Calculate the energy released when three alpha particles combine to form a `_^12 C` nucleus. The atomic mass of `_^4 He` is `4.002603 u`.

Calculate the mass of an alpha-particle.Its binding energy is 28.2 meV.

Three prop -particles ( m_prop = 4.0026) amu are combined to form a C^12 nucleus. The energy released will be

Calculate the binding energy of an alpha particle from the following data: mass of _1^1H atom = 1.007825 u mass of neutron = 1.008665 u mass of _4^2He atom = 4.00260 u Take 1 u = 931 MeV c^(-2)

During alpha-decay , a nucleus decays by emitting an alpha -particle ( a helium nucleus ._2He^4 ) according to the equation ._Z^AX to ._(Z-2)^(A-4)Y+._2^4He+Q In this process, the energy released Q is shared by the emitted alpha -particle and daughter nucleus in the form of kinetic energy . The energy Q is divided in a definite ratio among the alpha -particle and the daughter nucleus . A nucleus that decays spontaneously by emitting an electron or a positron is said to undergo beta -decay .This process also involves a release of definite energy . Initially, the beta -decay was represented as ._Z^AX to ._(Z+1)^AY + e^(-)"(electron)"+Q According to this reaction, the energy released during each decay must be divided in definite ratio by the emitted e' ( beta -particle) and the daughter nucleus. While , in alpha decay, it has been found that every emitted alpha -particle has the same sharply defined kinetic energy. It is not so in case of beta -decay . The energy of emitted electrons or positrons is found to vary between zero to a certain maximum value. Wolfgang Pauli first suggested the existence of neutrinoes in 1930. He suggested that during beta -decay, a third particle is also emitted. It shares energy with the emitted beta particles and thus accounts for the energy distribution. The beta particles (positron) are emitted with different kinetic energies because

During alpha-decay , a nucleus decays by emitting an alpha -particle ( a helium nucleus ._2He^4 ) according to the equation ._Z^AX to ._(Z-2)^(A-4)Y+._2^4He+Q In this process, the energy released Q is shared by the emitted alpha -particle and daughter nucleus in the form of kinetic energy . The energy Q is divided in a definite ratio among the alpha -particle and the daughter nucleus . A nucleus that decays spontaneously by emitting an electron or a positron is said to undergo beta -decay .This process also involves a release of definite energy . Initially, the beta -decay was represented as ._Z^AX to ._(Z+1)^AY + e^(-)"(electron)"+Q According to this reaction, the energy released during each decay must be divided in definite ratio by the emitted e' ( beta -particle) and the daughter nucleus. While , in alpha decay, it has been found that every emitted alpha -particle has the same sharply defined kinetic energy. It is not so in case of beta -decay . The energy of emitted electrons or positrons is found to vary between zero to a certain maximum value. Wolfgang Pauli first suggested the existence of neutrinoes in 1930. He suggested that during beta -decay, a third particle is also emitted. It shares energy with the emitted beta particles and thus accounts for the energy distribution. During beta^+ decay (positron emission) a proton in the nucleus is converted into a neutron, positron and neutrino. The reaction is correctly represented as

Find the energy required to split ._8^16O nucleus into four alpha particles. The mass of an alpha -particle is 4.002603 u and that of oxygen is 15.994915 u.

Find the energy required to split ._(8)^(16)O nucleus into four alpha - particles. The mass of an alpha - particle is 4.002603u and that of oxygen is 15.994915u.

Find the kinetic energy of the alpha - particle emitted in the decay ^238 Pu rarr ^234 U + alpha . The atomic masses needed are as following: ^238 Pu 238.04955 u ^234 U 234.04095 u ^4 He 4.002603 u . Neglect any recoil of the residual nucleus.

Calculate the average energy required to extract a nucleon from the nucleus of an alpha - particle. the mass of 'alpha' -particle , proton and neutron are 4.00150 a.m.u 1.00728 a.m.u and 1.00867 amu respectively .

What is the significance of binding energy per nucleon of a nucleus ? (ii) in a certain star, three alpha particles undergo fusion in a single reaction to form ""_(6)^(12)C nucleus. Calculate the energy released in this reaction in MeV. Given : m(""_(2)^(4)He)=4.002604u and m(""_(6)^(12)C)=12.000000u