The isotope `_(5)^(12) B` having a mass `12.014 u`undergoes beta - decay to `_(6)^(12) C _(6)^(12) C `has an excited state of the nucleus `( _(6)^(12) C ^(**) at 4.041 MeV` above its ground state if `_(5)^(12)E` decay to `_(6)^(12) C ^(**) ` , the maximum kinetic energy of the `beta` - particle in unit of MeV is `(1 u = 931.5MeV//c^(2)` where c is the speed of light in vaccuum) .A. `9`B. `6`C. `3`D. `1`

The isotope `_(5)^(12) B` having a mass `12.014 u`undergoes beta - dec

1.	The isotope `_(5)^(12) B` having a mass `12.014 u`undergoes beta - decay to `_(6)^(12) C _(6)^(12) C `has an excited state of the nucleus `( _(6)^(12) C ^() at 4.041 MeV` above its ground state if `_(5)^(12)E` decay to `_(6)^(12) C ^() ` , the maximum kinetic energy of the `beta` - particle in unit of MeV is `(1 u = 931.5MeV//c^(2)` where c is the speed of light in vaccuum) .A. `9`B. `6`C. `3`D. `1`
Answer» Correct Answer - A `._(5)B^(12)to._(6)C^(12)+._(-1)e^(0)+barv` Taking mass of `c^(12)` as 12.000u, mass defect `Deltam=12.014-12.000=0.014u` `Q=0.014xx931.5MeV =13.041 MeV` Out of this, 4.041MeV energy is taken by `._(6)C^(12**)` `:.` Max. K.E. of `beta` particle=13.041-4.041 `=9MeV`

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