• Title of article

    The effects of quartz recrystallization and reaction on weak phase interconnection, strain localization and evolution of microstructure

  • Author/Authors

    Gonçalves، نويسنده , , Cristiane C. and Gonçalves، نويسنده , , Leonardo and Hirth، نويسنده , , Greg، نويسنده ,

  • Issue Information
    ماهنامه با شماره پیاپی سال 2015
  • Pages
    17
  • From page
    24
  • To page
    40
  • Abstract
    We conducted axial compression and general shear experiments, at T = 900 °C and P = 1.5 GPa, on samples of banded iron formation (BIF) and synthetic aggregates of quartz, hematite and magnetite to investigate how dynamic recrystallization of quartz promotes strain localization, and the role of weak second phases (oxides) on the rheology and microstructural evolution of the aggregates. Experiments showed strain localization into oxide rich layers, and that the oxide content and oxide distribution are key factors for the strength of the aggregate. Only 2–10 wt.% hematite leads to pronounced weakening and increasing hematite content above ∼10% has only a minor additional effect. Where oxide grains are dispersed, the initial strength contrast with quartz induces stress concentrations at their tips, promoting high stress recrystallization-accommodated dislocation creep of quartz. Fine recrystallized quartz reacts with oxide, forming trails of fine reaction product (ferrosilite/fayalite) leading to the interconnection/percolation of a weaker matrix. The strength contrast between the quartz framework and these fine-grained trails promotes strain localization into micro-shear zones, inducing drastic strain weakening. Thus dynamic recrystallization of quartz promotes syn-deformational reactions leading to a microstructurally-controlled evolution of phase strength contrast. It results in a rheologic transition from load-bearing framework to a matrix-controlled rheology, with transition from S–C′ to S–C fabric with increasing strain.
  • Keywords
    Weak phase interconnection , Experimental deformation , Shear zone development , Quartz rich aggregates , Load-bearing framework , Matrix-controlled rheology
  • Journal title
    Journal of Structural Geology
  • Serial Year
    2015
  • Journal title
    Journal of Structural Geology
  • Record number

    2228486