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TLpq250025582
انگلیسی
Geological development of and nature of fractures in the sheeted dyke complex of the Spilia-Politiko area, Troodos ophiolite, Cyprus:
[Thesis]
D. A. van Everdingen
Implications for permeability in oceanic crust
P. Cawood
Memorial University of Newfoundland (Canada)
1993
655
Ph.D.
Memorial University of Newfoundland (Canada)
1993
The presence of hydrothermal vents on the seafloor at present-day spreading centres, and the lower than expected conductive heat flow values at ridge crests requires the convective circulation of fluids in oceanic crust. The fractured nature of oceanic crustal rocks further suggests that fractures rather than the rock matrix control the fluid circulation and hydrothermal alteration. Study of the nature and role of these fractures in the sub-surface below the modern seafloor is at present done only through one-dimensional boreholes and seismic refraction studies. These fracture networks are better described through analogues such as the ancient obducted oceanic crust of the Troodos ophiolite, Cyprus, which provide a three-dimensional, well-exposed cross-section through the oceanic crust. The Spilia-Politiko area, Cyprus, was chosen to investigate the characteristics of fractures in the sheeted dyke complex of the Troodos ophiolite. Sheeted dykes in the study area were intruded along a fast spreading, ridge in the Tethys Sea approximately 90 Ma. A later phase of amagmatic extension, post-dating hydrothermal alteration, resulted in the formation of the Mitsero graben structure through a roughly 12% extension of the crust. Fracture characteristic data for roughly 3200 fractures were systematically collected at 41 locations in the different dyke domains and throughout a vertical section of the Troodos crust, using a scanline mapping method. The mapped characteristics included fracture type, orientation, aperture, length, termination mode, and mineral filling. Fractures within the sheeted dyke complex of the Spilia-Politiko area are sub-divided into two distinct sets: (1) fractures parallel to dyke margins; and (2) those related to columnar jointing. The dyke-parallel fractures tend to exhibit longer trace lengths and larger apertures than those related to columnar jointing. The dyke-parallel fractures tend to contain epidote whereas the columnar joints were filled by calcite which formed at a later time. Both fracture types formed as the result of contraction during cooling of the dykes, such that fracture orientations are related to the paleo-orientation of the dykes. Paleo-permeability of the sheeted dyke complex, numerically modelled on the basis of fracture radius, aperture, orientation, and density data from the study area, ranges from 10 to 10m2. An observed decrease in the calculated paleo-permeability with depth corroborates studies of modern ocean crustal permeability as reported from Deep Sea Drilling Project borehole packer tests. Areas of intense hydrothermal alteration are more fractured than unaltered dykes, therefore their calculated permeabilities are higher, but only by 6%. The intensely altered zones are 50-100 metres wide and contain fluid inclusion and mineralogical evidence for the passage of hot, circa 350C, seawater-salinity fluids. They are considered to be the up-flow portions of hydrothermal circulation cells which resulted in the formation of epidosite bodies. Preferential fracturing along the dyke margins favours vertical permeability, which facilitates vertical hydrothermal convection driven by heat from the small magma chambers. In the study area, the distribution of epidosite bodies suggests that the hydrothermal cells have a mean cross-strike spacing of 5.3 kilometres. Restriction of hydrothermal alteration to well defined zones higher in the sheeted dyke section and an increase in the occurrence of hydrothermal mineral precipitation with depth implies focussing of hydrothermal up-flow higher in the section. Because the amount of fracturing in the diabase does not vary significantly from that of well-defined epidosite zones it is concluded that the location of hydrothermal circulation cells is controlled by the position of the heat source. (Abstract shortened by UMI.)
Earth sciences
Geology
Geology
Oceanography
D. A. van Everdingen
P. Cawood
مطالعه متن کتاب p
[Thesis]
276903
a
Y
