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`

How long can an electric lamp of 100W be kept glowing by fusion of 2.0 kg of deuterium? Take the fusion reaction as ""_(1)^(2)H + ""_(1)^(2)H to ""_(2)^(3)He + n + 3.27 MeV .

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

The binding energy of deuteron is 2.2 MeV and that of ._(2)^(4)He is 28 MeV. If two deuterons are fused to form one ._(2)^(4)He , th n the energy released is

Consider the D–T reaction (deuterium–tritium fusion) ""_(1)^(2)H + ""_(1)^(3)H to ""_(2)^(4)He + n (a) Calculate the energy released in MeV in this reaction from the data: m (""_(1)^(2)H) = 2.014102u m(""_1^(3)H) = 3.016049 u (b) Consider the radius of both deuterium and tritium to be pproximately 2.0 fm. What is the kinetic energy needed to overcome the coulomb repulsion between the two nuclei? To what temperature must the gas be heated to initiate the reaction? (Hint: Kinetic energy required for one fusion event =average thermal kinetic energy available with the interacting particles = 2(3kT/2), k = Boltzman’s constant, T = absolute temperature.)

Which of the following relations are functions? Give reason {(3,3) (4,2) (5,1) (6,0) (7,7)}

In the nuclear fusion reaction _(1)^(2)H + _(1)^(3)H rarr _(2)^(4)He + n given that the repulsive potential energy between the two nuclei is - 7.7 xx 10^(-14) J , the temperature at which the gases must be heated the reaction is nearly [Boltzmann's constant k = 1.38 xx 10^(-23) J//K]

Define an inductor. Derive equation of energy U=1/2LI^2 stored in inductor.

The slope of graph as shown in figure at points 1,2 and 3 is m_(1), m_(2) and m_(3) respectively then