High precision in a Fourier-transform spectrum of protactinium: extensive weighted least-squares fits of peak wavenumbers for analysis of fine and hyperfine structure

IF 1.5 4区 物理与天体物理 Q3 OPTICS
Sophie Kröger
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引用次数: 0

Abstract

A Fourier-transform recording of protactinium in the infrared range is reanalysed with high precision in order to determine the hyperfine interaction constants A and B. Starting with a selection of best lines and least-squares fits of hyperfine structure intervals, large systems of linear equations compare experimental hyperfine peak wavenumbers with a theoretical representation. The theoretical representation is based on Ritz’s combination principle and Casimir’s formula according to the existing classification. Weighted least-squares fits allow a discrimination between unperturbed and perturbed data such as blended hyperfine structure components. For the first time, the wavenumbers of the hyperfine components of more than 600 lines are fitted using the characteristics of about 250 levels as parameters. When adding adjustable wavenumber-scale correction parameters, global consistency for the whole IR spectrum is obtained with local limits of about \(0.3\,\times 10^{-3}\) cm\(^{-1}\). This demonstrates the high precision in both recording and analysis. The values of the fine structure energies are revised. Standard errors around 0.1 \(\times 10^{-3}\) cm\(^{-1}\) for the A constants and 10\(^{-3}\) cm\(^{-1}\) for the B constants and the fine structure energies are achieved. Representative examples illustrate extensive results obtained for atomic protactinium. This high precision facilitates further search for new energy levels, and 20 new levels were presented. Foreword The data presented here are the results of a study carried out at the Laboratoire Aimé Cotton (LAC) at Paris-Orsay in the years 2003 and 2004, when I was there for a research stay. At this time, I worked together with Jean-François Wyart and Annie Ginibre on the re-examination of protactinium spectra that have been measured about 30 years earlier and that were available in the form of a printed list of peak wavenumbers and a printed paper chart of the intensity profile. The spectra had already been analysed, but there was still a lot of additional information that could be extracted from the spectra with time and effort. The review of the data, the selection of the data and the step-by-step optimization of the data set took a lot of time. When I returned to Berlin in 2004, we had made good progress, but in principle, it is like a bottomless pit. We continued together to optimize the data and tried to the finishing touches to it. At some point, we decided that we had reached a ‘level of maturity’ where the data could be published. We have discussed a lot about how detailed the text should be. This discussion has dragged on over the years and this project has repeatedly been lost in the stream of other everyday tasks. Every now and then there was a small attempt to return to this topic, but it quickly got lost in the daily hustle and bustle. In 2012, we presented the results at a conference. The death of both of them within two years hit me hard. I very much regret that this work was not published earlier. This special volume was the right motivation for me to finally publish this data. I no longer have access neither to the computer programs used at the time, which ran on large computer systems, nor to the original measurement data. I have not been able to find out what happened to the large quantity of paper (printed list of peak wavenumbers anda printed paper chart of spectra). But I have a bunch of input and output files of the calculations that have become a bit jumbled over the years, which contain a lot of information, as well as our unfinished manuscript. The resulting data contain important information for posterity – particularly since the element is radioactive and the experiments to collect laboratory data are unlikely to be repeated any time soon. I think it is worth publishing these data.

High precision FT spectra of Pa: analysis of fine and hyperfine structure

Abstract Image

镤的傅立叶变换光谱的高精度:用于分析精细和超精细结构的峰值文数的广泛加权最小二乘法拟合
摘要 为了确定超正弦相互作用常数 A 和 B,对质子在红外范围内的傅立叶变换记录进行了高精度的重新分析。根据现有的分类,理论表示是基于里兹组合原理和卡西米尔公式。加权最小二乘法拟合可以区分未扰动数据和扰动数据,如混合超正弦结构成分。首次使用大约 250 个层次的特征作为参数,拟合了 600 多条谱线的超正弦成分的文波数。当添加可调节的文波数尺度校正参数时,整个红外光谱获得了全局一致性,局部极限约为\(0.3\,\times 10^{-3}\) cm\(^{-1}) 。这表明记录和分析的精度都很高。精细结构能量的值是经过修正的。A 常量的标准误差约为 0.1 (乘以 10^{-3}\) cm\(^{-1}\) ,B 常量和精细结构能的标准误差约为 10\(^{-3}\) cm\(^{-1}\) 。有代表性的例子说明了原子镤的广泛结果。这种高精度有助于进一步寻找新能级,并提出了 20 个新能级。前言 本文介绍的数据是我于 2003 年和 2004 年在巴黎奥赛艾梅-科顿实验室(LAC)进行研究的结果。当时,我与让-弗朗索瓦-怀亚特(Jean-François Wyart)和安妮-吉尼布雷(Annie Ginibre)合作,对大约 30 年前测量的镤化物光谱进行了重新研究。虽然已经对光谱进行了分析,但仍有许多额外的信息可以通过花费时间和精力从光谱中提取出来。审查数据、选择数据和逐步优化数据集花费了大量时间。2004 年我回到柏林时,我们已经取得了不错的进展,但原则上,这就像一个无底洞。我们继续一起优化数据,并试图对其进行收尾工作。在某个阶段,我们认为我们已经达到了可以公布数据的 "成熟度"。我们就文本的详细程度进行了多次讨论。这种讨论拖了好几年,这个项目也一再被其他日常工作淹没。时不时地,我们会尝试回到这个话题,但很快就会被日常的喧嚣所淹没。2012 年,我们在一次会议上展示了研究成果。他们两人在两年内相继去世,这对我打击很大。我非常遗憾这项工作未能尽早出版。这本特辑是我最终发表这些数据的正确动力。我现在既无法获得当时在大型计算机系统上运行的计算机程序,也无法获得原始测量数据。我也无法找到大量的纸张(峰值波数的打印列表和光谱的打印纸质图表)的去向。但我有一堆计算的输入和输出文件,这些文件多年来已变得有些杂乱,其中包含大量信息,还有我们未完成的手稿。由此产生的数据包含了对后人很重要的信息--尤其是因为该元素具有放射性,而收集实验室数据的实验在短期内不太可能重复。我认为值得公布这些数据。图文摘要Pa 的高精度傅立叶变换光谱:精细和超精细结构分析
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来源期刊
The European Physical Journal D
The European Physical Journal D 物理-物理:原子、分子和化学物理
CiteScore
3.10
自引率
11.10%
发文量
213
审稿时长
3 months
期刊介绍: The European Physical Journal D (EPJ D) presents new and original research results in: Atomic Physics; Molecular Physics and Chemical Physics; Atomic and Molecular Collisions; Clusters and Nanostructures; Plasma Physics; Laser Cooling and Quantum Gas; Nonlinear Dynamics; Optical Physics; Quantum Optics and Quantum Information; Ultraintense and Ultrashort Laser Fields. The range of topics covered in these areas is extensive, from Molecular Interaction and Reactivity to Spectroscopy and Thermodynamics of Clusters, from Atomic Optics to Bose-Einstein Condensation to Femtochemistry.
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