The masses of `^11C` and `^11B` are respectively 11.0114 u and 11.0093 u.Find the maximum energy a position can have in the `beta^+`-decay of `^11C` to `^11B`.

Write nuclear reaction equations for- beta^+ - decay of "_6^11C

Write the nuclear reaction for beta^+ decay of _6^11C

Boron has two stable isotopes "_5^10B and "_5^11B . There respective masses are 10.01294 u and 11.00931 u and the atomic mass of boron is 10.811 u. Find the abundances of "_5^10B and "_5^11B .

Boron has two stable isotopes, "_5^10B and "_5^11B . Their respective masses are 10.01294 u and 11.00931 u, and the atomic mass of boron is 10.811 u. Find the abundances of "_5^10B and "_5^11B .

Broron has two stable isotopes, ._(5)^(10)B and ._(5)^(11)B . Their respective masses are 10.01294 u and 11.00931 u, and the atomic mass of boron is 10.811 u. Find the abundances of ._(5)^(10)B and ._(5)^(11)B .

The radionuclide "^11C decays according to "_6^11C rarr "_5^11B + e^+ + v : T_(1/2) = 20.3 min .The maximum energy of the emitted positron is 0.960 MeV. Given the mass values: m ( "_6^11C ) = 11.011434 u and m ( "_6^11B ) = 11.009305 u, calculate Q and compare it with the maximum energy of the positron emitted.

Write the nuclear reaction equations for alpha decay of 88^226Ra and beta^+ decay of 6^11C .

The radionuclide ""^(11)C decays according to ""_(6)^(11)C to ""_(5)^(11)B + e^(+) + upsilon, T_(1//2) = 20.3 min The maximum energy of the emitted positron is 0.960 MeV. Given the mass values: m(""_6^11C) = 11.011434 u and m(""_6^11B) = 11.009305u . Calculate Q and compare it with the maximum energy of the positron emitted.