Use Moseley's law with b = 1 to find the frequency of the `K_alpha` X-ray of `La(Z = 57)` if the frequency of the `K_alpha` X-ray of `Cu(Z = 29)` is known to be `1*88 xx 10^(18)` Hz.

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##)

If lambda_(Cu) is the wavelength of K_(alpha) X-ray line of copper (atomic number 29 ) and lambda_(Mo) is the wavelength of the K_(alpha) X-ray line of molybdenum (atomic number 42 ),then the ratio lambda_(Cu)//lambda_(Mo) is close to

Let A = {x, y, z) and B = {1, 2}. Find the number of relations from A to B.

Expression of x+y + z = 1 in the form of x cos alpha + y cos beta + z cos gamma = p is ..........

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 .

1 mole photon having frequency 4.0 xx 10^(14) Hz find energy

The constant 'a' Mosely's law sqrt(v) - a(Z-b) for k_(alpha)X- rays is related to Rydberg constant R as ( 'c' is the speed of light)

K_alpha wavelength emitted by an atom of atomic number Z=11 is lambda . Find the atomic number for an atom that emits K_alpha radiation with wavelength 4lambda . (a) Z=6 (b) Z=4 (c ) Z=11 (d) Z=44.

Find the (a) maximum frequency, and (b) minimum wavelength of X-rays produced by 30 kv electrons.