The effect of gravity inside a solid sphere is that it pulls objects towards the center of the sphere, with the force of gravity decreasing as you move towards the surface. This is because the mass of the sphere is concentrated at the center, creating a gravitational pull towards that point.
The gravitational force inside a solid sphere is zero because the gravitational forces from the parts of the sphere above cancel out the forces from the parts below, resulting in a net force of zero at any point inside the sphere. This is known as the shell theorem.
The moment of inertia of a solid sphere is given by the formula (2/5) m r2, where m is the mass of the sphere and r is the radius of the sphere.
The formula for calculating the moment of inertia of a solid sphere is (2/5) m r2, where m is the mass of the sphere and r is the radius of the sphere.
An electric charge cannot be established or maintained inside a conductive container. This is the basis of the Faraday Cage, used to isolate a working space from electric fields.
The moment of inertia of a solid sphere is derived by integrating the mass of the sphere over its volume, taking into account the distance of each mass element from the axis of rotation. This integration results in the formula for the moment of inertia of a solid sphere, which is (2/5) mass radius2.
That all depends on the shape of the object and how its mass is distributed. The center of gravity of a solid sphere is at the center of the solid sphere. The center of gravity of a solid cube is at the center of the solid cube. The Earth's center of gravity is at the center of the Earth, and there's certainly plenty of mass there. But the center of gravity of a ring is at the center of the ring ... an open space where the finger goes.
The basketball itself is in a solid state of matter and the air inside of it is in a gaseous state of matter.
Every speck of mass throughout any solid body "has gravity", and attracts every other speck of mass. But when you're outside of the solid body, the gravitational effect of all those specks of mass is exactly as if all of its mass were located at its "center of mass" or "center of gravity". For a homogeneous spherical object, that point is the center of the sphere.
Since a sphere is round it is a shape without a face.
The gravitational force inside a solid sphere is zero because the gravitational forces from the parts of the sphere above cancel out the forces from the parts below, resulting in a net force of zero at any point inside the sphere. This is known as the shell theorem.
No it is not a solid.
Liquids, primarily water on the earth, and gasses, air, tend to form spheres in the absence of altering forces. The sphere is created by gravity naturally, where the forces acting around the center of gravity on the surface of the sphere are in equilibrium anywhere on the surface of the sphere. By introducing a solid mass on the surface of the sphere, which is less dense than the material of the sphere, it displaces that material creating a new surface further from the center of gravity of the sphere. The gravity acting on this new layer wants to pull the fluid back to it's original spherical shape by attempting to displace the solid object. Thus this downward force created is countered by an upward force of the fluid on the solid object it is trying to displace. **If the object were more dense than the fluid it would be drawn to the center of gravity, sink, thus the new surface of the fluid would again be in equilibrium.
A sphere is a geometric solid because it has 3 dimentions.
sphere
A sphere has a single face, one surface. A sphere has no corners. Or if you want to think about it from another perspective - a sphere has an infinity number of sides allowing for the curved surface.
The mass of a solid is the amount of matter that it has that determines its heaviness without the effect of gravity. Its standard unit of measurement is kilogram.
The moment of inertia of a solid sphere is given by the formula (2/5) m r2, where m is the mass of the sphere and r is the radius of the sphere.