Dolomite Perspectives on a Perplexing Mineral
Modes of Dolomite Formation
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03 dolomite perspectives on a perplexing mineral
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Modes of Dolomite Formation
Many environments of dolomitization have been identified. Some result in unique reservoir geom- etries that bear directly on exploration strategy. Rather than describe every type of dolomite formation, the following discussion focuses pri- marily on modes that permit dolomites that are thick enough to be targeted for exploration. This also implies that the discussion mainly covers secondary, or replacive, dolomite. In some cases the distinction between modern and ancient con- ditions must be drawn, because current settings do not necessarily reflect the conditions in which ancient dolomites were formed. Three well- established hydrologic models and settings, along with some of their variants, are discussed first, and the section concludes with hydrothermal and bacterial cases. Brine-Reflux Model—Perhaps the most popu- lar concept of dolomite formation is embodied in the brine-reflux model and similar variations. In this instance, seawater in a restricted lagoon evap- orates to form a hypersaline brine that sinks to the lagoon floor and seeps through underlying lime sediments as it escapes, or refluxes back to the sea (above) . As it filters through the pores of the underlying rock, magnesium from the brine replaces part of the calcium contained within the aragonite and calcite components of the lime- stone, converting it to dolomite. This scenario was proposed in 1960 to explain extensive lagoonal and reefal dolomites associ- ated with platform evaporites of the Permian basin in West Texas, USA. 22 Reflux dolomitization has since been recognized in cores from other areas, where the intensity of dolomitization decreases with distance from the evaporite- carbonate contact. Today, hypersaline environ- ments—where water salinity rises above that of normal seawater—are widespread in a belt between about 30° north and south latitude. In the Permian basin, lagoons developed behind barrier reefs on a broad shelf inundated by the shallow waters of Permian seas. The reefs impeded the surface exchange of water between lagoon and sea. Restricted circulation, combined with loss of water by evaporation, lowered water levels in the lagoon, raised the salinity of brines and promoted the precipitation of evaporites. As the specific gravity of the concentrated brine increased, it sank through the water column and migrated to the lowest depressions in the carbon- ate floor of the lagoon. Displacing the connate water in the underly- ing rock, the dense hypersaline brine seeped downward along vertical migration pathways, fol- lowing bedding planes only when vertical paths were exhausted. In rocks with varying permeabil- ities, the seeping brines migrated mainly through porous zones while bypassing denser limestone lenses. Thus, coarse-grained and porous Permian dolomites are limited to beds previously com- posed of coarse-grained and porous limestones. By contrast, fine-grained dense dolomites occupy open-shelf positions, where extremely fine- grained, mud-based lithographic limestones would normally form. Dolomite textures were seen to be caused by primary permeability and crystallinity, rather than by dolomitization. In this model, the down-and-out migration of the hypersaline brine was responsible for dolomi- tizing broad expanses of carbonate rock in the Permian basin. Within the carbonates, the brine- reflux pathways shifted seaward as the shelves regressed. The lagoons, which sourced the brines, also followed progressively forestepping reef deposits. As established escape zones for the brine became sealed off by advancing evaporites, they would be replaced by similar outlets farther seaward. With each forestep, previously unin- vaded reef limestones were exposed to the dolomitizing brines. The pace of regression was geologic, and so slow that most of the limestones were dolomitized before the supply of brine was cut off. Most modern dolomite is associated with hypersaline solutions. 23 Modern brine-reflux con- ditions have been documented on a smaller scale in settings such as the San Andrés Islands offshore Colombia, the Canary Islands, Spain and the Caribbean island of Bonaire in Netherlands Antilles. 24 > Brine reflux in an evaporitic setting. A sill to seaward restricts circulation of waters. Some of the seawater evaporates, causing water density to increase. The dense brines sink below the sediment, reflux through the basin or lagoon floor and dolomitize any carbonate sediments that they pass through. (Adapted from Allan and Wiggins, reference 19.) MattV_ORAUT09_Fig_8 Evaporation Increasing water density Free flow Open marine Sill Seepage reflu x 18. Lucia, reference 12. 19. Allan JR and Wiggins WD: Download 2.33 Mb. Do'stlaringiz bilan baham: 
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