In hydrogen atom, an electron is revolving in the orbit of radius `0.53 Å` with `6.6xx10^(15) rotations//second`. Magnetic field produced at the centre of the orbit is

An electron moving in a circular orbit of radius makes n rotations per second. The magnetic field produced at the centre has magnitude :

An electron moving in a circular orbit of radius makes n rotations per second. The magnetic field produced at the centre has magnitude :

In an hydrogen atom, the electron revolves around the nucles in an orbit of radius 0.53 xx 10^(-10) m . Then the electrical potential produced by the nucleus at the position of the electron is

In an hydrogen atom, the electron revolves around the nucles in an orbit of radius 0.53 xx 10^(-10) m . Then the electrical potential produced by the nucleus at the position of the electron is

An electron revolves in a circle of radius 0.4 A with a speed of 1 0^(6)ms^(-1) in a hydrogen atom. The magnetic field produced at the centre of the orbit due to the motion of the electron (in tesla) is [mu_(0)=4pixx10^(-7)Hm^(-1) , charge on the electron= 1.6xx10^(-19)C]

The radius of the first electron orbit of a hydrogen atom is 0.5Å . The electron moves in this orbit with a uniform speed of 2.2xx10^(6)m.s^(-1) . What is the magnetic field produced at the centre of the nucleus due to the motion of this electron?

If an electron is revolving in a circular orbit of radius 0.5A^(@) with a velocity of 2.2xx10^(6)m//s . The magnetic dipole moment of the revolving electron is

An electron revolving in an orbit of radius 0.5 A^(@) in a hydrogen atom excutes 10^(16) revolutions per second. The magnetic moment of electron due to the orbital motion will be