Electronic Population Reconstruction from Strong-Field-Modified Absorption Spectra with a Convolutional Neural Network

Optics Pub Date : 2024-02-26 DOI:10.3390/opt5010007
Daniel Richter, A. Magunia, M. Rebholz, Christian Ott, T. Pfeifer
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引用次数: 0

Abstract

We simulate ultrafast electronic transitions in an atom and corresponding absorption line changes with a numerical, few-level model, similar to previous work. In addition, a convolutional neural network (CNN) is employed for the first time to predict electronic state populations based on the simulated modifications of the absorption lines. We utilize a two-level and four-level system, as well as a variety of laser-pulse peak intensities and detunings, to account for different common scenarios of light–matter interaction. As a first step towards the use of CNNs for experimental absorption data in the future, we apply two different noise levels to the simulated input absorption data.
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利用卷积神经网络从强场修正吸收光谱重构电子种群
我们利用数值少级模型模拟了原子中的超快电子跃迁以及相应的吸收线变化,这与之前的工作类似。此外,我们还首次采用了卷积神经网络(CNN),根据模拟的吸收线变化预测电子状态群。我们利用两级和四级系统,以及各种激光脉冲峰值强度和失谐,来解释光与物质相互作用的不同常见情况。作为未来将 CNN 用于实验吸收数据的第一步,我们对模拟输入吸收数据应用了两种不同的噪声水平。
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Optics
Optics
CiteScore
2.20
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0.00%
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