Obtain a relation between the frequencies of `K_(alpha), K_(beta)` and `L_(alpha)` line for a target metrial .

The energy of an element with a vacancy in K-shell is 35.2 keV, in L-shell is 5.25 keV and in M-shell is 0.55 keV higher than the energy of the atom of with no vacancy. Find the frequency of K_(alpha),K_(beta) and L_(alpha) X-rays of that element.

If the frequency of K_(alpha), K_(beta) and L_(alpha) , X-ray lines of a substance are v_(K_(alpha)), v_(K_(beta)) , and v_(L_(beta))

Let lambda_(alpha'), lambda_(beta),and lambda'_(alpha) denote the wavelength of the X-ray of the K_(alpha), K_(beta), and L_(alpha) lines in the characteristic X-rays for a metal. Then.

Let lambda_(alpha), lambda_(beta),and lambda'_(alpha) denote the wavelength of the X-ray of the K_(alpha), K_(beta), and L_(alpha) lines in the characteristic X-rays for a metal. Then.

If lamda_(K_(alpha)),lamda_(K_(beta)) and lamda_(L_(alpha)) are the wavelengths of K_(alpha),K_(beta) and L_(alpha) lines, then

Show that the frequency of K_beta X-ray of a material equals the sum of the frequencies of K_alpha and L_alpha X-rays of the same material. (##HCV_VOL2_C44_S01_006_Q01##)

In figure find which is K_(a) and L_(alpha')

For a cartain metal, the K obsorption edge is at 0.72 Å . The wavelength of K_(alpha), K_(beta). And K_(gamma) lines of of K series are 0.210 Å , 0.192 Å, and 0.180 Å, respectively. The eneggies of K, L and M orbit are E_(K), E_(L) and E_(M) , respectively. Then

The energy of a silver atom with a vacancy in K shell is 25.31 keV, in L shell is 3.56 keV and in M shell is 0.530 keV higher than the energy of the atom with no vacancy. Find the frequency of K_alpha , K_beta and L_alpha X-rays of silver.

Statement-1 : The frequency of K_(alpha) X-radiation is greater than K_(beta) for a given target material. and Statement-2 : K_(alpha) radiation is produced when an electron from n = 2 jumps into the vacancy in n = 1 orbit, whereas in K_(beta) radiation the transition takes place from n = 2 to n = 1 .