[" 27) A mucless with mass number "],[qquad [A=240" and "B*E/A=7*6" Mev breake "],[" cinto two feagmonts each of "A=120],[" With B.E/A = "8.5Mev" .Colculate the "],[" leeleased lenesger."]]

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 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) 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 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

The binding anergy per nucleon is 8.5 MeV for A=120 and is 7.6 MeV for A=240 (see in figure). Suppose a nucleus with A=240 breaks into two nuclei of nearly equal mass numbers. Calculate the energy released in the process.

The binding anergy per nucleon is 8.5 MeV for A=120 and is 7.6 MeV for A=240 (see in figure). Suppose a nucleus with A=240 breaks into two nuclei of nearly equal mass numbers. Calculate the energy released in the process.