原位微区同步辐射X射线荧光和近边吸收谱研究铅耐受细菌吸附-转化铅机理

为了从微观水平研究细菌生物吸附及转化铅机理,利用原位微区同步辐射X射线荧光(μ-SRXRF)及X射线吸收近边结构谱( XANES)研究云南兰坪铅锌矿区农田土壤样品中筛选的铅耐受性细菌吸附铅的分布特征及铅形态转化规律。土壤中具有铅耐受性的菌株主要为Arthrobacter sp.属(节杆菌属),采用μ-SRXRF对其吸附铅的含量进行快速简单直接分析,部分细菌吸附铅的含量高达5925μg/g,富集系数达14.8。XANES结果表明,细菌吸附 Pb 后存在形态为 PbS、(C17 H35 COO)2Pb 和 Pb5(PO4)3Cl 分别占58.0％,22.2％和19.8％,与培养基本身以有机态为主的Pb形态有明显差异,表明培养基中铅被细菌吸附后有向硫化物转化的趋势,这为研究重金属生物有效性的影响因素提供了实验参考。     

微量贵金属对Co／γ-Al_2O_3的作用及其结构表征Ⅱ．Co－M／γ－Al_2O_3的XAFS表征

采用ＸＡＦＳ方法分别对Ｃｏ的近边结构和配位状态进行了详细的表征．ＸＡＮＥＳ的结果表明，所有样品中Ｃｏ均处于不对称的配位环境中，在吸收阈值处，形成了１ｓ→４ｐ吸收峰，并且该峰发生了分裂，尤其是Ｃｏ／γ－Ａｌ２Ｏ３分裂现象最为明显．对于Ｃｏ－Ｍ／γ－Ａｌ２Ｏ３（Ｍ＝Ｐｔ，Ｐｄ，Ｒｈ），这种不对称性可能来源于Ｃｏ的高度分散性及贵金属与Ｃｏ之间的相互作用，而对于Ｃｏ／γ－Ａｌ２Ｏ３，则与四面体配位的Ｃｏ２＋离子有关．ＥＸＡＦＳ结果表明，含贵金属样品中，Ｃｏ均以零价形式存在，和标样Ｃｏ粉相比，Ｃｏ－Ｃｏ键长略有增加，而配位数较标样下降许多．配位数的下降，表明Ｃｏ具有高度的分散性，而键长的增加可能是贵金属与Ｃｏ的相互作用削弱了Ｃｏ－Ｃｏ键引起的．     

室温下纳米氧化锌新相的合成及表征

常温常压下,用高分子聚乙烯吡咯烷酮(PVP)作为表面修饰剂,成功地合成了粒度分布窄、平均粒度为4.0nm的氧化锌纳米微粒,其晶体结构与文献报道在高温高压(450℃,6×10⁸Pa)下合成的体相ZnO具有相同结构.EXAFS实验结果表明,纳米Zn-O的键长比体相发生收缩,Zn原子周围的氧配位数减少.     

近边X射线吸收精细结构光谱法研究土壤腐殖质组分含碳官能团组成及磷酸根影响

应用同步辐射近边X射线吸收精细结构(NEXAFS)光谱技术研究了土壤腐殖质各组分(富里酸、胡敏酸及胡敏素等)的含碳官能团组成信息,并通过分析PO43-存在条件下胡敏酸、胡敏素的官能团组成变化特征,探讨了PO43-与土壤腐殖质之间的微观作用机制。结果表明,土壤腐殖质不同组分的官能团分布具有类似的光谱特征,但组成比例存在明显差异。随着腐殖质组分的酸不溶性增加,胡敏酸、胡敏素疏水性脂肪基官能团比例显著高于富里酸,芳构化程度也明显增加,而亲水性羧基官能团比例趋于降低;PO43-通过静电作用、取代反应可以选择性释放胡敏酸中部分小分子羧基官能团,从而改变胡敏酸官能团的组成特征。此研究结果对于应用NEXAFS研究有机碳官能团形态、结构及理解PO43-在土壤微界面上的反应机制具有重要意义。     

微束X射线荧光和X射线吸收近边结构谱分析云南某铅锌矿区苔藓中铅的分布和形态

苔藓对重金属胁迫具有良好耐受性和一定的积累能力.本研究采集并测定了铅锌矿区苔藓和苔下土壤中重金属元素含量,利用微束X射线荧光光谱(Micro-X-ray fluorescence spectrometry, micro-XRF)测定了苔藓中重金属元素的分布,采用X射线吸收近边结构(X-ray absorption near edge structure, XANES)分析了苔藓中Pb的元素形态.研究表明,矿区苔藓具有较强的Pb、Zn、Cd、As积累能力,Pb和Zn最高含量可达1.06和1.23 mg/g, Cd和As最高含量可达30.5和13.2 μg/g.苔藓地上部(尤其是新生组织)是苔藓吸收并积累重金属的主要部位;矿区采集的小灰藓和匍枝青藓中部分金属元素分布规律不同,反应了不同苔藓种属对金属元素的吸收、积累和耐受机制的差异.XANES结果显示,Pb在小灰藓中主要以Pb3(PO4)2形态存在(约78%),表明生成Pb3(PO4)2沉淀可能是苔藓对Pb的耐受机制之一.     

纳米α-Fe~2O~3的XANES研究

选择纳米α-Fe~2O~3体系,运用X射线近边吸收谱(XANES)技术对纳米材料进行分析。结果表明,三种尺寸的纳米α-Fe~2O~3样品(颗粒尺寸分别是3nm,10nm和55nm)与粗颗粒商品的氧K边XANES谱的不同之处在于,纳米样品出现了一个新的吸收B峰。研究揭示,该峰可能是纳米α-Fe~2O~3中晶界部分氧的2p-4sp杂化所产生的一个新电子跃迁末态造成的。进一步的研究表明,随着纳米α-Fe~2O~3的粒子尺寸减小,氧的2p轨道和铁的3d轨道杂化增加,主要体现在2p-e~g杂化程度加剧,使得纳米颗粒中铁周围的氧配位八面体畸变程度加强。最后,通过对3nm样品在研磨和不研磨两种制样方式获得的氧K边XANES谱分析,证实纳米粒子体系中存在特殊的协同作用力。     

X射线荧光与粒子激发X射线光谱分析

本文是《分析试验室》定期评述“Ｘ射线荧光光谱分析”系列评论第７篇,简述了１９９６年７月至１９９８年６月国内Ｘ射线荧光光谱分析技术发展的概况,从Ｘ射线荧光光谱仪的研制与改造、特殊激发方式的研究与应用、化学计量学与数据处理方法研究、化学态分析、标准物质与样品制备、测定方法研究与应用６个方面评述了国内Ｘ射线荧光与粒子激发Ｘ射线光谱分析进展。共收录国内学者论文及相关文集１４３篇。     

X射线吸收精细结构技术在放射性核素界面反应中的应用

X射线吸收精细结构（X-ray absorption fine structure,XAFS）技术是同步辐射应用的一个最重要方向之一,XAFS技术可以原位探测中心原子的2—3个邻近配位壳层,获得中心原子的电子结构和微观化学结构信息,已成为微观领域最重要的结构分析工具。在环境科学领域,XAFS技术可以在分子水平上研究污染...     

1, 1, 2, 3, 4, 5-六苯基硅杂环戊二烯X射线谱的理论研究

近年来苯基硅杂环戊二烯作为一类高效的有机发光二极管材料被广泛研究。本工作利用密度泛函理论结合芯态空穴近似研究了1, 1, 2, 3, 4, 5-六苯基硅杂环戊二烯分子中碳原子K壳层和硅原子L壳层的X射线光电子能谱和近边X射线吸收精细结构谱,与实验谱线符合较好。通过理论结果对实验测量的1, 1, 2, 3, 4, 5-六苯基硅杂环戊二烯分子的X射线谱进行了分析和标定。我们发现碳原子K壳层X射线光电子能谱在低能区283.8eV处的谱峰是由于与硅原子成键的两个电负性较强的碳原子导致的。碳原子K壳层近边X射线吸收精细结构谱中最强的吸收峰与苯分子的吸收峰类似。硅原子L壳层近边X射线吸收精细结构谱两个主要吸收峰分别来自于σ_Si-C^*和π_Si-Ph^*跃迁。     

近边X光吸收谱（XANES）的发展

微观的局部有序指明了了解复杂体系性质的道路。蛋白质的生物功能、催化剂的活性、金属表面的吸附及超导体的电性能等，测定其局部结构是认识这些体系的第一步。科学的不断发展使局部结构测定的必要性日增，而发展的科学本身又从理论上和技术上孕育了新的实验探测方法。     

Studies of carbon monoxide oxidation on carbon-supported platinum-osmium electrocatalysts

The electrocatalytic oxidation of hydrogen in the presence of carbon monoxide was studied on PtOs/C electrocatalysts prepared by the formic acid method and heat-treated under several temperatures and atmospheres. The physical properties of the metallic phase were evaluated by X-ray diffraction (XRD), energy dispersive X-ray (EDX) analysis, and in situ X-ray absorption spectroscopy (XAS). The electrochemical performance of these materials was evaluated by single-cell polarization measurements, cyclic voltammetry, and linear sweep CO stripping voltammetry. The results have shown an enhancement of the CO oxidation process for the as-prepared PtOs/C and for a material heat-treated in a reducing atmosphere (hydrogen at 500 °C), compared to Pt/C. The electrochemical data also showed that the as-prepared and hydrogen-treated PtOs/C catalysts present CO tolerance higher than Pt/C. This has been associated with the occurrence of a surface reaction of CO adsorbed on Pt and oxygenated Os sites, favored by an intimate physical contact between segregated Os and Pt phases.Dedicated to Prof. Wolf Vielstich on the occasion of his 80th birthday in recognition of his numerous contributions to interfacial electrochemistry     

Comparison of conventional and total reflection excitation geometry for fluorescence X-ray absorption spectroscopy on droplet samples

X-ray absorption fine structure (XAFS) experiments in fluorescence mode have been performed in total reflection excitation geometry and conventional 45°/45° excitation/detection geometry for comparison. The experimental results have shown that XAFS measurements are feasible under normal total reflection X-ray fluorescence (TXRF) conditions, i.e. on droplet samples, with excitation in grazing incidence and using a TXRF experimental chamber. The application of the total reflection excitation geometry for XAFS measurements increases the sensitivity compared to the conventional geometry leading to lower accessible concentration ranges. However, XAFS under total reflection excitation condition fails for highly concentrated samples because of the self-absorption effect.     

电位质子滴定与NEXAFS和XPS表征功能化多壁碳纳米管比较(英文)

Since the discovery of carbon nanotubes (CNT), this material has been recognized as an attractive catalyst support. CNT must be functionalized before use as a catalyst support and typically this involves oxidation. However, the functional group distribution on the CNT is very complex mixture of groups and varies with oxidation agent used. Here a simple acid-base titration is introduced to characterize the oxygen functionalized CNT. By comparing characterization with near-edge X-ray absorption fine structure (NEXAFS) and X-ray photoelectron spectroscopy (XPS) for both at the C and O K-edges, it can be demonstrated that potentiometric proton titration can be a fast and quantitative analysis for Brnsted acid functional groups on CNT.     

Impact of finite-temperature and condensed-phase effects on theoretical X-ray absorption spectra of transition metal complexes

The impact of condensed-phase and finite-temperature effects on the theoretical X-ray absorption spectra of transition metal complexes is assessed. The former are included in terms of the all-electron Gaussian and augmented plane-wave approach, whereas the latter are taken into account by extensive ensemble averaging along second-generation Car–Parrinello ab initio molecular dynamics trajectories. We find that employing the periodic boundary conditions and including finite-temperature effects systematically improves the agreement between our simulated X-ray absorption spectra and experimental measurements. © 2018 Wiley Periodicals, Inc.     

Pitfalls in X-ray absorption spectroscopy analysis and interpretation: A practical guide for general users

Despite the growing popularity of X-ray absorption spectroscopy (XAS) in scientific research, many researchers do not receive formalized training on this technique. Some of them learned from online resources, which only briefly introduce XAS and its applications. Here, this article aims to provide the overview of tips about the XAS analysis, general rules, as well as required information for presenting XAS data in publications, and some common mistakes in XAS data interpretations. Armed with these basics, the motivated aspiring XAS researchers will find existing resources more accessible and can progress much faster in understanding and using XAS.     

Changes in the near-edge X-ray absorption fine structure spectra of long-chain diacetylene derivatives through photopolymerization in Langmuir–Blodgett films

Photopolymerization of cadmium 10,12-pentacosadiynoate (CdDA) in Langmuir–Blodgett (LB) films, with the molecular packing well arranged by moderate preannealing, was investigated with near-edge X-ray absorption fine structure (NEXAFS) spectroscopy. Greenish films of polydiacetylene with an absorption wavelength of 705 nm were obtained through the photopolymerization of preannealed monomer LB films, and this resulted in an extended π-conjugate system based on the well-ordered monomer in a two-dimensional arrangement. The electronic structures of the polydiacetylenes were found to be correlated to the variation of the molecular arrangements in the films from the changes in the NEXAFS spectra through photopolymerization in the LB films. © 2004 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 42: 2329–2336, 2004     

New sights into the electrochemical interface provided by in situ X-ray absorption fine structure and surface X-ray scattering

Various important processes, such as electron transfer reactions, adsorption/desorption, solvation/desolvation, and formation/cleavage of chemical bonds, take place at electrolyte/electrode interfaces during electrocatalytic reactions. Those processes have been understood on the basis of changes in the surface composition, atomic arrangement, and molecular and electronic structures of the interfaces by using various in situ analysis techniques. To date, in situ analysis and observation of those interfacial processes at an ideal single-crystal surface are indispensable not only for fundamental understanding of the reaction mechanism but also for rational design of the highly efficient and durable electrocatalytic materials. Here, historical and recent progress of in situ studies on electrocatalytic reactions is briefly reviewed with a focus on two major techniques, X-ray absorption fine structure and surface X-ray scattering.     

Platinum submonolayer-monolayer electrocatalysis: An electrochemical and X-ray absorption spectroscopy study

A new Pt monolayer electrocatalyst concept is described and the results of electrochemical and X-ray absorption spectroscopy (XAS) studies are presented. Two new methods that facilitate the application of this concept in obtaining ultra-low-Pt-content electrocatalysts have been developed. One is the electroless (spontaneous) deposition of a Pt submonolayer on Ru nanoparticles, and the other is a deposition of a Pt monolayer on Pd nanoparticles by redox displacement of a Cu adlayer. The Pt submonolayer on Ru (PtRu₂₀) electrocatalyst demonstrated higher CO tolerance than commercial catalysts under conditions of rotating disk experiments. The long-term stability test showed no loss in performance over 870 h using a fuel cell operating under real conditions, even though the Pt loading was approximately 10% of that of the standard Pt loading. In situ XAS indicated an increase in d-band vacancy of deposited Pt, which may facilitate partly the reduced susceptibility to CO poisoning for this catalyst. The kinetics of O₂ reduction on a Pt monolayer on Pd nanoparticles showed a small enhancement in comparison with that from a Pt nanoparticle electrocatalyst. The increase in catalytic activity is partly attributed to decreased formation of PtOH, as shown by XAS experiments.     

Novel visualization studies of lignocellulosic oxidation chemistry by application of C-near edge X-ray absorption fine structure spectroscopy

The research presented herein is the first attempt to probe the chemical nature of lignocellulosic samples by the application of carbon near edge X-ray absorption fine structure spectroscopy (C-NEXAFS). C-NEXAFS is a soft X-ray technique that principally provides selective interrogation of discrete atomic moieties using photoelectrons of variable energies. The X1A beam line of the National Synchrotron Light Source was employed for the specific purpose of observing carboxylic acid moieties that display a signature absorption band centered at 289 eV. This study caps a larger effort to support the mechanistic basis for lignocellulosic fiber chemical degradation induced by the disproportionation of hydrogen peroxiduring fiber bleaching trials. It is shown that fibers that have been bleached with a hydrogen peroxide phase without removal of resident pendant metals (Mn, Cu, Fe) sustain significant macroscopic damage likely via classical Fenton-type radical reactions, as evidenced by a tensile reduction by over 30%. We present X-ray absorption spectra obtained using a scanning transmission X-ray microscope (STXM) at the end of a 2.5 GeV electron synchrotron that provided 1s ^* contrast-enhanced micrographs illustrating a random distribution of acid functionalities that were principally located on fiber surfaces. Control studies using non-bleached fibers demonstrated that very little signature carboxylic acid absorption patterns were present in the fibers, suggesting that these groups are an incriminating fingerprint for macroscopic fiber strength damage during non-radical suppressed bleaching trials.     

Local structure and oxidation state of uranium in some ternary oxides: X-ray absorption analysis

We investigated the local atomic and electronic structures of two related systematic sets of ternary uranium oxides, NaUO₃-KUO₃-RbUO₃ and BaUO₃-Ba₂U₂O₇-BaUO₄, by measuring the X-ray absorption near edge structure (XANES). The results are compared with calculations based on a self-consistent real space full multiple scattering analysis. We found a very good agreement between measured and calculated spectra, which indicates that the uranium ions are in a pure U⁵⁺ oxidation state in these compounds. The low energy shoulder observed in the U L₃ edge XANES is an intrinsic feature of the uranium unoccupied 6d electronic states of the U⁵⁺ ions within the studied materials. Specific double shoulder features in the higher energy range of the U L₃ edge XANES can be interpreted as indicative of the pure cubic perovskite structure.