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Line 3: In [[nuclear physics]], '''ab initio methods''' seek to describe the [[atomic nucleus]] from the ground up by solving the non-relativistic [[Schrödinger equation]] for all constituent [[nucleon]]s and the forces between them. This is a more fundamental approach compared to e.g. the [[nuclear shell model]]. Previously limited to very light nuclei, recent progress has enabled ab initio treatment of heavier nuclei such as [[isotopes of nickel\|nickel]].<ref name=navratil2016>{{cite journal\|first1=P.\|last1=Navrátil\|first2=S.\|last2=Quaglioni\|first3=G.\|last3=Hupin\|first4=C.\|last4=Romero-Redondo\|first5=A.\|last5=Calci\|title=Unified ab initio approaches to nuclear structure and reactions\|journal=Physica Scripta\|volume=91\|issue=5\|pages=053002\|year=2016\|url=http://stacks.iop.org/1402-4896/91/i=5/a=053002\|doi=10.1088/0031-8949/91/5/053002}}</ref> A significant challenge in the ab initio treatment stems from the complexities of the inter-nucleon interaction. The [[nuclear force\|strong nuclear force]] is believed to emerge from the [[strong interaction]] described by [[quantum chromodynamics]] (QCD), but QCD is non-~~pertubative~~perturbative in the low-energy regime relevant to nuclear physics. This makes the direct use of QCD for the description of the inter-nucleon interactions very difficult (see [[lattice QCD]]), and a model must be used instead. The most sophisticated models available are based on [[chiral perturbation theory\|chiral effective field theory]]. This [[effective field theory]] (EFT) includes all interactions compatible with the symmetries of QCD, ordered by the size of their contributions. The degrees of freedom in this theory are nucleons and [[pion]]s, as opposed to [[quark]]s and [[gluon]]s as in QCD. The effective theory contains parameters called low-energy constants, which can be determined from scattering data.<ref name=navratil2016 /><ref name=machleidt2011> {{cite journal \|first=R.

Ab initio methods (nuclear physics): Difference between revisions