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Exact Analysis of an Interacting Bose Gas. I. The General Solution and the Ground State
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Citations
3
References
1963
Year
Quantum DynamicEngineeringMany-body Quantum PhysicPotential TheoryUltracold AtomRepulsive Delta-function PotentialQuantum TheoryGeneral SolutionQuantum SciencePhysicsQuantum Field TheoryAtomic PhysicsQuantum ChemistryBose-einstein CondensationGross-pitaevskii EquationDouble SpectrumNatural SciencesInteracting Bose GasCondensed Matter PhysicsGround StateOne-dimensional Bose ParticlesMany-body Problem
The model involves a single nontrivial coupling constant, γ. The study aims to compute the ground‑state energy as a function of γ, demonstrate its analyticity except at γ=0, and characterize the excitation spectrum as a double spectrum. The authors perform an explicit calculation of the ground‑state energy across all γ values. The one‑dimensional Bose gas with repulsive δ‑function interaction is solved exactly; eigenfunctions and energies are obtained explicitly, Bogoliubov theory holds for small γ, and the excitation spectrum is best described as a double spectrum.
A gas of one-dimensional Bose particles interacting via a repulsive delta-function potential has been solved exactly. All the eigenfunctions can be found explicitly and the energies are given by the solutions of a transcendental equation. The problem has one nontrivial coupling constant, $\ensuremath{\gamma}$. When $\ensuremath{\gamma}$ is small, Bogoliubov's perturbation theory is seen to be valid. In this paper, we explicitly calculate the ground-state energy as a function of $\ensuremath{\gamma}$ and show that it is analytic for all $\ensuremath{\gamma}$, except $\ensuremath{\gamma}=0$. In Part II, we discuss the excitation spectrum and show that it is most convenient to regard it as a double spectrum---not one as is ordinarily supposed.
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