Rg. Scott et Jg. Spray, Magnetic fabric constraints on friction melt flow regimes and ore emplacement direction within the South Range Breccia Belt, Sudbury Impact Structure, TECTONOPHYS, 307(1-2), 1999, pp. 163-189
Magnetic fabric analysis and petrography have been carried out on similar t
o 1100 samples from the South Range Breccia Belt (SRBB), a 45-km-long are o
f Huronian Supergroup breccia fragments and crystallized friction melt (pse
udotachylyte), sub-concentric to the 1.85 Ga Sudbury Impact Structure. Opti
cal petrography and analytical SEM analyses show the pseudotachylyte to con
sist of fine-grained quartz, biotite and ilmenite, with minor plagioclase,
apatite, zircon, pyrite and pyrrhotite. Alternating field and thermal demag
netization spectra indicate that the principal magnetic carrier in the matr
ix is pyrrhotite, while clasts can contain either pyrrhotite or magnetite.
Mean magnetic susceptibilities in the matrix are generally on the order of
10(-4) SI. Two AMS (anisotropy of magnetic susceptibility) fabrics have bee
n determined in the matrix. The most common is an oblate, sub-vertical foli
ation, sub-parallel to the local strike of the SRBB, with anisotropies (P)
ranging from 1.08 to 1.20. The second AMS fabric is a weakly to strongly pr
olate sub-vertical lineation with generally higher P values of 1.2 to 1.55.
Both fabrics are coaxial to the petrofabric in the matrix. Huronian clasts
exhibit scattered, heterogeneous AMS fabrics, distinct from those found in
the SRBB matrix. The strongly prolate (T = -0.73) and anisotropic (P = 1.5
5) AMS fabric found directly over the giant Frood-Stobie Ni-Cu-PGE deposit,
hosted within the SRBB, suggests that sulfide droplets were injected and/o
r squeezed into the matrix above the deposit. Samples containing pyrrhotite
from the edges of the deposit do not exhibit this magnetic signature. Simi
lar prolate, moderately anisotropic lineations are also found further to th
e east of the Frood-Stobie Mine, and appear to be associated with a magneto
telluric conductor at depth. It is suggested that these Lineations are due
to injection of material from depth into the SRBB during failure of the inn
er rim of the Sudbury Impact Structure during the crater modification stage
. The oblate magnetic fabric found within the SRBB is consistent with frict
ional comminution and melting of the wall rock Lithologies during collapse
of the transient cavity and subsequent slumping of the crater walls. Howeve
r, subsequent deformation of the Sudbury Structure by late Penokean folding
and thrusting to the NW could produce a similar oblate fabric. Tight clust
ering of the maximum principal axes of the magnetic susceptibility could be
interpreted as being consistent with tectonometamorphic transposition of t
he matrix petrofabric, as well as generation by slumping and friction melt
flow during failure of the hanging wall. Further work is needed on undeform
ed impact structures of similar size to Sudbury in order to constrain the p
etro- and magnetic fabrics produced during rim collapse. Additional work in
the westerly trending SRBB along the edge of the Creighton Pluton would he
lp to determine if the dominant NE-SW-trending matrix fabric is regional in
origin, or is controlled by the current orientation of portions of the SRB
B. (C) 1999 Elsevier Science B.V. All rights reserved.