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Main Authors: Wang, Jia, Hu, Hui, Liu, Xia-Ji
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.01233
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author Wang, Jia
Hu, Hui
Liu, Xia-Ji
author_facet Wang, Jia
Hu, Hui
Liu, Xia-Ji
contents We present a comprehensive analysis of four-body scattering in one-dimensional (1D) quantum systems using the adiabatic hyperspherical representation (AHR). Focusing on dimer-dimer collisions between two species of fermions interacting via the sinh-cosh potential, we implement the slow variable discretization (SVD) method to overcome numerical challenges posed by sharp avoided crossings in the potential curves. Our numerical approach is benchmarked against exact analytical results available in integrable regimes, demonstrating excellent agreement. We further explore non-integrable regimes where no analytical solutions exist, revealing novel features such as resonant enhancement of the scattering length associated with tetramer formation. These results highlight the power and flexibility of the AHR+SVD framework for accurate few-body scattering calculations in low-dimensional quantum systems, and establish a foundation for future investigations of universal few-body physics in ultracold gases.
format Preprint
id arxiv_https___arxiv_org_abs_2506_01233
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Hyperspherical Analysis of Dimer-Dimer Scattering in One-Dimensional Systems
Wang, Jia
Hu, Hui
Liu, Xia-Ji
Quantum Gases
Atomic Physics
Quantum Physics
We present a comprehensive analysis of four-body scattering in one-dimensional (1D) quantum systems using the adiabatic hyperspherical representation (AHR). Focusing on dimer-dimer collisions between two species of fermions interacting via the sinh-cosh potential, we implement the slow variable discretization (SVD) method to overcome numerical challenges posed by sharp avoided crossings in the potential curves. Our numerical approach is benchmarked against exact analytical results available in integrable regimes, demonstrating excellent agreement. We further explore non-integrable regimes where no analytical solutions exist, revealing novel features such as resonant enhancement of the scattering length associated with tetramer formation. These results highlight the power and flexibility of the AHR+SVD framework for accurate few-body scattering calculations in low-dimensional quantum systems, and establish a foundation for future investigations of universal few-body physics in ultracold gases.
title Hyperspherical Analysis of Dimer-Dimer Scattering in One-Dimensional Systems
topic Quantum Gases
Atomic Physics
Quantum Physics
url https://arxiv.org/abs/2506.01233