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Main Author: Lin, Xincheng
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2304.06172
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author Lin, Xincheng
author_facet Lin, Xincheng
contents Four-body systems are studied using an effective field theory with two- and three-body contact interactions. A method to systematically address deep trimers (three-body bound states that are more tightly bound than four-body bound/resonant states) in four-body calculations is developed using a diagrammatic approach. Previous calculations were limited by the existence of deep trimers, which this work overcomes. For cold $^4$He atoms, binding energies of 526.1(5)~mK and 128.517(1)~mK are obtained at leading order for the tetramer ground and excited states, respectively, where errors come from the truncation of three-body partial waves. Tetramer binding energies and decay widths are also computed approaching the unitary limit. In the unitary limit, there are two tetramers associated with each trimer of binding energy $B_3^{(0)}$. The binding energy and decay width for the associated tetramer ground state are $E_4^{(0)} = 4.60(1)B_3^{(0)}$ and $Γ_4^{(0)}/2 = 0.0160(1)B_3^{(0)}$, respectively, and for the associated tetramer excited state, $E_4^{(1)} = 1.0022(3)B_3^{(0)}$ and $Γ_4^{(1)}/2 = 2.57(2)\times 10^{-4}B_3^{(0)}$, respectively. This calculation is a gateway to higher-order and/or more-body calculations in nuclear and atomic systems.
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publishDate 2023
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spellingShingle Four-Body Systems at Large Cutoffs in Effective Field Theory
Lin, Xincheng
Nuclear Theory
Four-body systems are studied using an effective field theory with two- and three-body contact interactions. A method to systematically address deep trimers (three-body bound states that are more tightly bound than four-body bound/resonant states) in four-body calculations is developed using a diagrammatic approach. Previous calculations were limited by the existence of deep trimers, which this work overcomes. For cold $^4$He atoms, binding energies of 526.1(5)~mK and 128.517(1)~mK are obtained at leading order for the tetramer ground and excited states, respectively, where errors come from the truncation of three-body partial waves. Tetramer binding energies and decay widths are also computed approaching the unitary limit. In the unitary limit, there are two tetramers associated with each trimer of binding energy $B_3^{(0)}$. The binding energy and decay width for the associated tetramer ground state are $E_4^{(0)} = 4.60(1)B_3^{(0)}$ and $Γ_4^{(0)}/2 = 0.0160(1)B_3^{(0)}$, respectively, and for the associated tetramer excited state, $E_4^{(1)} = 1.0022(3)B_3^{(0)}$ and $Γ_4^{(1)}/2 = 2.57(2)\times 10^{-4}B_3^{(0)}$, respectively. This calculation is a gateway to higher-order and/or more-body calculations in nuclear and atomic systems.
title Four-Body Systems at Large Cutoffs in Effective Field Theory
topic Nuclear Theory
url https://arxiv.org/abs/2304.06172