Porphyroblast inclusion trails: the key to orogenesis

Detailed microstructural analysis of inclusion trails in hundreds of garnet porphyroblasts from rocks where spiral‐shaped inclusion trails are common indicates that spiral‐shaped trails did not form by rotation of the growing porphyroblasts relative to geographic coordinates. They formed instead by progressive growth by porphyroblasts over several sets of near‐orthogonal foliations that successively overprint one another. The orientations of these near‐orthogonal foliations are alternately near‐vertical and near‐horizontal in all porphyroblasts examined. This provides very strong evidence for lack of porphyroblast rotation. The deformation path recorded by these porphyroblasts indicates that the process of orogenesis involves a multiply repeated two‐stage cycle of: (1) crustal shortening and thickening, with the development of a near‐vertical foliation with a steep stretching lineation; followed by (2) gravitational instability and collapse of this uplifted pile with the development of a near‐horizontal foliation, gravitational spreading, near‐coaxial vertical shortening and consequent thrusting on the orogen margins. Correlation of inclusion trail overprinting relationships and asymmetry in porphyroblasts with foliation overprinting relationships observed in the field allows determination of where the rocks studied lie and have moved within an orogen. This information, combined with information about chemical zoning in porphyroblasts, provides details about the structural/metamorphic ( P‐T‐t ) paths the rocks have followed. The ductile deformation environment in which a porphyroblast can rotate relative to geographic coordinates during orogenesis is spatially restricted in continental crust to vertical, ductile tear/transcurrent faults across which there is no component of bulk shortening or transpression.