During negative B decay, an anti- neutrino is also emmited along with the ejected electron. Then

During a negative beta decay,

During a negative beta -decay

During a negative beta decay:

A neutron intially at rest, decays into a proton, an electron and an antineutrio. The ejected electron has a momentum of p_(1) = 1.4× 10^(-28) kg-m/s and the antineutrino p_(2) = 6.5 ×10^(–27) kg-m/s. Find the recoil speed of the proton if the electron and the antineutrino are ejected along the the same direection.

During beta^(-) -decay, a neutron inside nucleus converts into proton, electron and x . Then the paritcle x is

A neutron initially at rest, decays into a proton, an electron and an antineutrino. The ejected electron has a momentum of 1.4xx10^-26 kg.m/s nd the antineutrino 6.4xx10^27 kgm/s. Find the recoil speed of the proton a. if the electron and the antineutrino are ejected along the same directioin and b. if they are ejected along perpendicular directions. Mass of the proton 1.67xx10^-27 kg.

The beta -decay process, discovered around 1900 , is basically the decay of a neutron (n) , In the laboratory, a proton (p) and an electron (e^(-)) are observed as the decay products of the neutron. Therefore, considering the decay of a neutron as a tro-body dcay process, it was observed that the electron kinetic energy has a continuous spectrum. Considering a three-body decay process i.e., n rarr p + e^(-)+overset(-)v_(e ) , around 1930 , Pauli explained the observed electron energy spectrum. Assuming the anti-neutrino (overset(-)V_(e )) to be massless and possessing negligible energy, and neutron to be at rest, momentum and energy conservation principles are applied. From this calculation, the maximum kinetic energy of the electron is 0.8xx10^(6)eV . The kinetic energy carried by the proton is only the recoil energy. What is the maximum energy of the anti-neutrino?