If the energy difference between the ground state of an atom and its excited state is `4.4 xx 10^(-4) J`, the wavelength of photon required to produce the transition :

If the energy difference between the ground state of an atom and in excited state is 4.4xx10^(-14)J , the wavelength of photon required to produce the transition is:

if The energy difference between the ground state and excited state of an atom is 4.4xx 10^(-19 ) J . the wavelength of photon required to produce this transition is

The energy difference between ground state of an atom and its excited state is 3xx10^(-19)J . What is the wavelength of photom required for this radiation ?

the energy required to excite an electron in hydrogen atom to its first excited state is

A hydrogen atom initially in the ground level absorbs a photon and is excited to n=4 level then the wavelength of photon is

An electron passing through a potential difference of 4.9 V collides with a mercury atom and transfers it to the first excited state. What is the wavelength of a photon corresponding to the transition of the mercury atom to its normal state?

The energy required to excite an electron from the ground state of hydrogen atom to the first excited state, is

Assume that the charge of an electron is 1.6times10^(-19) coulomb and the energy of the first orbit of hydrogen atom is -13.6 eV. If the energy required to excite the ground state electron of hydrogen atom to the first excited state, is expressed as y times10^(-19)J per atom, what is the value of y ?

The ground state energy of hydrogen atom is -13.6eV . If the electron jumps to the ground state from the 3^("rd") excited state, the wavelength of the emitted photon is