If an electron in H atom has an energy of -78.4 kcal/mol the orbit in which the electron is present is

An one -electron atom has an energy of -3.4 eV. The kinetic energy of the electron is

An one -electron atom has an energy of -3.4 eV. The potential energy of the electron is

Velocity of an electron revolving in a certain orbit of H-atom is (1)/(275) tiems the velocity of light. Find the orbit in which the electron is revolving.

According to Bohr's atomic model the electrons move around the nucleus in a circular orbit the electrons can move only in that orbit in which a angular momentum of electrons I sintegral multiple of h/2pi i.e. mvr=nh/2 pi where n=principle quantum number r=radius of orbit v=velocity of electron h=plank's constant the energy of orbit in which electron is moving is given by E_n=-13.6(z^2/n^2)eV//"atom" The radius of which of the following orbits is the same as that of the first Bohr's orbit of hydrogen atom?

Name the noble gas and give its atomic number if the number of d-electrons present in this atom is equal to the difference in the no. of electrons present in the p and s-subshells.

The bromine atom possesses 35 electrons. It contains 6 electrons in 2p orbital. 6 electrons in 3p orbital and 5 electron in 4p orbital. Which of these electron experiences the lowest effective nuclear charge?

Statement I : The magnetic moment of an electron rotating in an atom is proportional to its angular momentum . Statement II : The electrons in an atom can rotate only if those orbits for which the angular momentum of the electron is an integral multiple of (h)/(2pi) (h - Planck 's constant ).

An electron in a hydrogen -like atom is in an excited state. It has a total energy of -3.4 eV. Calculate the kinetic energy of the electron.

In Bohr's model of the H-atom the ratio between the period of revolution of an electron in the orbit n=1 to the period of revolution of the electron in the orbit n=2 is