Calculate the energy of the following nuclear reaction:
`._(1)H^(2)+._(1)H^(3) to ._(2)He^(4) + ._(0)n^(1)+Q`
Given: `m(._(1)H^(2))=2.014102u, m(._(1)H^(3))=3.016049u, m(._(2)He^(4))=4.002603u, m(._(0)n^(1))=1.008665u`

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))

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))

Calculate the Q - value of the reaction ._(1)H^(2)+._(1)H^(2) rarr ._(1)H^(3)+._(1)H^(1) m(._(1)H^(2))=2.014103 "amu" m(._(1)H^(3))=3.016049 "amu" m(._(1H^(1))=1.007825 amu

Calculate the energy released in the following nuclear reaction: ""_(1)^(2)H+ ""_(1)^(2)H =""_(2)^(4)He Mass of ""_(1)^(2)H = 2.01419u, Mass of ""_(2)^(4)He =4.00277u

Estimate the amount of energy released in the nuclear fusion reaction: _(1)H^(2)+._(1)H^(2)rarr._(2)He^(2)+._(0)n^(1) Given that M(._(1)H^(2))=2.0141u, M(._(2)He^(3))=3.0160u m_(n)=1.0087u , where 1u=1.661xx10^(-27)kg . Express your answer in units of MeV.

The Q value of a nuclear reaction A+b to C+d is defined by Q=[m_(A)+m_(b)-m_(C )-m_(d)]c^(2) where the masses refer to the respective nuclei. Determine from the given data the Q-value of the following reactions and state whether the reactions are exothermic or endothermic. ._(1)^(1)H+ ._(1)^(3)H to ._(1)^(2)H+._(1)^(2) Atomic masses are given to be m(._(1)^(2)H)=2.014102 u m(._(1)^(3)H)=3.016049 u m(._(6)^(12)C)=12.000000 u m(._(10)^(20)Ne)=19.992439 u