zero
The strength of the gravitational field.
The answer to this whimsical but useless exercise is: Infinity
To express the idea of infinity.
Zero times infinity is defined as "indeterminate".
infinite
Earth's gravitational field extends to infinity. No matter how far you are from the earth, It's gravitational field will always pull you towards it. However, the further you are from the earth, the weaker that force will be.
A body A of mass m is placed in the gravitational field of a body B of mass M. The gravitational potential of body B at a point in the field is the work done is bringing unit mass from infinity to that point and is independent of body A. On the other hand, the gravitational potential energy of body A is the energy possessed by it due to its position in the field. In fact, Gravitational potential energy = mass of body(A) x gravitational potential
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.
No. The sum of the gravitational field and the electric field is a useless concept.
the value of log0 is -infinity which is minus of infinity
i guess it 's 39.2n.kg
No. Gravitational force is the pull an object experience from gravity. Gravitational energy is the energy an object has from its position in a gravitational field. An object moving up in a gravitational field gains gravitational energy.
Jupiters gravitational field strength is 25 Nkg^-1
ANY object is surrounded by a gravitational field.
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.
Gravitational potential energy is defined as the work performed in moving the mass from infinity to the point concerned in the gravitational field. It will be given in negative. gravitational PE = - G M m / r^2 Here G - universal gravitational constant. M - mass which produced gravitaional field. m - the mass of the object. r - the distance of the point from the centre of the M, where the object has been borught.
The gravitational field is basically "just there". However, any change in the gravitational field - for example, when an object moves, collapses, etc. - is believed to propagate at the speed of light.