The gravitational force inside a hollow sphere is zero. In a non-hollow sphere of uniform composition, the gravitational force varies inversely with the distance from the center.
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.
A charged sphere with a cavity has the property that the electric field inside the cavity is zero. This means that any charge placed inside the cavity will not experience any electric force. The electric field outside the sphere behaves as if all the charge is concentrated at the center of the sphere.
The gravitational field inside a hollow sphere is zero. This is because the gravitational force from the spherical shell cancels out in all directions, resulting in no net gravitational force at the center or within the sphere.
The distribution of the electric field inside a sphere is uniform, meaning it is the same at all points inside the sphere.
When a sphere floats, its weight is equal to the buoyant force acting on it. This is because the sphere reaches an equilibrium where the upward buoyant force from the fluid equals the downward force of gravity acting on the sphere.
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.
A charged sphere with a cavity has the property that the electric field inside the cavity is zero. This means that any charge placed inside the cavity will not experience any electric force. The electric field outside the sphere behaves as if all the charge is concentrated at the center of the sphere.
The gravitational field inside a hollow sphere is zero. This is because the gravitational force from the spherical shell cancels out in all directions, resulting in no net gravitational force at the center or within the sphere.
Yes. -- Force when you lift something. -- Friction on the soles of your shoes when you walk. -- Gravitation all the time.
The distribution of the electric field inside a sphere is uniform, meaning it is the same at all points inside the sphere.
Gravitation is the natural force of attraction that exists between all objects with mass, while the law of universal gravitation is a scientific principle formulated by Newton that quantifies this force as being directly proportional to the product of the masses of the objects and inversely proportional to the square of the distance between them. In essence, gravitation is the phenomenon, whereas the law of universal gravitation mathematically describes how this force behaves.
When a sphere floats, its weight is equal to the buoyant force acting on it. This is because the sphere reaches an equilibrium where the upward buoyant force from the fluid equals the downward force of gravity acting on the sphere.
unit of both gravitation and force is newton(N) if you mean gravitational constant the unit is-Nm^2/kg^2
Mass and/or Energy
Newtons law of gravitation show us that the gravitation force between two objects directly proportion to their masses.
when the distence between the two objects is increased by ten times then the force of gravitation will reduce by 100 times.
Force? As in The Force from Star Wars? Or a gravitation force? Care to explain?