Two nucleons are at a separation of `1xx10^(-15)m.` The net force between them is `F_(1)` if both are neutrons `F_(2)` if both are protons and `F_(3)` if one is a proton and other is a neutron. In such a case

Two nucleons are at a separation of 1 xx 10^-15 m . The net force between them is F_1 , if both are neutrons, F_2 if both are protons and F_3 if one is a proton and other is a neutron. In such a case.

Two protons are a distance of 1 xx 10^(-10) cm from each other. The force acting on them are

In the nucleus of helium if F_1 is the net force between two protons, F_2 is the net force between two neutrons and F_3 is the net force between a proton and a neutron. Then,

Two protons are kept at a separation of 10 nm . Let F_n and F_e be the nuclear force and the electromagnetic force between them.

If the nuclear force between two protons, two neutrons and between proton and neutron is denoted by F_(p p), F_(n n) and F_(pn) respectively, then

Two electrons separated by distance .r. experience a force F between them. The force between a proton and a singly ionized helium atom separated by distance 2r is

The nucleus of helium atom contains two protons that are separated by distance 3.0xx10^(-15)m . The magnitude of the electrostatic force that each proton exerts on the other is

Supposing Newton's law of gravitation for gravitation forces F_(1) and F_(2) between two masses m_(1) and m_(2) at positions r_(1) and r_(2) read where M_(0) is a constant of dimension of mass, r_(12) = r_(1) - r_(2) and n is a number. In such a case,

In two cases, two identical conducting sphere are given equal charges, in one case of the same type whereas in another case of opposite type. The distance between the spheres is not large comparing with the diameter. Let F_(1) and F_(2) be the magnitudes of the force of interaction between the spheres, as shown, then

The gravitational force between two object is F. It masses of both object are halved without changing distance between them, then the gravitation force would become