A nucleus with mass number A =240 and BE`//`A = 7.6 Me V breaks into two fragments each of A =120 with `BE//A ` =8.5 Me V .Calculate the released energy .

A nucleus with mass number 240 breaks into two fragments each of mass number 120, the binding energy per nucleon of unfragmented nuclei is 7.6 MeV while that of fragments is 8.5 MeV. The total gain in the binding energy in the process is:

A heavy nucleus X of mass number 240 and binding energy per nucleon 7.6 MeV is split into two fragments Y and Z of mass numbers 110 and 130. The binding energy of nucleons in Y and Z is 8.5MeV per nucleon. Calculate the energy Q released per fission in MeV.

(a) Draw a graph showing the variation of binding energy per nucleon (BE/A) vs mass number A for the nuclei in 20 le A le 170 . (b) A nucleus of mass number 240 and having binding energy/nucleon 7.6 MeV splits into two fragments Y, Z of mass numbers 110 and 130 respectively. If the binding energy/nucleon of Y, Z is equal to 8.5 MeV each, calculate the energy released in the nuclear reaction

A nucleus with mass number 184 initially at rest emits an alpha particle. If the Q value of the reaction is 5.5 MeV, calculate the kinetic energy of the energy of the alpha particle

A torch bulb of 3 V draws a current of 0.4 A . If the bulb is switched on for 5 minutes, calculate the energy released by the bulb.

Assume that the nuclear binding energy per nucleon (B//A) versus mass number (A) is as shown in figure. Use this plot to choose the correct choice(s) given below. (a) Fusion of two nuclei with mass numbers, lying in the range of 1ltAlt50 will release energy. Fusion of two nuclei with mass numbers lying in the range of 51ltAlt100 will release energy. (c) Fission of a nucleus lying in the mass range of 100ltAlt200 will release energy when broken into two equal fragements. (d) Fission of a nucleus lying in the mass range of 200ltAlt260 will release energy when broken into two equal fragments.