Frequencies of `K_alpha` X-rays of different materials are measured. Which one of the graphs in figure (44-Q1) may represent the relation between the frequency v and the atomic number Z.

Figure shows the intensity-wavelength relations of X-rays coming from two different Coolidge tube. The solid curve represents the relation for the tube A in which the potential difference between the target and the filament is V_a and the atomic number of the target material is Z_A . These quantities are V_beta and Z_beta for the other tube. 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.

Explain about the relationship between the atomic number of an element and frequency of the X-ray emitted from the elements.

Each question has four choices, a,b,c and d,out of which only one is correct. Each question contains STATEMENT 1 and STATEMENT 2. if both the statements are true and statement 2 is the correct explanation of statement 1. If both the statements are true but statement 2 is not the correct explanation of statement 1. If statement is True and statement2 is false. If statement1 is false and statement2 is true. Consider the function f(x)=sin(k x)+{x}, where (x) represents the fractional part function. Statement 1 : f(x) is periodic for k=mpi, where m is a rational number Statement 2 : The sum of two periodic functions is always periodic.

Continuous X-rays are made to strike a tissue paper soaked with polluted water. The incoming X-rays excite the atoms of the sample by knocking out the electrons form the inner shells. Characteristic X-rays are subsequently emitted. The emitted X-rays are analysed and the intensity is plotted against the wavelength (figure 44*E1). Assuming that only K_alpha intensities are detected, list the elements present in the sample from the plot. Use Moseley's equation. v = (25 xx 10^(14) Hz) (Z - 1)^(2) .

The graph of a linear programming problem is given below. The shaded region is the feasible region. The objective function is Max Z=px+qy (i) What are the coordinates of the corners of the feasible region. (ii) Write the constraints. (iii) If the Z occurs at A and B, what is the relation between p and q. (iv) If q=1 write the objective, function. (v) Find the Max Z.

Figure shows a source of sound moving along the X-axis at a speed of 22 m s^-1 continuously emitting a sound of frequency 2.0 kHz which travels in air at a speed of 330 in s^-1 . A listener Q stands on the Y-axis at a distance of 330 m from the origin. At t = 0, the source crosses the origin P. (a) When does the sound emitted from the source at P reach the listener Q 9 (b) What will be the frequency heard by the listener at. this instant 9 (c) Where will the source be at this instant ? .

The maximum frequency upsilon of continuous X-ray is related to the applied potential difference V as _____ .

If gamma is the frequency of characteristic X-ray line emitted by a target element of atomic number Z, then Moseley's law is