In the past, several researchers have added X-Ray Fluorescence (XRF) to SEMs, using the standard Energy-Dispersive Spectrometers (EDS) already in place [1]-[2]. Most used the electron beam to create fluorescing x rays with a thin transmission target placed between the beam and the sample. The main problem with this approach was the low incident x-ray flux onto the sample, especially if the analysis area is restricted. The advantages of XRF (e.g., improved sensitivities and peak-to-background ratios) were then lost because of the low count rates achieved. We solved this problem by attaching a separate x-ray source onto the SEM, with flux outputs orders of magnitude higher than those produced by SEM beams in transmission targets. By restricting the sample analysis area with apertures or active focusing optics, one can still achieve count rates in these small areas that are typical of standalone XRF spectrometers, with all the advantages of the XRF technique [3].

Keywords:  SEM-XRF, electron microscopy

Energy-Dispersive X-Ray Spectroscopy (ED-XRS or EDS) is a powerful and easy-to-use technique for the elemental analysis of a wide variety of materials. Most commonly, this technique is called X-Ray Fluorescence (XRF), which classically uses x-ray photon sources to excite the sample. A Scanning Electron Microscope (SEM), of course, uses electrons as the excitation source for microbeam x-ray spectroscopy together with sample imaging using characteristic x rays and/or secondary electrons. These two XRS techniques are used independently, although often the same sample is analysed by both, to provide complementary information.

Keywords:  SEM-XRF, electron microscopy

Over the last few years, small x-ray tubes have been modified for mounting on Scanning Electron Microscopes. There have been two main types: (a) low-power miniature tubes mounted re-entrantly within the SEM [1], and (b) higher-power tubes with integrated x-ray optics to produce smaller beam spots at the sample with intensities still high enough for routine analytical work [1, 2]. This addition allows samples to be analyzed both by X-Ray Fluorescence (XRF), and by the electron beam (SEM-EDS), as illustrated with the two spectra in FIG. 1.

Keywords:  SEM-XRF, electron microscopy

In 2014 [1], the first commercial Micro-focus x-rays tubes were added to the Scanning Electron Microscope (SEM) providing x-ray fluorescence (XRF). These x-ray tubes excite a sample and produce characteristic x-rays in the same manner as Energy Dispersive Spectroscopy (EDS). The characteristics x-rays are then collected by an unmodified EDS detector. The addition of XRF compliments standard EDS analysis primarily due to the absence of the background continuum created by the decelerated electrons generated by the electron beam (Bremsstrahlung). The electron beam is more suited for lighter elements, below 2.0keV. While XRF analysis typically detects ppm level trace elements above 2.0keV, hence offering an increased level of analytical capability over standard EDS systems.

Keywords:  SEM-XRF, electron microscopy

For this study, Energy Dispersive Micro X-ray Fluorescence (µXRF) is applied in a practical sense to real problems existing within the food industry. It is also compared to electron-based Energy Dispersive Spectroscopy (EDS). Both systems are generally considered non-destructive methods for determining elemental composition; however µXRF demonstrates specific advantages for elements heavier than phosphorus, or above ~2KeV in the energy spectrum. Elements such as iron, nickel and copper, can be detected in smaller concentrations by µXRF than EDS. Although the X-ray probe is fixed, two-dimensional elemental dot maps can be collected by robotically scanning the SEM stage using available software. Since µXRF employs small probe sizes (focal points are usually 10-50µm), and X-ray probes are not usually optically visible, a simple method for aligning and “aiming” of that probe is presented so that very small, specific regions, or very small particles can be analyzed. When combined with SEM, µXRF becomes a very powerful tool.

Keywords:  SEM-XRF, electron microscopy

Austenitic cast steels of Cr25-Ni32-Nb grade have found wide application in chemical and petrochemical industries. This study discusses the problem of the kinetics of oxidation of these materials in the atmosphere of laboratory air at temperatures of 930 and 1000 °C. Considering the operating conditions of castings (centrifugally cast reformer tubes), the results of the oxidation test of specimens taken from the zone of columnar crystals and equiaxial grains were presented.

Keywords:  SEM/EDS, electron microscopy, microanalysis, SEM-XRF, austenitic steel

Keywords:    SEM/EDS, SEM-XRF, electron microscopy, pottery pigment, archeology

Keywords:  SEM/EDS, electron microscopy, microanalysis, SEM-XRF, steel

Electronic components are everywhere in our modern world. It is imperative that these components are reliable, as they control extremely important systems from every day items, to electronically controlled military equipment as well as a variety of aerospace equipment. To assure this reliability components must go through a battery of tests. XRF analysis is an irreplaceable tool for the semiconductor industry to not only guarantee but to also certify their products. Electrical or photonic circuits are one of these components that are the foundation for so many other products. These circuits begin their lives on silicon wafers. As the wafers and associated circuits and boards become more specialized they require different types of testing.

Keywords: SEM-XRF, electron microscopy, XRF, SEM

Calendar-dated tree-ring sequences offer an unparalleled resource for high-resolution paleoenvironmental reconstruction. Where such records exist for a few limited geographic regions over the last 8,000 to 12,000 years, they have proved invaluable for creating precise and accurate timelines for past human and environmental interactions. To expand such records across new geographic territory or extend data for certain regions further backward in time, new applications must be developed to secure “floating” (not yet absolutely dated) tree-ring sequences, which cannot be assigned single-calendar year dates by standard dendrochronological techniques. This study develops two approaches to this problem for a critical floating tree-ring chronology from the East Mediterranean Bronze–Iron Age. The chronology is more closely fixed in time using annually resolved patterns of ¹⁴C, modulated by cosmic radiation, between 1700 and 1480 BC. This placement is then tested using an anticorrelation between calendardated tree-ring growth responses to climatically effective volcanism in North American bristlecone pine and the Mediterranean trees. Examination of the newly dated Mediterranean tree-ring sequence between 1630 and 1500 BC using X-ray fluorescence revealed an unusual calcium anomaly around 1560 BC. While requiring further replication and analysis, this anomaly merits exploration as a potential marker for the eruption of Thera.

Keywords: hyperspectral imaging, micro XRF, tree-ring, tree ring sequences, Laboratory of Tree-Ring Research

Selenium (Se), a trace element essential for human and animal biological processes, is deficient in many agricultural soils. Some extremely rare plants can naturally accumulate extraordinarily high concentrations of Se. The native legume Neptunia amplexicaulis, endemic to a small area near Richmond and Hughenden in Central Queensland, Australia, is one of the strongest Se hyperaccumulators known on Earth, with foliar concentrations in excess of 4000 μg Se g⁻¹ previously recorded. Here, we report on the Se distribution at a whole plant level using laboratory micro X-ray Fluorescence Microscopy (μXRF) and scanning electron microscopy (SEM-EDS), as well as on chemical forms of Se in various tissues using liquid chromatography-mass spectrometry (LC-MS) and synchrotron X-ray absorption spectroscopy (XAS). The results show that Se occurs in the forms of methyl-selenocysteine and seleno-methionine in the foliar tissues, with up to 13 600 μg Se g⁻¹ total in young leaves. Selenium was found to accumulate primarily in the young leaves, flowers, pods and taproot, with lower concentrations present in the fine-roots and stem and the lowest present in the oldest leaves. Trichomes were not found to accumulate Se. We postulate that Se is (re)distributed in this plant via the phloem from older leaves to newer leaves, using the taproot as the main storage organ. High concentrations of Se in the nodes (pulvini) indicate this structure may play an important a role in Se (re)distribution. The overall pattern of Se distribution was similar in a non-Se tolerant closely related species (Neptunia gracilis), although the prevailing Se concentrations were substantially lower than in N. amplexicaulis.

Keywords: hyperspectral imaging, micro XRF, phytometallomics,  plants, botany

Keywords: hyperspectral imaging, micro XRF, phytometallomics,  plants, botany

Aluminium (Al) is highly toxic to plant growth, with soluble concentrations being elevated in the ∼40% of arable soils worldwide that are acidic. Determining the distribution of Al in plant tissues is important for understanding the mechanisms by which it is toxic and how some plants tolerate high concentrations. Synchrotron- and laboratory-based X-ray fluorescence microscopy (XFM) is a powerful technique to quantitatively analyse the distribution of elements, including in hydrated and living plants. However, analysis of light elements (Z < phosphorus) is extremely challenging due to signal losses in air, and the unsuitability of vacuum environments for (fresh) hydrated plant tissues. This study uses XFM in a helium environment to avoid Al signal loss to reveal the distribution of Al in hydrated plant tissues of Tea (Camellia sinensis). The results show that Al occurs in localised areas across the foliar surface, whereas in cross-sections Al is almost exclusively concentrated in the apoplastic space above and in between adaxial epidermal cells. This distribution of Al is related to the Al tolerance of this species, and accumulation of phytotoxic elements in the apoplastic space, away from sensitive processes such as photosynthesis in the palisade mesophyll cells, is a common tolerance mechanism reported in many different plant species. This study develops an XFM method on both synchrotron and laboratory sources that overcomes the drawbacks of existing analytical techniques, permitting measurement of light elements down to Al in (fresh) hydrated plant tissues.

Keywords: hyperspectral imaging, micro XRF, phytometallomics,  plants, botany

Keywords:   micro-XRF, microEDXRF, centerline segregation, steel, continuously cast

The flora of Papua New Guinea is amongst the richest in the world with an estimated 25,000 plant species. The extreme levels of biodiversity, climatic ranges and soil types suggest a high possibility of metal hyperaccumulator plants existing in Papua New Guinea. However, no hyperaccumulator plants have been reported from this region yet. The use of handheld X-ray fluorescence instruments is a non-destructive and effective method for the systematic quantitative assessment of hyperaccumulation in vast numbers of herbarium specimens. X-ray fluorescence scanning was undertaken at the Queensland Herbarium (Australia) on all Papua New Guinea specimens from seven major families (Celastraceae, Cunoniaceae, Phyllanthaceae, Proteaceae, Rubiaceae, Salicaceae and Violaceae), covering 3164 plant specimens. This preliminary survey revealed the existence of ten zinc hyperaccumulator species (> 3000 µg g⁻¹ Zn), eight manganese accumulator species (> 5000 µg g⁻¹ Mn) and one nickel hyperaccumulator species (> 1000 µg g⁻¹ Ni). These results highlight the potential for discovery of numerous new metal hyperaccumulator plants from the flora of Papua New Guinea if larger-scale systematic screening efforts were undertaken.

Keywords: (hyper)accumulation, micro XRF,  plants, botany

Background and AimsBlue-green iridescence in the tropical rainforest understorey sedge Mapania caudata creates structural coloration in its leaves through a novel photonic mechanism. Known structures in plants producing iridescent blues consist of altered cellulose layering within cell walls and in special bodies, and thylakoid membranes in specialized plastids. This study was undertaken in order to determine the origin of leaf iridescence in this plant with particular attention to nano-scale components contributing to this coloration. Methods Adaxial walls of leaf epidermal cells were characterized using high-pressure-frozen freeze-substituted specimens, which retain their native dimensions during observations using transmission and scanning microscopy, accompanied by energy-dispersive X-ray spectroscopy to identify the role of biogenic silica in wall-based iridescence. Biogenic silica was experimentally removed using aqueous Na2CO3 and optical properties were compared using spectral reflectance. Key Results and Conclusions Blue iridescence is produced in the adaxial epidermal cell wall, which contains helicoid lamellae. The blue iridescence from cell surfaces is left-circularly polarized. The position of the silica granules is entrained by the helicoid microfibrillar layers, and granules accumulate at a uniform position within the helicoids, contributing to the structure that produces the blue iridescence, as part of the unit cell responsible for 2° Bragg scatter. Removal of silica from the walls eliminated the blue colour. Addition of silica nanoparticles on existing cellulosic lamellae is a novel mechanism for adding structural colour in organisms.

Keywords:  SEM/EDS, cell wall, circular polarization, Cyperaceae, epidermis, helicoids, iridescence, leaf, Mapania, nanoparticle, photonics, silica

The pinhole formation mechanism was studied with a variety of MEAs using ex-situ and in-situ methods. The ex-situ tests included the MEA aging in oxygen and MEA heat of ignition. In-situ durability tests were performed in fuel cells at different operating conditions with hydrogen and oxygen. After the in-situ failure, MEAs were analyzed with an Olympus BX 60 optical microscope and Cambridge 120 scanning electron microscope. MEA chemical analysis was performed with an IXRF EDS microanalysis system. The MEA failure analyses showed that pinholes and tears were the MEA failure modes. The pinholes appeared in MEA areas where the membrane thickness was drastically reduced. Their location coincided with the stress concentration points, indicating that membrane creep was responsible for their formation. Some of the pinholes detected had contaminant particles precipitated within the membrane. This mechanism of pinhole formation was correlated to the polymer blistering.

Keywords:  SEM/EDS, electron microscopy, microanalysis

Energy-dispersive X-ray spectrometry (EDS) is an analytical technique used to determine elemental composition. It is a powerful, easy-to-use, non-destructive technique that can be employed for a wide variety of materials. In this technique the electron beam of the scanning electron microscope (SEM) impinges on the sample and excites atomic electrons causing the production of characteristic X rays. These characteristic X rays have energies specific to elements in the sample. The EDS detector collects these X rays as a signal and produces a spectrum. Samples also can be excited by X rays. Collimated and focused X rays from an X-ray source produce characteristic X rays that can be detected by the same EDS detector. When X rays are used as the source of excitation, the method is then called X-ray fluorescence (XRF) or micro-XRF.

Keywords:  SEM/EDS, electron microscopy, microanalysis, SEM-XRF

Keywords:    EDS/XRF, siliceous lithofacies

Keywords:    EDS/XRF, archeological pottery, pigments, iron, electron microscopy

Keywords:    concretions, hematite, Mars, Mars Exporation Rover, Meridiani Planum, Spherule,  sulfate, SEM/EDS

Keywords:   SEM/EDS, superconductor, fiber, analysis

With a sharp increase in the cases of multi-drug resistant (MDR) bacteria all over the world, there is a huge demand to develop a new generation of antibiotic agents to fight them. As an alternative to the traditional drug discovery route, we have designed an effective antibacterial agent by modifying an existing commercial antibiotic, kanamycin, conjugated on the surface of gold nanoparticles (AuNPs). In this study, we report a single-step synthesis of kanamycin-capped AuNPs (Kan-AuNPs) utilizing the combined reducing and capping properties of kanamycin. While Kan-AuNPs have increased toxicity to a primate cell line (Vero 76), antibacterial assays showed dose-dependent broad spectrum activity of Kan-AuNPs against both Gram-positive and Gram-negative bacteria, including Kanamycin resistant bacteria. Further, a significant reduction in the minimum inhibitory concentration (MIC) of Kan-AuNPs was observed when compared to free kanamycin against all the bacterial strains tested. Mechanistic studies using transmission electron microscopy and fluorescence microscopy indicated that at least part of Kan-AuNPs increased efficacy may be through disrupting the bacterial envelope, resulting in the leakage of cytoplasmic content and the death of bacterial cells. Results of this study provide critical information about a novel method for the development of antibiotic capped AuNPs as potent next-generation antibacterial agents.

Keywords: SEM/EDS, antibacterial activity, antibiotic resistance, characterization, gold nanoparticles, kanamycin

Keywords:    spatially resolved elemental analysis, XRF, EDXRF, mapping,

Keywords:    multi-source XRF, heavy metals, soil, dust, elemental analysis