Saved in:
Bibliographic Details
Main Authors: Yin, Guoling, Lai, Chi-Kin, Chang, Nana, Liang, Yi, Mao, Dekai, Zhou, Xiaoji
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.14677
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917595738800128
author Yin, Guoling
Lai, Chi-Kin
Chang, Nana
Liang, Yi
Mao, Dekai
Zhou, Xiaoji
author_facet Yin, Guoling
Lai, Chi-Kin
Chang, Nana
Liang, Yi
Mao, Dekai
Zhou, Xiaoji
contents Advancements in the experimental toolbox of cold atoms have enabled the meticulous control of atomic Bloch oscillation within optical lattices, thereby enhancing the capabilities of gravity interferometers. This work delves into the impact of thermal effects on Bloch oscillation in 1D accelerated optical lattices aligned with gravity by varying the system's initial temperature. Through the application of Raman cooling, we effectively reduce the longitudinal thermal effect, stabilizing the longitudinal coherence length over the timescale of its lifetime. The atomic losses over multiple Bloch oscillation is measured, which are primarily attributed to transverse excitation. Furthermore, we identify two distinct inverse scaling behaviors in the oscillation lifetime scaled by the corresponding density with respect to temperatures, implying diverse equilibrium processes within or outside the Bose-Einstein condensate regime. The competition between the system's coherence and atomic density leads to a relatively smooth variation in the actual lifetime versus temperature. Our findings provide valuable insights into the interaction between thermal effects and Bloch oscillation, offering avenues for the refinement of quantum measurement technologies.
format Preprint
id arxiv_https___arxiv_org_abs_2402_14677
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Influence of thermal effects on atomic Bloch oscillation
Yin, Guoling
Lai, Chi-Kin
Chang, Nana
Liang, Yi
Mao, Dekai
Zhou, Xiaoji
Quantum Gases
Advancements in the experimental toolbox of cold atoms have enabled the meticulous control of atomic Bloch oscillation within optical lattices, thereby enhancing the capabilities of gravity interferometers. This work delves into the impact of thermal effects on Bloch oscillation in 1D accelerated optical lattices aligned with gravity by varying the system's initial temperature. Through the application of Raman cooling, we effectively reduce the longitudinal thermal effect, stabilizing the longitudinal coherence length over the timescale of its lifetime. The atomic losses over multiple Bloch oscillation is measured, which are primarily attributed to transverse excitation. Furthermore, we identify two distinct inverse scaling behaviors in the oscillation lifetime scaled by the corresponding density with respect to temperatures, implying diverse equilibrium processes within or outside the Bose-Einstein condensate regime. The competition between the system's coherence and atomic density leads to a relatively smooth variation in the actual lifetime versus temperature. Our findings provide valuable insights into the interaction between thermal effects and Bloch oscillation, offering avenues for the refinement of quantum measurement technologies.
title Influence of thermal effects on atomic Bloch oscillation
topic Quantum Gases
url https://arxiv.org/abs/2402.14677