A nuclide 1 is said to be the mirror isobar of nuclide 2 if `Z_(1) =N_(1)` and `Z_(2) =N_(1)`. (a) What nuclide is a mirror isobar of `underset(11)overset(23).` Na ? (b) which nuclide out of the two mirror isobars have greater binding energy and why?

The value of cot (underset(n=1)overset(23)sum cot^(-1) (1 + underset(k=1)overset(n)sum 2k)) is

Two mirror labelled L_(1) for left mirror and L_(2) for right mirror (L_(2)) looks into this mirror and sees a series of images. The second nearest image seen in the right mirror is situated at a distance:

The sum, underset(n-1)overset(10)(Sigma)(n(2n+1)(2n-1))/5 is equal to.........

If z_1 is a complex number other than -1 such that |z_1|=1\ a n d\ z_2=(z_1-1)/(z_1+1) , then show that the real parts of z_2 is zero.

Nuclei with magic no. of proton Z=2,8,20,28,50,52 and magic no. of neutrons N=2,8,20,28,50,82 and 126 are found to be stable. (i) Verify this by calculating the proton separation energy S_(p) for .^(120)Sn (Z=50) and .^(121)Sb =(Z=51) . The proton separation energy for a nuclide is the minimum energy required to separated the least tightly bound proton form a nucleus of that nuclide. It is given by S_(p)=(M_(z-1,N)+M_(H)-M_(Z,N))c^(2) . given .^(119)Sn_49 =118.9058u, .^(120) Sn_50 =119.902199u, .^(121)Sb_51=120.903824u, .^(1)H=1.0078252u (ii) what does the existence of magic number indicate?

A convex mirror offocal length fforms an image which is 1/n times the object. The distance of the object from the mirror is:

Point S^(') is the image of a point source of light S in a spherical mirror whose optical axise is N_(1)N_(2) (shown in Figure). Find by construction the position of the center of the mirror and its focus.

A radio nuclide with half life T = 69.31 second emits beta -particles of average kinetic energy E = 11.25eV . At an instant concentration of beta -particles at distance, r = 2m from nuclide is n = 3 xx 10^(13) per m^(3) . (i) Calculate number of nuclei in the nuclide at that instant. (ii) If a small circular plate is placed at distance r from nuclide such that beta -particles strike the plate normally and come to rest, calculate pressure experienced by the plate due to collision of beta -particle. (Mass of beta -particle = 9 xx 10^(-31)kg ) (log_(e) 2 = 0.693)

A radio nuclide A_(1) with decay constant lambda_(1) transforms into a radio nuclide A_2 with decay constant lambda_(2) . Assuming that at the initial moment, the preparation contained only the radio nuclide A_(1) (a) Find the equation decribing accumulation of radio nuclide A_(2) with time. (b) Find the time interval after which the activity of radio nuclide A_(2) reaches its maximum value.

A radio nuclide A_(1) with decay constant lambda_(1) transforms into a radio nuclide A_2 with decay constant lambda_(2) . Assuming that at the initial moment, the preparation contained only the radio nuclide A_(1) (a) Find the equation describing accumulation of radio nuclide A_(2) with time. (b) Find the time interval after which the activity of ratio nucliei A_(2) reaches its maximum value.