Precision measurements of s-wave scattering lengths in a two-component Bose-Einstein condensate

Abstract

We use collective oscillations of a two-component Bose-Einstein condensate (2CBEC) of atoms prepared in the internal states 1F=1, mF=-1 and 2F=2, mF=1 for the precision measurement of the interspecies scattering length a12 with a relative uncertainty of 1.6× 10-4. We show that in a cigar-shaped trap the three-dimensional (3D) dynamics of a component with a small relative population can be conveniently described by a one-dimensional (1D) Schr\"odinger equation for an effective harmonic oscillator. The frequency of the collective oscillations is defined by the axial trap frequency and the ratio a12/a11, where a11 is the intra-species scattering length of a highly populated component 1, and is largely decoupled from the scattering length a22, the total atom number and loss terms. By fitting numerical simulations of the coupled Gross-Pitaevskii equations to the recorded temporal evolution of the axial width we obtain the value a12=98.006(16)\,a0, where a0 is the Bohr radius. Our reported value is in a reasonable agreement with the theoretical prediction a12=98.13(10)\,a0 but deviates significantly from the previously measured value a12=97.66\,a0 Mertes07 which is commonly used in the characterisation of spin dynamics in degenerate atoms. Using Ramsey interferometry of the 2CBEC we measure the scattering length a22=95.44(7)\,a0 which also deviates from the previously reported value a22=95.0\,a0 Mertes07. We characterise two-body losses for the component 2 and obtain the loss coefficients γ12=1.51(18)×10-14 cm3/s and γ22=8.1(3)×10-14 cm3/s.