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

Calculate the energy released in joules and MeV in the following nuclear reaction: ._(1)H^(2) + ._(1)H^(2) rarr ._(2)He^(3) + ._(0)n^(1) Assume that the masses of ._(1)H^(2) , ._(2)He^(3) , and neutron (n) , respectively, are 2.40, 3.0160, and 1.0087 in amu.

Calcualte the energy released (in joule and MeV ) in the follwing nulcear reaction: ._(1)^(2)H + ._(1)^(2)H rarr ._(2)^(3)He + ._(0)^(1)n Assume that the masses of ._(1)^(2)H, ._(2)^(3)He and neutron (n) are 2.0141,3.0160 and 1.0087 respectively in amu.

Calculate the energy released in joules and MeV in the following nuclear reaction : ._(1)^(2) H+_(1)^(2) rarr _(2)^(3)He + _(0)^(1)n Assume that the masses of ._(1)^(2)H, _(2)^(3)He and neutron (n) respectively are 2.020, 3.0160 and 1.0087 in amu.

Calculate the energy released in the following: ._(1)H^(2) + ._(1)H^(3) rarr ._(2)He^(4) + ._(0)n^(1) (Given masses : H^(2) = 2.014, H^(3) = 3.016, He = 4.003, n = 1.009 m_(u))

A nuclear fusion reaction is given by ._(1)H^(2)+._(1)H^(2)rarr._(1)He^(3)+._(0)^(1)n + Q ("energy") . If 2 moles of deuterium are fused, then total released energy is

Balance the following nuclear reactions: a. ._(3)Li^(7) + ._(0)n^(1) rarr 2 ._(2)He^(4) + ? b. ._(42)Mo^(94) + ._(1)H^(2) rarr ._(0)n^(1) + ?

Assuming that about 20 M eV of energy is released per fusion reaction ._(1)H^(2)+._(1)H^(3)rarr._(0)n^(1)+._(2)He^(4) , the mass of ._(1)H^(2) consumed per day in a future fusion reactor of powder 1 MW would be approximately

The positions of ._(1)^(2)D,._(2)^(4)He and ._(3)^(7)Li are shown on the binding energy curve as shown in figure. The energy released in the fusion reaction. ._(1)^(2)D+._(3)^(7)Li rarr 2 ._(2)^(4)He + ._(0)^(1)n