`""_(83)^(212)Bi` decays as per following equation.
`""_(83)^(212)Birarr""_(82)^(208)TI+""_(2)^(4)He.` The kinetic energy of a-particle emitted is 6.802 MeV. Calculate the kinetic energy of TI recoil atoms.

Neon -23 decays in the following way ""_(10)^(23)Nerarr""_(11)^(23)Ne+""_(-1)e^0+barv. Find the minimum and maximum kinetic energy that the beta particle (""_(-1)e^(0)) can have . The atomic masses of ""^(23)Ne and ""^(23)Na are 22.9945 u and 22.9898 u, respectively.

1 mole of gas A and 1 mole of gas B at 27^@C were pumped into a 24.6 L. volume pre-evacuated isolated flask. The catalyst coated inside the flask catalyses the following reaction A(g) + B(g) to 2D (g) . The kinetic energy of D is 98.03 L atm. Calculate the pressure realised at the end of the reaction.

A nucleus with mass number 220 initially at rest emits an alpha -particle. If the Q value of the reaction is 5.5MeV, calculate the kinetic energy of the alpha -particle.

The radionuclide ""^(11)C decays according to ""_(6)^(11)C to ""_(5)^(11) B + e^(+) + v, T_(1//2) = 20.3 min The maximum energy of the emitted positron is 0.960 MeV. Given the mass values: m ( ""_(6)^(11)C) = 11.011434 u and m (""_(6)^(11)B ) = 11.009305 u, calculate Q and compare it with the maximum energy of the positron emitted.

Under certain circumstances, a nucleus can decay by emitting a particle more massive than an a-particle. Consider the following decay processes: ""_(88)^(223)Ra to ""(82)^(209)Pb + ""_(6)^(14)C . ""_(88)^(223)Ra to ""_(86)^(219)Rn + ""_(2)^(4)He Calculate the Q-values for these decays and determine that both are energetically allowed.