If the radius of an orbit is `r` and the velocity of electron in it is `v` , then the frequency of electron in the orbit will be

Electron Orbits

The radius of the an orbit of Be^(+3) ion is 0.529Å. The velocity of electron in this orbit will be

What is the velocity of electron in second orbital of He^(+) ion.

Which of the following option(s) is/are independent of both n and Z for H- like species? U_(n) = Potential energy of electron in n^(th) orbit KE_(n) = Kinetic energy of electron in n^(th) orbit l_(n) = Angular momentam of electoron in n^(th) orbit v_(n) = Velcity of electron in n^(th) orbit f_(n) = Frequency of electron in n^(th) orbit T_(n) = Time period of revolution of electron in n^(th) orbit

The velocity of an electron in the first orbit of H atom is v. The velocity of an electron in the 2nd orbit of He^+ atom.

The velocity of electron moving in 3rd orbit of He^(+) is v. The velocity of electron moving in 2nd orbit of Li^(+2) is

The velocity of an electron in the first orbit of H atom is v . The velocity of an electron in the second orbit of He^(+) is

If an electron is moving with velocity v in an orbit of radius r then the equivalent magnetic field at the centre will be:

The velocity of an electron in single electron atom in an orbit

The ratio of the radius of the Bohr orbit for the electron orbiting the hydrogen nucleus that of the electron orbiting the deuterium nucleus is approximately