational constant, M is the mass of the planet, and R is its radius (remember we are standing on the surface). (Note: Here I have neglected the vector qualities of acceleration, this will not matter at present, the acceleration will be pointing down, towards the center of the planet.) From this formula we can see that the acceleration increases if the mass of the planet increases. This is to be expected; gravity (in Newtonian gravity) is caused by mass, and thus a bigger mass means a stronger gravitational field. Since Venus is less massive than Earth we might expect the surface gravity on Venus to be less than on Earth. However, we also have the R^2 in the denominator. This means the surface gravity on a planet will increase if the radius decreases (and the mass stays the same). This is also clear; if the radius is less then you stand deeper into the gravitational field. Venus is about the same size as Earth so this effect should not play as much a role as the difference in mass does. Thus, just by using these arguments we can already conclude that the surface gravity on Earth is larger than the surface gravity on Venus. Let us now look at some numbers. Earth's surface gravity is about 9.81 m/s^2 (it varies slightly from location to location). And Venus' surface gravity is 8.87 m/s^2, which is less, as expected. This means that if you weigh 70 kg on Earth you will weigh 70*(8.87/9.81) = ~63 kg on Venus.
Sure. The acceleration of gravity at the 'surface' of Uranus is 8.995 m/s2 . . . about 92% of what it is on Earth, and greater than on Mercury, Venus, Mars, Pluto, or the moon.
Yes. The surface gravity of Venus is about 92% that of the Earth.
The surface gravity of Venus is 90.4% that of Earth.
The force of gravity at the surface of Venus is 8.87 meters per second per second, or 8.87 meters per second squared. If you weighed 100 pounds on Earth, you would weigh approximately 91 pounds on Venus.
The acceleration of gravity on the surface of Venus is 8.858 m/s2 , so the force is 8.858 newtons (1.991 pounds) per kilogram of mass. That's 90.32% of the corresponding value on Earth. If you weigh 200 pounds here, you would weigh 180.6 pounds on Venus (not counting all the stuff you'd need to wear just to stay alive there).
The acceleration of gravity at the surface of Earth is approximately 9.81 meters per second squared.