Calculate Q value of the following nuclear reaction `13^(Al^(27)) + 2^(He^(4)) rarr 14^(Si^(30)) + 1^(H^(1))`+ Q. The exact mass of `13^(Al^(27))` is 26.9815 amu, `14^(Si^(30))` is 29.9738, `2^(He^(4))` is 4.0026 amu and `1^(H^(1))` is 1.0078 amu.

Predict the bombarding projectile in the following nuclear reactions (i) 13^(Al^(27)) + ? rarr 11^(Na^(24)) + 2^(He^(4)) (ii) 34^(Se^(83)) + ? rarr 34^(Se^(84)) + gamma rays (iii) 7^(N^(14)) + ? rarr 8^(O^(17) + 1^(H^(1))

Complete the following nuclear reactions (i) 18^(Ar^(40)) + ? rarr 19^(K^(40)) + 0^(n^(1)) (ii) ______ + 1^(H^(1))rarr 2^(He^(4)) + 2^(He^(4)) (iii) 88^(Ra^(236))rarr ? + 2^(He^(4)) (iv) 92A^(U^(238))rarr 56^(Ba^(143)) + _______+ 0^(n^(1))

Evaluate each of the following :- 4/(cot^(2)30^(@))+1/(sin^(2)60^(@))-cos^(2)45^(@)

Factorise each of the following : 27p^(3) - (1)/(216)-(9)/(2)p^(2) + (1)/(4)p

Find the Q - value for the nuclear reaction: ._(2)He^(4)+._(7)N^(14) rarr ._(8)O^(17)+._(1)H^(1) m(._(2)He^(4))=4.0039 "amu" m(._(7) N^(14))=14.0075 "amu" m(._(8)O^(17))=17.0045 amu m(._(1)H^(1))=1.0082 amu

Find the roots of the following equations : (1) x-(1)/(x)=3, x!= 0 (2) (1)/(x+4)-(1)/(x-7) = (11)/(30), x !=-4, 7

A star initially has 10^(40) deuterons. It produces energy via the process _(1)H^(2) + _(1)H^(2) + rarr _(1) H^(3) + p. and _(1)H^(2) + _(1)H^(3) + rarr _(2) He^(4) + n .If the average power radiated by the state is 10^(16) W , the deuteron supply of the star is exhausted in a time of the order of . The masses of the nuclei are as follows: M(H^(2)) = 2.014 amu, M(p) = 1.007 amu, M(n) = 1.008 amu, M(He^(4)) = 4.001 amu .