Spatial distribution of melt-bearing structures in anatectic rocks from Southern Brittany, France: implications for melt transfer at grain- to orogen-scale

In this study, we present quantitative spatial information on the one- and two-dimensional distribution of inferred melt-bearing structures in anatectic supracrustal rocks of the Southern Brittany Migmatite Belt, south of the transcurrent South Armorican Shear Zone (SASZ); based on these data, we infer the mechanism of melt extraction from partially molten crust. Former melt-bearing structures include foliation-parallel leucosomes and cross-cutting granitic leucosomes that infill inter-boudin partitions and extensional shear surfaces, as well as discordant dykes of granite. Petrographic (i.e., mineralogical and microstructural) continuity of granite from structure to structure suggests that they once formed a continuous melt-bearing network. Measurements along one-dimensional line traverses perpendicular to layering of stromatic migmatite exposed in clean, sub-horizontal outcrop surfaces provide information about thickness and spacing distributions of foliation-parallel leucosomes. Most leucosome thicknesses fall in the range of 1–10 mm, with upper limits around 20–30 mm. The number of thicker layers decreases abruptly with increasing thickness, which is inconsistent with scale-invariance. This suggests that leucosome formation was controlled by short-range melt movement along grain boundaries to form melt-rich layers constrained by pre-existing compositional layering. Spacing distributions also are not scale-invariant; however, the large percentage of leucosomes (40–60%) in these line traverses suggests that spacing distributions may be controlled in part by impingement of leucosomes, making it difficult to derive genetic information from these data. Qualitative observation of inferred melt-bearing structures in mutually perpendicular two-dimensional exposures from the same outcrop reveals anisotropy of the leucosome network related to a well-developed sub-horizontal quartz–feldspar lineation reflecting stretching associated with transcurrent movement along the SASZ. Analysis of these two-dimensional distributions using the box-counting method corroborates the observed anisotropy, but indicates that leucosome morphology (and perhaps distribution) is not scale-invariant. The applicability of the box-counting method, or of fractal analysis, to understanding melt movement in migmatites is discussed in light of these results. Based on the anisotropy of melt-bearing structures, we infer that melt-movement in structures now represented by layer-parallel leucosomes was primarily sub-horizontal. These layers fed steeply dipping structures now represented by cross-cutting leucosomes, in particular those developed at inter-boudin partitions, and granite dykes. The formation and orientation of these steeply dipping structures was in part controlled by far-field stresses related to dextral displacement along the SASZ. Melt extraction is inferred to have occurred along these steeply dipping structures; extracted melt accumulated in plutons at higher crustal levels, such as the Quiberon, Sarzeau, and Guérande granites.