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Multi-Scale Correlative Study of Corrosion Evolution in a Magnesium Alloy

ZEISS Research Microscopy Solutions
16 Aug 2016

This application note describes the results of a multi-scale correlative tomography study on the corrosion of a Magnesium alloy. Zeiss’ Atlas 5 is used to efficiently link and navigate between in situ sub-micron X-ray microscopy, nanoscale X-ray microscopy and FIB-SEM tomography. The study provides a description of the complex crack and corrosion byproduct geometries which can lead to a more complete understanding of the underlying mechanisms for corrosion.

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ZEISS Atlas 5

ZEISS Research Microscopy Solutions

Large area imaging for SEM, FE-SEM & FIB-SEM ATLAS combines a 16 bit scan generator and dual super-sampling signal acquisition hardware with image processing and control software for your ZEISS electron microscope. Acquire images up to 32 k x 32 k pixels, with dwell times from 100 ns to > 100 s, adjustable in 100 ns increments. Save your images with eight or sixteen bits of intensity. With the ATLAS “Mosaic Tool” you create large image montages, automatically moving from image tile to tile, and mosaic site to site, resulting in an “Extreme Field of View” image, at SEM nanometer scale resolution. ATLAS provides • reduced number of tiles to acquire, reducing stage motion delay and areal fraction of each image “lost” to overlap • reduced number of overlap “seams”, leading to less beam damage and degradation of the sample • reduced computational complexity

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X-Ray Diffraction and SpectroscopyX-Ray diffraction & spectroscopy are used in material characterization to discern the structure and elemental composition of a sample. X-Ray diffractometers (XRD) are superior instruments in elucidating the dimensional atomic structure of crystalline materials, including powders, thin films and single crystals. For large unit cells or ordered macromolecules, consider small-angle X-ray scattering (SAXS). X-ray spectroscopic techniques include X-ray fluorescence (XRF) and X-ray photoelectron spectroscopy (XPS), both providing simple and accurate methods for determining the elemental composition of a material. Energy dispersive (EDXRF) and wavelength dispersive (WDXRF) XRF spectrometers are available, as well as handheld/portable devices. High-resolution, 3D microstructure characterization of materials can be achieved with X-ray microscopes combining sub-micron resolution imaging with 3D computed tomography. Find the best XRD and XRF spectrometers in our peer-reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.Software PlatformsSoftware platforms are useful for various stages of laboratory experiments from data collection to data storage and processing. For instance lab software is available for system control, data management, data analysis and qualification / validation.Non-Destructive TechniquesNon-destructive techniques (NDT) describes a variety of analytical techniques used to evaluate the properties of a material. Common methods include ultrasonic, magnetic-particle, liquid penetrant, radiographic, remote visual inspection (RVI), and eddy-current testing. NDT is regularly used in forensic engineering, civil engineering, mechanical engineering, electrical engineering, systems engineering, aeronautical engineering, and medicine.3D Imaging3D imaging technologies allow for the visualization and analysis of three-dimensional structures at high resolution. These systems are used in fields like molecular biology, material science, and medical diagnostics. 3D imaging can be applied to visualize cells, tissues, and organs, providing valuable insights into their structure and function. Browse our peer-reviewed product directory to find the best 3D imaging solutions, compare products, check reviews, and get pricing directly from manufacturers.MicroscopyMicroscopy is a technique used to observe small objects in detail, from cells to materials, using light or electron microscopes. It enables researchers to examine structures with high resolution, aiding in fields such as biology, medicine, and materials science. With advanced microscopy techniques, scientists can gain insights into cellular processes, tissue structures, and material properties. Explore the best microscopy solutions in our peer-reviewed product directory, compare products, read customer reviews, and get pricing directly from manufacturers.Surface AnalysisX-Ray SourceSpectroscopySpectroscopy is a technique that analyzes the interaction of light with matter to study molecular properties, concentrations, and structural information. Widely used in chemical, pharmaceutical, and environmental analysis, spectroscopy offers insights into molecular composition and helps identify unknown compounds. It plays a key role in quality control, research, and diagnostics. Browse our peer-reviewed product directory to compare spectroscopy tools, read reviews, and get prices directly from manufacturers.CorrosionMetalsMetal analysis is critical in various industries, including environmental monitoring, food safety, and pharmaceuticals. Techniques such as ICP-MS and atomic absorption spectrometry are commonly used to detect trace metals. Explore metal analysis tools in our peer-reviewed product directory; compare products, check reviews, and get pricing directly from manufacturers.SEMScanning Electron Microscopy (SEM) is a technique that uses a focused electron beam to scan a sample and create high-resolution images. It is widely used in materials science, nanotechnology, and biological research. Explore SEM systems in our peer-reviewed product directory; compare products, check reviews, and get pricing directly from manufacturers.

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Multi-Scale Correlative Study of Corrosion Evolution in a Magnesium Alloy