According to Bohr's frequency rule, the frequency of radiotion obsorbed or emitted when transtion occurs between two stationary states that differ in enegry by `DeltaE` is given by

The frequency of radiation absorbed or emitted when transition occurs between two stationary states with energies E_(1) (lower) and E_(2) (higher) is given by

The wavelength of one line in the visible region o fthe atmoic spectrum of hydrogen is 6.5xx10^(-7)m . This radiation is emitted when electron in a hydrogen atom goes from a high enegry state to a lower energy state. Calculate the difference in enegry between the two states. Strategy: According to the Bohr frequency rule, if the electron jumps from one orbit whose quantum number is n_(1) to a second orbit whose quantum number is n_(f) , the difference in enegry (DeltaE) is related to the frequency (v) of the radiation which in turn is related to the wavelength (lambda) : ? DeltaE = hv and v = (c)/(lambda) Thus, DeltaE = (hc)/(lambda)

When the source is moving towards the stationary observer, the apparent frequency is given by

According to maxwell's theiory of electrodnamics, an electron going in a circle should emit redastion of frequency equal to the frequency of revolution what should be the wavelength of the radiation emitted by a hydrogen atom in ground state if this rule is follewed?

According to Bohr the difference between the energies of the electron in the two orbits is equal to

The frequency of crosoing -over occurring between two genes located on the same chromosome depends on:

According to Maxwell's theory of electron dynamics, an electron going in a circle should emit radiation of frequency equal to its frequency of revolution. What should be the wavelength of the radiation emitted by a hydrogen atom in the ground state if this rule is followed?

Using Bohr's theory show that when n is very large the frequency of radiation emitted by hydrogen atom due to transition of electrom from n to (n-1) is equal to frequency of revolution of electron in its orbit.