Electron Backscatter Diffraction (EBSD)

In geology, electron backscatter diffraction (EBSD) is a powerful tool for the observation and analysis of microstructures and for phase identification.

Overview

��ϳԹ��վ College's electron backscatter diffraction (EBSD) system was purchased with funds awarded through the NSF Major Research Instrumentation program (proposal 0320871 funded to Rachel Beane).

Features

The EBSD system, by HKL Technology Inc., includes a Nordlys II EBSD Detector, forescatter detectors and software for orientation mapping (stage and beam control), texture determination, and phase identification (using the American Mineralogist Geological Phase database).

The system is attached to a LEO 1450VP SEM (variable pressure scanning electron microscope) with an EDAX energy dispersive spectrometer (EDS) for mineral chemistry.

How it Works

The EBSD system uses backscattered electrons (BSE) emitted from a specimen in a SEM to form a diffraction pattern that is imaged on a phosphor screen.

Analysis of the diffraction pattern allows identification of the phase and its crystal lattice orientation.

The scanning and mapping capabilities of the system permit rapid acquisition of data, from polished rock thin sections, at sub-micron resolutions.

Among other uses, these data may be applied to evaluate crystallographic preferred orientations (CPO) of mineral fabrics, and to examine misorientation axes and angles that may signify processes such as subgrain development and dislocation creep.

Researchers interested in applying EBSD methods to textural problems in rocks are encouraged to contact Professor Rachel Beane for possible collaborations.

Scanning Electron Microscope (SEM)

Methods

The typical methods this lab uses for collection and processing of EBSD data follow. Specific projects will vary from these methods.

Electron backscatter diffraction (EBSD) analyses are conducted at ��ϳԹ��վ College on a LEO 1450VP SEM outfitted with an HKL Nordlys II detector and Channel 5 software. Samples are prepared by taking standard polished thin sections weighted with halved brass rods (M. Cheadle, personal communication) and polishing an additional six hours in a non-crystallizing colloidal silica suspension on a Buehler Vibromet2 vibratory polisher (SYTON method of Fynn and Powell, 1979).

Thin sections are not carbon coated; charging is minimized by using a chamber pressure of 10-15 Pa, combined with the 70° tilt. Operating parameters for collecting EBSD patterns are an accelerating voltage of 20kV, working distance of 25 mm, and probe current of 2.2nA.

Channel 5 acquisition and indexing settings vary by phase, but typical values are 2x2 or 4x4 binning, high gain, Hough resolution=75, 7 bands, and 80 reflectors. Mean angular deviations between the detected Kikuchi bands and the simulations are less than 1.3 degrees (and often less than 0.8 degrees). Data are post-processed by removing wild spikes, removing observed systematic misindexing, and by extrapolating zero solutions based on 4 neighbors (if required).

Sullivan, W.A. and Beane, R.J., 2009. Asymmetric quartz crystallographic fabrics produced during constrictional deformation. Geological Society of America, Abstracts with Programs , v. 41.
Grew, E.S., Yates, M.G., Beane, R.J., Floss, C. and Gerbi, C., 2008. Chopinite-sarcopside solid solution (Mg,Fe)3 (PO4)2, in Lodranite GRA95209. 71st Annual Meteoritical Society Meeting.
Tsai, C.-H., Shou, H., Izuka, Y., and Beane, R.J., 2008. Textures of progressive garnet growth recorded in Ti-rich metagabbros from the southern Tongbai Mountains, central China. Goldschmidt Conference Abstracts. Geochimica et Cosmochimica Acta; v. 72, p. A958.
Horton, F.*, Beane, R.J., Ketcham, R., and Irby, I.*, 2008. EBSD and HRXCT analysis of elongated garnets of the Spring Point Formation, Casco Bay, ME. Abstracts with Geological Society of America, Abstracts and Programs, v. 40.
Grew, E.S., Yates, M.G., Beane, R.J., Floss, C. and Gerbi, C., 2008. Chopinite-sarcopside in meteorite GRA95209. Goldschmidt Conference Abstracts. Geochimica et Cosmochimica Acta; v. 72, p. A328
Naus-Thijssen, F., Johnson, S., and Beane, R., 2007. Crenulation cleavage development and its rheological implications. Geological Society of America, Abstracts with Programs, v. 39, p.78.
Rodriguez, A.* and Beane, R.J., 2006. Pigeonite Microstructures in Martian Meteorite EETA79001. Geological Society of America, Abstracts with Programs, v. 38, No. 7, p.77.
Beaulieu, J., McFadden, R. and Fayon, A., 2007. Grain-scale deformation and kinematics along a strain gradient, Pioneer Metamorphic Core Complex, Idaho. Geological Society of America, Abstracts with Programs, v. 39, p.74.
Naus-Thijssen, F., Johnson, S., and Beane, R.J., 2006. Chemical and Mechanical Development of Crenulation Cleavage. Knowledge Based Materials, Marie Curie Summer School on Polyphase and Composite Materials, Älvdalen, Sweden.
Rodriguez, A.* and Beane, R.J., 2006. Pigeonite Microstructures in Martian Meteorite EETA79001. Maine Space Grant Consortium, Annual Meeting, Boothbay, Maine.
Beane, R.J. and Field, C.F., 2005. Kyanite deformation in whiteschist of the UHPM Kokchetav Massif, Kazakhstan. Eos Trans. AGU, 86(52), Fall Meet. Suppl., Abstract V43A-1549.
Hawkins, A., Selverstone, J., Brearley, A. and Beane, R., 2005. Fishnet and atoll garnets from the Tauern Window, Eastern Alps: Conditions and Mechanisms of Formation. Geological Society of America, Abstracts with Programs,v. 37, p. 226.
Msall, M.E., Dietsche, W., Beane, R., Wichard, R. and Carpenter, J*, 2004. Examination of an unusual grain boundary in CaF2. The 11th International Conference on Phonon Scattering in Condensed Matter (Phonons2004), St. Petersburg, Russia.
Beane, R. J. and Prior, D. J , 2002. Using EBSD analysis to interpret garnet microstructures. Geological Society of America, Abstracts with Programs, v. 34, p. 9.

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Earth and Oceanographic Science