The acceleration due to gravity on the surface of the Sun is approximately 274 m/s². This is significantly stronger than Earth's gravity, which is about 9.81 m/s². The Sun's massive size and density contribute to this high gravitational pull, which is essential for maintaining its structure and facilitating processes like nuclear fusion in its core.
No meaningful comparison is possible without specifying that the distance from both bodies will be the same at the moment of measurement. If you measured the acceleration due to gravity (or your weight) some distance from the sun, and then measured the acceleration due to gravity (or your weight) at the same distance from the Earth, you would find that the measurement in the vicinity of the sun is about 332,982 times the corresponding measurement at the Earth. It doesn't matter what the distance is, as long as both are the same.
The unit of gravitational acceleration is the unit as in regular acceleration Acceleration is measure [distance / time unit2] Acceleration is usually measure in [m/s2] The moon's is 1.625 [m/s2] Earth's is 9.8067 [m/s2] The sun's is 274.1 [m/s2]
what is gravitational force acting on sun in our book it was 270 m/s2 but i think it is 27.0 m/s2 *EDIT*: No, it is 274 m/s2. (27 m/s2 is only marginally higher than Jupiter's)
Like all other planets and other objects in the solar system, including you, Venus is kept in orbit by the Sun's gravity, which is exacty balanced by its acceleration towards the Sun, which appears as a continuous inward curve towards the Sun.
The force that the planet Earth applies on an object(the force is also called weight) depends on the mass of the object. It is not constant. The formula is: Weight = mass x acceleration due to gravity Acceleration due to gravity has a constant value on Earth: 9.81 m s-2 However, it is not constant everywhere in the universe. It depends on the planet you are on. Mass, however, is constant.
We can calculate the gravity on any planet or star by using this formula g = GM/r2 where M is mass of the planet or star G is universal gravitational constant g is acceleration due to gravity & r is the radius of the planet or star. Mass of the sun=1.99x1030 kg. radius of the sun=6.96 x 108m The acceleration due to gravity on the sun= 274.13 m/s2 g =(6.673x10-11) X (1.99x1030)/(6.96x108)2 Plugging in the values gives us the acceleration due to gravity on the sun= 274.13 m/s2
Actually the number stated is only an approximate number. The exact value depends on where you are on the earth and even where the sun and moon are in relation to you. Astronauts above the earth experience microgravity and as a space probe moves away from the earth, the acceleration of gravity decreases. Even on the surface of the earth, the acceleration due to gravity varies - depending on the density of the material underneath.
Your units are off. Earth's acceleration due to gravity is 9.8 m/s2 = 1g The Sun's acceleration due to gravity is 274m/s2 So you must divide: (274m/s2) / (9.8 m/s2)= 28 times as much gravity on the sun than on earth. Or... the sun's gravity is 28g where 1g is the pull on earth.
No meaningful comparison is possible without specifying that the distance from both bodies will be the same at the moment of measurement. If you measured the acceleration due to gravity (or your weight) some distance from the sun, and then measured the acceleration due to gravity (or your weight) at the same distance from the Earth, you would find that the measurement in the vicinity of the sun is about 332,982 times the corresponding measurement at the Earth. It doesn't matter what the distance is, as long as both are the same.
The mass of the sun is many times that of the earth, the result is that the acceleration of gravity is also much greater. Since the acceleration of gravity on the sun is higher, and the weight of an object is based on its mass and acceleration of gravity, the object would weigh considerably more
On or near the surface of the earth, the acceleration of gravityis 9.8 meters (32.2 feet) per second2 in a vacuum.On or near the surface of other bodies, it's a different value, because their masses are different.Acceleration due to gravity is completely independent of the mass of the falling body. Whether the falling body has a large, small, or in-between mass, the acceleration due to gravity is the same number, as long as it stays on the same planet. Any difference is the result of air resistance.Ans 2The previous answer is a nice example of a newtonian constant gravity.Acceleration due to gravity is dependent on the mass and the distance between both bodies, bodies of relatively small mass have a negligible effect on the gravity exerted by large bodies. All bodies with mass have gravity. As the two bodies approach each other gravity increases as a square to their change in distance between their centers. The greater the mass of either body the greater the acceleration. dropping a bowling ball and a golf ball from a specific height they will strike the earth at the same time. But the gravity exerted by the sun on Venus is greater than the gravity exerted by the sun on the Earth due to the relative distances between them. The gravity exerted on the Earth by the sun is greater than the gravity exerted by the sun on the moon due to the relative difference in mass of the earth and the moon.Gravity is proportional to the product of the two masses, and inversely proportional to the square of the distance.Read more: Does_the_mass_and_gravity_correlate
The acceleration of one mass toward another one on account of gravity doesn't depend on the mass of the smaller one. That's why all objects fall to earth with the same acceleration. The size of an object's orbit around a large mass doesn't depend on the smaller object's mass either. That's why a space-walking astronaut and the Space Shuttle that his pajamas are stored in for later can stay in the same orbit without flying apart.
Planets are pulled in strongly by the Sun's gravity. The planets also go around the Sun at high speeds. The combined effect is that the acceleration due to gravity only causes a planet's path to curve continuously inwards towards the Sun, and that process can go on forever.
they pull toward each other, but the earths orbital velocity compensates exactly for this acceleration together due to gravity a = (G* (m1+m2))/d^2 acceleration that balances this a = v^2/d : G = newtons gravitational constant m1 = sun mass m2 = earth mass d = distance between centres v = orbital velocity
Everything in our solar system revolves around the sun due to gravity. Gravity is the fundamental key to planetary orbit.
When our skin get exposure to sun our skin darken. And skin darkening due to sun rays is known as tanning. Tanning is cause due acceleration in melanin.
Earth orbits the sun due to the force of gravity. Gravity is the attraction between two objects with mass, and the sun's gravity pulls Earth towards it, causing Earth to move in a circular path around the sun.