The electrostatic force between two point charges and the gravitational attractive force between two point masses- both are inversely proportional to the square of the distance between the charges and the masses, respectively.
(1)(a) Compare the eletrostatic force `(F_(C))` and the gravitational force `(F_(G))` between an electron and a proton. (b) Compare `F_(C)` and `F_(G)` between two protons.
(ii) Find out the accelerations of an electron and of a proton due to the electrostatic force between them when htey are placed at a distance of `1 Å`

The electrostatic force between two point charges is directly proportional to the

Give the ratio of magnitude of the electrostatic force to the gravitational force between a proton and an electron.

Coulomb's law for electrostatic force between two point charges and Newton's law for gravitational force between two stationary point masses, both have inverse-square dependence on the distance between the charges and masses respectively, (a) Compare the strength of these forces by determining the ratio of their magnitudes (i) for an electron and a proton and (ii) for two protons. (b) Estimate the accelerations of electron an proton due to the electrical force of the mutual attraction when they are =10^(-10)m apart? (m_(p) = 1.67 xx 10^(-27) kg, m_(e) = 9.11 xx 10^(-31) kg)

What is the ratio of electrostatic force and gravitational force between two electrons?

Electric force between two protons is ...... times greater than gravitational force.

Coulomb's law for electrostatic force between two point charges and Newton's law for gravitational force between two stationary point masses, both have inverse-square dependence on the distance between the charges/masses. Compare the strength of these forces by determining the ratio of their magnitudes (i) for an electron and a proton and (ii) for two protons

Two protons are kept at a separation of 50Å. Fn is the nuclear force and F_(e ) is the electrostatic force between them, then

Coulomb's law for electrostatic force between two point charges and Newton's law for gravitational force between two stationary point masses, both have inverse square dependence on the distance between the charges // masses (a) compare the strength of these forces by determining the ratio of their magnitudes (i) for an electron and as proton (ii) for two protons (b) estimate the accelerations for election and proton due to electrical force of their mutal attraction when they are 1 A apart.