The Earth's gravitational field is important primarily because it keeps the Earth in orbit around the Sun, which sustains life. Without gravity, life would cease to exist.
In the cavity at the center of the Earth, your weight would be zero, because you would be pulled equally by gravity in all directions. - The gravitational field of Earth at its center is zero.
At a point between the Earth and the Moon where the gravitational field strength is zero, the gravitational pull from the Earth and the Moon cancels out, resulting in a net force of zero. This point is known as the L1 Lagrange point, where the gravitational forces are balanced due to the interaction between the gravitational pull of the Earth and the Moon.
The gravitational field due to the stone is much weaker than that due to Earth because of the difference in mass between the two objects. The strength of the gravitational field depends on the mass of the object creating it, so Earth's gravitational field is much stronger due to its significantly larger mass compared to the stone.
No. Earth's gravitational field is due to the large mass within it; the electromagnetic field is due to the movement of the metals in its core. There are also the standard differences between a gravitational and an EM field.
All objects within the universe attract all other objects through gravity. as distance increases this attraction lessens to an insignificant amount, however the force is still there. therefore the Earth's gravitational field's range is limitless.
In the cavity at the center of the Earth, your weight would be zero, because you would be pulled equally by gravity in all directions. - The gravitational field of Earth at its center is zero.
Mercury's gravitational field strength is approximately 3.7 m/s^2, which is about 38% of Earth's gravitational field strength. This means that objects on the surface of Mercury would weigh less compared to Earth due to the lower gravitational pull.
If the gravitational field of the sun collapses, the earth is likely to come to an end.
The Earth's Gravitational field
No, the gravitational field strength on each planet depends on its mass and radius. For example, Jupiter has a stronger gravitational field than Earth due to its larger mass, while Mars has a weaker gravitational field because it is smaller and less massive than Earth.
No.
The gravitational field strength of Earth and the Moon differs because each celestial body has its own mass and radius. Earth is more massive and has a larger radius compared to the Moon, leading to a stronger gravitational field on Earth. The gravitational field strength decreases with distance from the center of the body, so being closer to Earth results in a stronger gravitational pull compared to being closer to the Moon.
At a point between the Earth and the Moon where the gravitational field strength is zero, the gravitational pull from the Earth and the Moon cancels out, resulting in a net force of zero. This point is known as the L1 Lagrange point, where the gravitational forces are balanced due to the interaction between the gravitational pull of the Earth and the Moon.
The gravitational acceleration of an object near Earth is the same because it depends only on the mass of the Earth and the distance from the center of the Earth. This means that all objects experience the same gravitational acceleration, regardless of their mass or composition.
The gravitational field due to the stone is much weaker than that due to Earth because of the difference in mass between the two objects. The strength of the gravitational field depends on the mass of the object creating it, so Earth's gravitational field is much stronger due to its significantly larger mass compared to the stone.
The motion of the sun will stop because the sun will crush on the earth if the gravitational field of the sun collapses.
The intensity of the gravitational field of Earth is maximum at its surface, where it is approximately 9.81 m/s². This value decreases as you move further away from the surface of the Earth.