A star initially has `10^40` deuterons. It produces energy via the processes `._1H^2+_1H^2rarr_1H^3+p` and `._1H^2+_1H^3rarr_2He^4+n`. If the average power radiated by the star is `10^16` W, the deuteron supply of the star is exhausted in a time of the order of (a) `10^6s` (b) `10^8s` (c) `10^12s` The masses of the nuclei are as follows `M(H^2)=2.014` amu, `M(n)=1.008` amu, `M(p)=1.007` amu,`M(He^4)=4.001`amuA. `10^6 sec`B. `10^8 sec`C. `10^12 sec`D. `10^16 sec`

A star initially has `10^40` deuterons. It produces energy via the pro

1.	A star initially has `10^40` deuterons. It produces energy via the processes `._1H^2+_1H^2rarr_1H^3+p` and `._1H^2+_1H^3rarr_2He^4+n`. If the average power radiated by the star is `10^16` W, the deuteron supply of the star is exhausted in a time of the order of (a) `10^6s` (b) `10^8s` (c) `10^12s` The masses of the nuclei are as follows `M(H^2)=2.014` amu, `M(n)=1.008` amu, `M(p)=1.007` amu,`M(He^4)=4.001`amuA. `10^6 sec`B. `10^8 sec`C. `10^12 sec`D. `10^16 sec`
Answer» Correct Answer - C ( c) Mass defect `= 3 xx 2.014 - 4.001 - 1.007 - 1.008 = 0.026 amu = 0.026 xx 931 xx 10^6 xx 1.6 xx 10^-19 J` `=3.82 xx 10^-12 J` Power of star `= 10^16 W` Number of deuterons used `= (10^16)/(Delta M) = 0.26 xx 10^28` Deuteron supply exhausts in `(10^40)/(0.26 xx 10^28) = 10^12 s`.

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