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`, then the energy released 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

The binding energy of deuteron is 2.2 MeV and that of ._2^4 He is 28 MeV . If two deutrons are fused to form one ._2^4 He , then the energy released is

The binding energy per nucleon of deuterium and helium atom is 1.1 MeV and 7.0 MeV . If two deuterium nuclei fuse to form helium atom, the energy released is.

If the binding energy of the deuterium is 2.23 MeV . The mass defect given in a.m.u. is.

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. The binding energy per nucleon of ._(1)H^(2) and ._(2)He^(4) are 1.1 MeV and 7 MeV , respectively. If two deuteron nuclei react to form a single helium nucleus, then the energy released is

The binding energy per nucleon of deuterium and helium nuclei are 1.1 MeV and 7.0 MeV respectively. When two deuterium nuclei fuse to form a helium nucleus the energy released in the fusion is

The binding energy of deuteron ._1^2 H is 1.112 MeV per nucleon and an alpha- particle ._2^4 He has a binding energy of 7.047 MeV per nucleon. Then in the fusion reaction ._1^2H + ._1^2h rarr ._2^4 He + Q , the energy Q released is.