Q value (nuclear science)

In nuclear physics and chemistry, the $Q$ value for a reaction is the amount of energy absorbed or released during the nuclear reaction. The value relates to the enthalpy of a chemical reaction or the energy of radioactive decay products. It can be determined from the masses of reactants and products. $Q$ values affect reaction rates. In general, the larger the positive $Q$ value for the reaction, the faster the reaction proceeds, and the more likely the reaction is to "favor" the products.

Q=(\,m_{\text{r}}-m_{\text{p}}\,)\times {\text{0.9315 GeV }}

where the masses are in atomic mass units. Also, both $\;m_{\text{r}}\;$ and $\;m_{\text{p}}\;$ are the sums of the reactant and product masses respectively.

Definition[edit]

The conservation of energy, between the initial and final energy of a nuclear process ${\text{( }}E_{\text{i}}=E_{\text{f}}{\text{ ),}}$ enables the general definition of $Q$ based on the mass–energy equivalence. For any radioactive particle decay, the kinetic energy difference will be given by:

Q=K_{\text{f}}-K_{\text{i}}=(\,m_{\text{i}}-m_{\text{f}}\,)\,c^{2}~

where $K$ denotes the kinetic energy of the mass $m$ . A reaction with a positive $Q$ value is exothermic, i.e. has a net release of energy, since the kinetic energy of the final state is greater than the kinetic energy of the initial state. A reaction with a negative $Q$ value is endothermic, i.e. requires a net energy input, since the kinetic energy of the final state is less than the kinetic energy of the initial state.^[1] Observe that a chemical reaction is exothermic when it has a negative enthalpy of reaction, in contrast a positive $Q$ value in a nuclear reaction.

The $Q$ value can also be expressed in terms of the Mass excess $\Delta M$ of the nuclear species as:

Q=\Delta M_{\text{i}}-\Delta M_{\text{f}}~

Proof: The mass of a nucleus can be written as $M=Au+\Delta M,~$ where $A~$ is the mass number (sum of number of protons and neutrons) and $u=^{12}\!\!C/12=931.494$ MeV/c $^{2}~$ . Note that the count of nucleons is conserved in a nuclear reaction. Hence, $A_{f}=A_{i}~$ and $Q=\Delta M_{\text{i}}-\Delta M_{\text{f}}~$ .

Applications[edit]

Chemical $Q$ values are measurement in calorimetry. Exothermic chemical reactions tend to be more spontaneous and can emit light or heat, resulting in runaway feedback(i.e. explosions).

$Q$ values are also featured in particle physics. For example, Sargent's rule states that weak reaction rates are proportional to $Q$ ⁵. The $Q$ value is the kinetic energy released in the decay at rest. For neutron decay, some mass disappears as neutrons convert to a proton, electron and antineutrino:^[2]

Q=(m_{\text{n}}-m_{\text{p}}-m_{\mathrm {\overline {\nu }} }-m_{\text{e}})c^{2}=K_{\text{p}}+K_{\text{e}}+K_{\overline {\nu }}={\text{0.782 MeV  ,}}

where m_n is the mass of the neutron, $m$ _p is the mass of the proton, $m$ _$ν$ is the mass of the electron antineutrino, and $m$ _e is the mass of the electron; and the $K$ are the corresponding kinetic energies. The neutron has no initial kinetic energy since it is at rest. In beta decay, a typical $Q$ is around 1 MeV.

The decay energy is divided among the products in a continuous distribution for more than two products. Measuring this spectrum allows one to find the mass of a product. Experiments are studying emission spectrums to search for neutrinoless decay and neutrino mass; this is the principle of the ongoing KATRIN experiment.

Notes and references[edit]

^ Krane, K.S. (1988). Introductory Nuclear Physics. John Wiley & Sons. p. 381. ISBN 978-0-471-80553-3.
^ Martin, B.R.; Shaw, G. (2007). Particle Physics. John Wiley & Sons. p. 34. ISBN 978-0-471-97285-3.

External links[edit]

"Query input form". Nuclear Structure and Decay Data. IAEA. – interactive query form for $Q$ -value of requested decay.
Schuster, Eugenio (Fall 2020). "Nuclear energy release; fusion reactions" (PDF). Mechanical Engineering 362 – Nuclear Fusion and Radiation. Bethlehem, PA: Lehigh University. ME 362 Lecture 1. Retrieved 5 March 2021. – demonstrates simply the mass-energy equivalence.

[Krane-1] Krane, K.S. (1988). Introductory Nuclear Physics. John Wiley & Sons. p. 381. ISBN 978-0-471-80553-3.

[Martin-2] Martin, B.R.; Shaw, G. (2007). Particle Physics. John Wiley & Sons. p. 34. ISBN 978-0-471-97285-3.

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