Dolomite Perspectives on a Perplexing Mineral
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03 dolomite perspectives on a perplexing mineral
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overdolomitization. After an initial replacement
phase during which calcite is replaced by dolo- mite, a pore-filling phase may occur, whereby dolomite precipitates to form crystal overgrowths or pore-occluding cement. Thus, overdolomitiza- tion causes young dolostones to have less porosity than associated limestones. 18 Dolomite crystal formation plays another role in reservoir quality. Dolomite frequently forms larger crystals than the calcite it replaces. Enlarged crystal size is associated with increases in pore-throat size and pore smoothness, which boost permeability in dolostones. 19 Because the quality of a dolomite reservoir is characterized by its texture, this interrelation- ship of crystal shape and grain size, orientation and packing within a rock can also affect reser- voir quality. Textural classification schemes help geologists infer processes that controlled crystal nucleation and growth. 20 One widely accepted dolomite classification scheme is based on crys- tal boundary relationships and divides textures into two types: planar and nonplanar. The planar crystals are further divided into euhedral and sub- hedral classes (above) . Planar dolomite forms in both shallow and burial diagenetic environments. Texture develops when crystals undergo faceted growth with pla- nar interfaces, characteristic of dolomite crystals formed during early diagenesis and, under cer- tain conditions, at elevated temperatures in the subsurface. Two porosity-permeability popula- tions exist for planar dolomite. • Planar-e (euhedral) dolomite: This texture, often referred to as “sucrosic,” forms important reservoirs worldwide. Permeability varies strongly with porosity. Uniform pore-throat sizes and well-interconnected pore systems are found in planar-e dolomite, as seen in capillary pressure data and scanning electron microscope (SEM) pore-cast analysis. • Planar-s (subhedral) dolomite: Permeability is lower than in planar-e dolomite and does not increase as rapidly with increasing poros- ity. Uniform throat sizes and well-connected pore systems are not seen in this dolomite, probably because of continued cementation during diagenesis. Nonplanar dolomite occurs in the subsurface at temperatures greater than 50°C [122°F]. This dolo- mite exhibits no significant correlation between permeability and porosity (below) . Permeability in > Dolomite textures. Dolomite can be divided into planar and nonplanar textures ( top). The planar texture is further subdivided into euhedral and subhedral classes. Euhedral (planar-e) dolomite is characterized by well- developed crystal faces with sharp boundaries, with the area between crystals being either porous or filled by another mineral. Subhedral (planar-s) dolomite grains are still planar but less distinct than planar-e grains and show compromised boundaries between crystals. Nonplanar dolomite consists of anhedral grains that lack well-developed crystal faces. These anhedral grains are closely packed, with curved, lobate, serrated or otherwise irregular crystalline boundaries. (Adapted from Sibley and Gregg, reference 20.) Actual examples of these textures are captured in polished thin-section micrographs obtained through a petrographic microscope under polarized light. Euhedral dolomite ( bottom left) from a Cretaceous reservoir of the Middle East exhibits well-developed faces associated with intercrystalline porosity. Subhedral dolomite ( center bottom) was obtained from a Triassic reservoir of the northern Arabian Platform. Anhedral dolomite from a Jurassic reservoir of the Arabian basin ( bottom right) shows a lack of crystal faces and interlocked crystals that destroy porosity. (Photographs courtesy of Fadhil Sadooni.) MattV_ORAUT09_Fig6_2 Planar texture Increase in temperature Nonplanar texture Euhedral Subhedral Anhedral > Porosity versus permeability. Quantitative analysis of different textural types indicates that permeability in dolomites is not directly related to total porosity or crystal size, but rather to the connectivity of pore throats. There is a strong relationship between increasing porosity and permeability in planar-e dolomites ( top, green), and an apparent strong relationship in planar-s (blue). The correlation coefficient ( r) between porosity and permeability in nonplanar dolomites ( bottom, yellow) is low, as permeability in this type of dolomite is a function of secondary features such as connected vugs and fractures. Points plotted at 0.5 mD represent measurements that fell below the lower determination limit of the permeameter and are not part of a statistical trend. (From Woody et al, reference 21.) MattV_ORAUT09_Fig_7 Total porosity, % by volume 10 5 10 4 10 3 10 2 10 1 r = 0.99 r = 0.99 10 0 10 –1 Permeability , mD 10 5 10 4 10 3 10 2 10 1 10 0 10 –1 0 5 10 15 20 25 30 Total porosity, % by volume 0 5 10 15 20 25 30 Permeabilit y, mD r = 0.15 Planar-e dolomite Planar-s dolomite Nonplanar dolomite 26678schD5R1.indd 36 12/9/09 7:28 AM Autumn 2009 37 nonplanar dolomite is often attributed to secondary porosity features such as fractures or intercon- nected vugs, rather than intergranular porosity found between crystals. 21 Researchers continue to unravel the mysteries of dolomite mineralization. The discovery that dolomite is metastable was a revelation that helped geoscientists explain the variations in chemical proportions and structural order that are seen as the mineral evolves. Dolomitization is not a single event; it is a sequence of responses caused by changing geologic conditions. Download 2.33 Mb. Do'stlaringiz bilan baham: 
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