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Main Authors: Liu, Yujuan, Song, Ziwen, Lin, Tingting, Tang, Biao, Hao, Aoxing
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.15552
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author Liu, Yujuan
Song, Ziwen
Lin, Tingting
Tang, Biao
Hao, Aoxing
author_facet Liu, Yujuan
Song, Ziwen
Lin, Tingting
Tang, Biao
Hao, Aoxing
contents Laser frequency fluctuation and atomic thermal motion can lead to errors in pulse duration and detuning in cold atom interferometry, thereby reducing measurement stability and fringe contrast. To address this issue, we investigate the use of super-Gaussian pulses, which are characterized by smooth temporal profiles and centralized energy distribution, in the beam-splitting and reflection stages of an atom interferometer. Through numerical simulations, we compare the performance of rectangular, Gaussian, and 2nd- to 10th-order super-Gaussian pulses subject to deviations in pulse duration and detuning. Our results show that both Gaussian and super-Gaussian pulses offer a significant advantage over traditional rectangular pulses, particularly under thermal conditions where velocity spread is prominent. We find that 4th-order pulses achieving up to a 90\% improvement in contrast over rectangular pulses under realistic conditions, and while their peak performance at very low temperatures is comparable to that of Gaussian pulses, they demonstrate enhanced robustness against combined detuning and pulse-length errors. These findings demonstrate that super-Gaussian pulse shaping is an effective method for enhancing the robustness of atom interferometers against errors induced by thermal motion.
format Preprint
id arxiv_https___arxiv_org_abs_2505_15552
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Robust Atom Interferometry with Super-Gaussian Pulses against Thermal Velocity Spread
Liu, Yujuan
Song, Ziwen
Lin, Tingting
Tang, Biao
Hao, Aoxing
Atomic Physics
Laser frequency fluctuation and atomic thermal motion can lead to errors in pulse duration and detuning in cold atom interferometry, thereby reducing measurement stability and fringe contrast. To address this issue, we investigate the use of super-Gaussian pulses, which are characterized by smooth temporal profiles and centralized energy distribution, in the beam-splitting and reflection stages of an atom interferometer. Through numerical simulations, we compare the performance of rectangular, Gaussian, and 2nd- to 10th-order super-Gaussian pulses subject to deviations in pulse duration and detuning. Our results show that both Gaussian and super-Gaussian pulses offer a significant advantage over traditional rectangular pulses, particularly under thermal conditions where velocity spread is prominent. We find that 4th-order pulses achieving up to a 90\% improvement in contrast over rectangular pulses under realistic conditions, and while their peak performance at very low temperatures is comparable to that of Gaussian pulses, they demonstrate enhanced robustness against combined detuning and pulse-length errors. These findings demonstrate that super-Gaussian pulse shaping is an effective method for enhancing the robustness of atom interferometers against errors induced by thermal motion.
title Robust Atom Interferometry with Super-Gaussian Pulses against Thermal Velocity Spread
topic Atomic Physics
url https://arxiv.org/abs/2505.15552