In the reaction `""_(1)^(2)H+ _(1)^(3)H+^(1)to_(2)^(4)He+^(1)n_(0)` if the binding energies of `""_(1)^(2)H+ _(1)^(3)H+^(1)and_(2)^(4)He` are respectively , a, b and c (in MeV), then energy (in MeV) released in this reaction is

In the reaction ._1^2 H + ._1^3 H rarr ._2^4 He + ._0^1 n , if the binding energies of ._1^2 H, ._1^3 H and ._2^4 He are respectively a,b and c (in MeV), then the energy (in MeV) released in this reaction is.

In the reaction ._1^2 H + ._1^3 H rarr ._2^4 He + ._0^1 n , if the binding energies of ._1^2 H, ._1^3 H and ._2^4 He are respectively a,b and c (in MeV), then the energy (in MeV) released in this reaction is.

The reaction ._(1)D^(2) + ._(1)T^(3) rarr ._(1)He^(2) + ._(0)n^(1) is an example of

If the binding energy per nucleon in ._(3)Li^(7) and ._(2)He^(4) nuclei are respectively 5.60 MeV and 7.06 MeV, then the ebergy of proton in the reaction ._(3)Li^(7) +p rarr 2 ._(2)He^(4) is

Which of the following statement is not true for ._(1)H^(1),._(1)H^(2),._(1)H^(3) respectively -

The source of energy of stars is nuclear fusion. Fusion reaction occurs at very high temperature, about 10^(7) . Energy released in the process of fusion is due to mass defect. It is also called Q -value. Q = Delta mc^(2), Delta m = mass defect. In a nuclear reaction ._(1)H^(2) + ._(1)H^(2) rarr ._(2)He^(3) + ._(0)n^(1) If the masses of ._(1)H^(2) and ._(2)He^(3) are 2.014741 and 3.016977 amu, respectively. then the Q -value of the reaction is nearly.

The ratio of the radii of the nucleons of ._(2)^(4)He and ._(1)^(1)H is

Complete the following fusion reactions : (a) ""_(2)^(3) He +_(1)^(2) H to_2 He + _1 H + en ergy (b) ""_(1)^(2) He +_(1)^(2) H to_2 He + ^1 n + en ergy

Complete the reation : ""^(3)He_(2)+""^(2)H_(1)to""^(4)He_(2)+......+"Energy"

In the following nuclear reaction, calculate the energy released in MeV : ""_(1)^(2)H+""_(1)^(2)Hto""_(2)^(3)He+""_(0)^(1)n Given that : Mass of ""_(1)^(2)H=2.015u Mass of ""_(2)^(3)He=3.017u Mass of ""_(0)^(1)n=1.009u What is the name of this reaction?