Symmetry energy: Difference between revisions

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In nuclear physics, the symmetry energy reflects the variation of the binding energy of the nucleons in the nuclear matter depending on its neutron to proton ratio as a function of baryon density. Symmetry energy is an important parameter in the equation of state describing the nuclear structure of heavy nuclei and neutron stars.^[1][2][3][4]

Let ${\displaystyle n_p}$ and ${\displaystyle n_n}$ be the number density of protons and neutrons in nuclear matter, and ${\displaystyle n=n_p+n_n}$. Let ${\displaystyle E_0(n)}$ be the binding energy per nucleon in symmetric matter, with equally many protons as neutrons, as a function of density. The binding energy per nucleon ${\displaystyle E}$ of non-symmetric matter is then a function that also depends on the isospin asymmetry,

${\displaystyle \delta =\frac{n_p-n_n}{n}}$

so to lowest order the energy per baryon is

${\displaystyle E(n,\delta )=E_0(n)+S(n){\delta }^2+O({\delta }^4),}$

where ${\displaystyle S}$ is the symmetry energy.^[2] There are no odd powers of ${\displaystyle \delta }$ in the expansion because the nuclear force acts the same between two protons as between two neutrons.^[5] At saturation density ${\displaystyle n_0}$, the symmetry energy is Template:Val.^[4]

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