High-energy interference-free K-lines synchrotron X-ray fluorescence microscopy of rare earth elements in hyperaccumulator plants.

IF 2.9 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Metallomics Pub Date : 2023-09-05 DOI:10.1093/mtomcs/mfad050
Antony van der Ent, Dennis Brueckner, Kathryn M Spiers, Ken Vidar Falch, Gerald Falkenberg, Clément Layet, Wen-Shen Liu, Hong-Xiang Zheng, Marie Le Jean, Damien Blaudez
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Abstract

Synchrotron-based micro-X-ray fluorescence analysis (µXRF) is a nondestructive and highly sensitive technique. However, element mapping of rare earth elements (REEs) under standard conditions requires care, since energy-dispersive detectors are not able to differentiate accurately between REEs L-shell X-ray emission lines overlapping with K-shell X-ray emission lines of common transition elements of high concentrations. We aim to test REE element mapping with high-energy interference-free excitation of the REE K-lines on hyperaccumulator plant tissues and compare with measurements with REE L-shell excitation at the microprobe experiment of beamline P06 (PETRA III, DESY). A combination of compound refractive lens optics (CRLs) was used to obtain a micrometer-sized focused incident beam with an energy of 44 keV and an extra-thick silicon drift detector optimized for high-energy X-ray detection to detect the K-lines of yttrium (Y), lanthanum (La), cerium (Ce), praseodymium (Pr), and neodymium (Nd) without any interferences due to line overlaps. High-energy excitation from La to Nd in the hyperaccumulator organs was successful but compared to L-line excitation less efficient and therefore slow (∼10-fold slower than similar maps at lower incident energy) due to lower flux and detection efficiency. However, REE K-lines do not suffer significantly from self-absorption, which makes XRF tomography of millimeter-sized frozen-hydrated plant samples possible. The K-line excitation of REEs at the P06 CRL setup has scope for application in samples that are particularly prone to REE interfering elements, such as soil samples with high concomitant Ti, Cr, Fe, Mn, and Ni concentrations.

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超积累植物中稀土元素的高能无干扰K线同步辐射X射线荧光显微镜。
基于同步加速器的微X射线荧光分析(µXRF)是一种无损且高灵敏度的技术。然而,在标准条件下绘制稀土元素(REE)的元素图谱需要小心,因为能量色散探测器无法准确区分与常见高浓度过渡元素的K壳层X射线发射线重叠的稀土元素L壳层X射线辐射线。我们的目的是测试超积累植物组织上REE K线的高能无干扰激发的REE元素图谱,并与P06(PETRA III,DESY)微探针实验中REE L壳层激发的测量结果进行比较。使用复合折射透镜光学器件(CRLs)的组合来获得具有44keV能量的微米大小的聚焦入射光束和针对高能X射线检测而优化的超厚硅漂移检测器,以检测钇(Y)、镧(La)、铈(Ce)、镨(Pr)和钕(Nd)的K线,而不会由于线重叠而产生任何干扰。超积累器官中从La到Nd的高能激发是成功的,但与L-线激发相比效率较低,因此由于通量和检测效率较低而较慢(在较低入射能量下比类似图谱慢约10倍)。然而,REE K线不会受到自吸收的显著影响,这使得毫米大小的冷冻水合植物样品的XRF层析成像成为可能。在P06 CRL设置下,REE的K线激发在特别容易受到REE干扰元素影响的样品中有应用范围,例如伴随Ti、Cr、Fe、Mn和Ni浓度较高的土壤样品。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Metallomics
Metallomics 生物-生化与分子生物学
CiteScore
7.00
自引率
5.90%
发文量
87
审稿时长
1 months
期刊介绍: Global approaches to metals in the biosciences
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