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Abstract Nepheline syenites from the ∼1.2 Ga Ilímaussaq Complex of southern Greenland are examined to assess the utility of anisotropy of magnetic susceptibility (AMS) fabrics as proxies for silicate petrofabrics. Mineral lamination is a relatively common structural feature in cumulate rocks, including in the Ilímaussaq intrusion, but there is little consensus on the process (or processes) responsible for its formation. The Ilímaussaq AMS data are combined with rock magnetic experiments and electron backscatter diffraction (EBSD) measurements to characterize the magnetic mineralogy and compare the magnetic fabrics obtained to the silicate petrofabric. The data show that Na-amphibole (arfvedsonite) is most likely the dominant control on the AMS fabrics in the coarse-grained nepheline syenites (referred to as kakortokites), and that the AMS fabric is inverse relative to the observed silicate fabric. The EBSD data for a kakortokite sample suggests that the petrofabric is defined by arfvedsonite and is wholly planar, with evidence of only weak cross-lineation of c axes. The fine-grained nepheline syenites (lujavrites), two of which have a well-developed lamination carried by Na-pyroxene (aegirine), appear to have composite AMS fabrics that are considered to be a consequence of a mixed aegirine (normal) and arfvedsonite (inverse) response. The combined datasets shed light on the mechanisms of fabric acquisition in both lithologies. In the kakortokites, the AMS fabrics and silicate crystallographic preferred orientations, as well as the lack of observed microstructural evidence for subsolidus intra-crystal deformation, support models invoking gravitationally controlled crystal mats in the development of the macro-rhythmic layering of these rocks. In the lujavrites, the strong planar fabrics revealed by both the AMS and EBSD datasets, with some evidence of subsolidus deformation, point to fabric formation and perhaps even aegirine crystallization at the postcumulus stage. The combination of EBSD and AMS fabric datasets is a powerful means of deciphering the processes responsible for mineral alignment in igneous cumulates.
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This content will become publicly available on August 1, 2026
Magnetic and Crystallographic Fabric Analyses of Amphibolite: A Proposed Methodology Applied to a Migmatite Dome
Abstract Mafic rocks are volumetrically and rheologically significant components of the mid‐to lower continental crust, yet tools to study their fabrics have not been well developed. We examine amphibolites exhumed from mid‐to lower crustal levels in a gneiss dome (Entia dome, central Australia) that display various strengths of mineral lineation and foliation associated with different deformation geometries. Combining petrofabric analysis (electron backscatter diffraction, EBSD) with magnetic fabric analysis (Anisotropy of magnetic susceptibility (AMS), we quantify relationships between AMS‐derived fabrics and crystallographic‐preferred alignment of fabric‐defining amphiboles. We combine single‐crystal AMS data with EBSD data to model amphibole textures and their expected magnetic anisotropy. We formulate a new EBSD‐derived petrofabric index,CAindex, and correlate it with the calculated AMS shape parameterU.CAindexvalues can then be estimated for natural samples using measuredUvalues, leveraging both rapid but texturally low‐resolution AMS and texturally‐resolved but time‐ and analytically‐onerous petrofabric analyses to interpret petrofabrics from magnetic fabric data. In the Entia dome, we identify amphibole c‐fibers (L‐tectonite) in the high‐strain core of the dome, which reflect constrictional strains. In contrast, a‐fibers (S‐tectonites) are dominant near the dome margins and indicate flattening strains. Fabrics measured in different structural subdomains agree well with 2D and 3D numerical models of finite strain distribution in domal structures. Combining textural modeling, AMS measurements, and EBSD analyses allows investigation of previously unexploited records of ductile deformation and flow in amphibole‐bearing rocks. These results can be applied to a wide range of field‐based studies of tectonic and magnetic processes.
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- Award ID(s):
- 2153786
- PAR ID:
- 10655568
- Publisher / Repository:
- American Geophysical Union
- Date Published:
- Journal Name:
- Journal of Geophysical Research: Solid Earth
- Volume:
- 130
- Issue:
- 8
- ISSN:
- 2169-9313
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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