A radio nuclide with disintegration cons...

A radio nuclide with disintegration constant `lambda` is produced in a reactor at a constant rate `alpha` nuclei per second. During each decay energy `E_0` is released. `20%` of this energy is utilized in increasing the temperature of water. Find the increase in temperature of `m` mass of water in time `t`. Specific heat of water is `s`. Assume that there is no loss of energy through water surface.

Text Solution

Verified by Experts

The correct Answer is:

`[(0.2 E_(0)[alpha t-(alpha)/(lambda)(1-e^(-lambdat))])/(ms)]`

Similar Questions

Explore conceptually related problems

A radionuclide with half - life 1620 s is produced in a reactor at a constant rate of 1000 nuclei per second. During each decay energy, 200 MeV is released. If the production of radionuclides started at t = 0, then the rate of release of energy at t = 3240 s is

A radioactive nuclide is produced at a constant rate x nuclei per second. During each decay, E_0 energy is released ,50% of this energy is utilised in melting ice at 0^@ C. Find mass of ice that will melt in one mean life. ( lambda =decay consant, L_f =Latent heat of fusion )

A radionuclide with half life T is produced in a reactor at a constnat rate p nuclei per second. During each decay, energy E_(0) is released. If production of radionuclide is started at t=0, calculate (a) rate of release of energy as a function of time (b) total energy released upto time t

Text Solution

Similar Questions

Recommended Questions