Quantum inverse scattering method: Difference between revisions

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Revision as of 03:56, 28 May 2024 edit MateyJ1998 (talk \| contribs) 61 edits m Fixed up a sentence that implies the QISM is also the Algebraic Bethe Ansatz. They are similar but not the same. ← Previous edit		Latest revision as of 19:40, 9 November 2024 edit undo Adamnemecek (talk \| contribs) 102 edits m fix link to correlation function to link to the statmech one Tag: Visual edit
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Line 1: {{expert needed\|1=Physics\|reason=copyedit, create lede\|date=May 2019}}▼ {{Short description\|Method used to solve integrable many-body quantum systems}} {{Multiple issues\| ▲{{expert needed\|1=Physics\|reason=copyedit, create lede\|date=May 2019}} {{Cleanup rewrite\|date=September 2024}} {{More citations needed\|date=September 2024}} }} In [[quantum physics]], the '''quantum inverse scattering method''' (QISM), similar to the closely related '''algebraic Bethe ansatz''', is a method for solving [[integrable system\|integrable model]]s in 1+1 dimensions, introduced by [[Leon Takhtajan]] and [[Ludvig Faddeev\|L. D. Faddeev]] in 1979.<ref>{{cite journal \|last1=Takhtadzhan \|first1=L A \|last2=Faddeev \|first2=Lyudvig D \|title=The Quantum Method of the Inverse Problem and the Heisenberg Xyz Model \|journal=Russian Mathematical Surveys \|date=31 October 1979 \|volume=34 \|issue=5 \|pages=11–68 \|doi=10.1070/RM1979v034n05ABEH003909\|bibcode=1979RuMaS..34...11T }}</ref> Line 10 ⟶ 14: The quantum inverse scattering method relates two different approaches: #the [[Bethe ansatz]], a method of solving integrable quantum models in one space and one time dimension.{{Citation needed\|date=September 2024}} #the [[inverse scattering transform]], a method of solving classical integrable differential equations of the evolutionary type.{{Citation needed\|date=September 2024}} This method led to the formulation of [[quantum group]]s, in particular the [[Yangian]].{{Citation needed\|date=September 2024}} The center of the Yangian, given by the [[quantum determinant]] plays a prominent role in the method.{{Citation needed\|date=September 2024}} An important concept in the [[inverse scattering transform]] is the [[Lax pair\|Lax representation]]. The quantum inverse scattering method starts by the [[quantization (physics)\|quantization]] of the Lax representation and reproduces the results of the Bethe ansatz. In fact, it allows the Bethe ansatz to be written in a new form: the ''algebraic Bethe ansatz''.<ref>See for example lectures by N.A. Slavnov {{arXiv\|1804.07350}}</ref> This led to further progress in the understanding of quantum [[integrable system]]s, such as the [[quantum Heisenberg model]], the quantum [[nonlinear Schrödinger equation]] (also known as the [[Lieb–Liniger model]] or the [[Tonks–Girardeau gas]]) and the [[Hubbard model]].{{Citation needed\|date=September 2024}} The theory of [[~~correlation~~Correlation function (statistical mechanics)\|correlation functions]]s was developed{{when\|date=November 2015}}, relating determinant representations, descriptions by differential equations and the [[Riemann–Hilbert problem]]. Asymptotics of correlation functions which include space, time and temperature dependence were evaluated in 1991.{{Citation needed\|date=September 2024}} Explicit expressions for the higher [[conservation law]]s of the integrable models were obtained in 1989.{{Citation needed\|date=September 2024}} Essential progress was achieved in study of [[ice-type model]]s: the bulk free energy of the six vertex model depends on boundary conditions even in the [[thermodynamic limit]].{{Citation needed\|date=September 2024}} ==Procedure==