TY - GEN
T1 - Precise measurements of s-wave scattering phase shifts with a juggling atomic clock
AU - Gensemer, Steven
AU - Hart, Russell
AU - Martin, Ross
AU - Xu, Xinye
AU - Legere, Ronald
AU - Gibble, Kurt
AU - Kokkelmans, Servaas
PY - 2009
Y1 - 2009
N2 - We demonstrate an interferometric scattering technique that allows highly precise measurements of s-wave scattering phase shifts. We collide two clouds of cesium atoms in a juggling fountain clock. The atoms in one cloud are prepared in a coherent superposition of the two clock states and the atoms in the other cloud in an F,mF state. After the two clouds collide, we detect the scattered part of the clock atom's wavefunction for which the phase of the clock coherence is shifted by the difference of the s-wave phase shifts. In this way, we unambiguously observe the differences of scattering phase shifts. These phase shifts are independent of the atomic density to lowest order, enabling measurements of scattering phase shifts with clock accuracy. Recently, we have observed the changes in scattering phase shifts as a function of magnetic field over a range where Feshbach resonances may be expected and inelastic scattering channels open and close. Measurements like these will tightly constrain our knowledge of cesium-cesium interactions. With such knowledge, future measurements may place stringent limits on the time variation of fundamental constants, such as the electron-proton mass ratio, by precisely probing phase shifts near a Feshbach resonance.
AB - We demonstrate an interferometric scattering technique that allows highly precise measurements of s-wave scattering phase shifts. We collide two clouds of cesium atoms in a juggling fountain clock. The atoms in one cloud are prepared in a coherent superposition of the two clock states and the atoms in the other cloud in an F,mF state. After the two clouds collide, we detect the scattered part of the clock atom's wavefunction for which the phase of the clock coherence is shifted by the difference of the s-wave phase shifts. In this way, we unambiguously observe the differences of scattering phase shifts. These phase shifts are independent of the atomic density to lowest order, enabling measurements of scattering phase shifts with clock accuracy. Recently, we have observed the changes in scattering phase shifts as a function of magnetic field over a range where Feshbach resonances may be expected and inelastic scattering channels open and close. Measurements like these will tightly constrain our knowledge of cesium-cesium interactions. With such knowledge, future measurements may place stringent limits on the time variation of fundamental constants, such as the electron-proton mass ratio, by precisely probing phase shifts near a Feshbach resonance.
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U2 - 10.1142/9789812838223_0009
DO - 10.1142/9789812838223_0009
M3 - Conference contribution
AN - SCOPUS:84892931910
SN - 981283821X
SN - 9789812838216
T3 - Proceedings of the 7th Symposium on Frequency Standards and Metrology, ISFSM 2008
SP - 91
EP - 99
BT - Proceedings of the 7th Symposium on Frequency Standards and Metrology, ISFSM 2008
PB - World Scientific Publishing Co. Pte Ltd
T2 - 7th Symposium on Frequency Standards and Metrology, ISFSM 2008
Y2 - 5 October 2008 through 11 October 2008
ER -