Deposition and diagenesis of Glauconite Sandstone, Berrymore-Lobstick-Bigoray area, South Central Alberta a study of physical chemistry of cementation /

Meshri, Indu D.

January 1981

Thesis (Ph.D.)--University of Tulsa, 1981. / Four folded enclosures in pocket. Bibliography: leaves 120-130.

Petrographic image analysis as a tool to quantify porosity and cement distribution /

Nejedlik, John.

January 2001

Thesis (M.Sc.)--University of Adelaide, National Centre for Petroleum Geology & Geophysics, 2002. / Includes bibliographical references (leaves 153-157).

Influence of artificial weak cementation on loose silty sand behavior /

Shi, Liangyu.

January 2004

Thesis (M. Phil.)--Hong Kong University of Science and Technology, 2004. / Includes bibliographical references (leaves 163-170). Also available in electronic version. Access restricted to campus users.

The genetic association between brittle deformation and quartz cementation examples from burial compaction and cataclasis /

Makowitz, Astrid. McBride, Earle F. Milliken, K. L.

January 2004

Thesis (Ph. D.)--University of Texas at Austin, 2004. / Supervisors: Earle F. McBride and Kitty L. Milliken. Vita. Includes bibliographical references. Also available from UMI.

The genetic association between brittle deformation and quartz cementation : examples from burial compaction and cataclasis /

Makowitz, Astrid.

January 2004

Thesis (Ph. D.)--University of Texas at Austin, 2004. / Includes bibliographical references (p. 278-297). Available also in an electronic version.

Origin, distribution and paragenetic sequence of carbonate cements in the Ben Nevis Formation, White Rose Field, Jeanne d'Arc Basin, offshore Newfoundland, Canada /

Normore, Leon Scott,

January 2006

Thesis (M.Sc.)--Memorial University of Newfoundland, 2006. / Restricted until October 2007. Bibliography: leaves 182-200. Also available online.

Cement types and cementation patterns of Middle Ordovician ramp- to-basin carbonates, Virginia

Grover, G.

January 1981

Middle Ordovician ramp carbonates were deposited in a rapidly subsiding foreland basin bordered on the southeast by tectonic highlands. Marine, turbid cements include neospar, bladed and turbid rim cements; they are associated with synsedimentary hardgrounds and erosional surfaces. Neospar cement is isopachous and locally botryoidal, and is neomorphic after acicular and botryoid aragonite. Bladed cement has a well-defined crystal morphology, and has non-recrystallized fabrics that suggest a high-Mg calcite precursor. Turbid rim cement syntaxially coats pelmatozoans; its substrate specificity suggests a high-Mg calcite precursor. Marine cements occur throughout the sequence but are abundant in nonreefal buildups, where syndepositional lithification was important in stabilizing buildups. The bulk of the later, non-marine cements are nonferroan, clear rim and equant cements. Zoned (defined by cathodoluminescence) clear cements consist of nonluminescent (oldest), bright and dull (youngest) cements; the sequence relates to increasingly reducing conditions of pore waters. Zoned peritidal cements are best developed in southeastern belts and have complex zonations, pendant to pore rimming fabrics, and are associated with crystal silt (which abuts all cement zones), solutional cavities and erosional surfaces (which locally truncates dull cement). These cements are meteoric vadose to shallow phreatic in origin. Cements in northwestern exposures of peritidal beds are dominated by nonzoned, dull cements which lack abundant evidence of early cementation. Major cementation of subtidal facies occurred under burial conditions. Burial cements in southeastern belts have a simple zonation reflecting progressive burial (up to 3000 m) of the carbonates. Shallow burial, non-luminescent cement in southeastern belts formed from oxidizing waters which expelled anoxic, connate marine waters, and meteoric waters were carried by aquifers from tectonic upland recharge areas on the southeastern basin margin. Burial cements in northwestern belts are dominated by dull cement, initial generations of which precipitated from downdip portions of aquifers. Deeper burial, bright and dull calcite and ferroan dolomite cements formed at burial depths (2000 to 3000 m) and temperatures (75 to 135°C or more) associated with hydrocarbon formation - emplacement. Final clear dull cement fills tectonic fractures and was emplaced during Late Paleozoic deformation. Deeper burial diagenesis appears to be genetically linked to Late Paleozoic, Mississippi Valley-type mineralization. Zoned peritidal and burial cements are mainly confined to southeastern portions of the ramp where cementation was influenced by meteoric waters from tectonic uplands and was carried northwest by paleoaquifers. Northwestern portions of the ramp were little influenced by these meteoric waters, and nonzoned dull cements precipitated from relatively reducing waters. The close association of zoned cements and regional uplands in the Middle Ordovician sequence indicates the importance of assessing regional geologic relationships, geologic history and tectonics in understanding regional cementation patterns and cementation processes of ancient carbonate platforms. / Ph. D.

LD5655.V856 1981.G768

Cementation (Petrology)

Geology, Stratigraphic

Geology -- Virginia

Regional cementation associated with unconformity-sourced aquifers and burial fluids, Mississippian Newman Limestone, Kentucky

Niemann, James Cottier

January 1984

Aquifer-related cements may be differentiated from deeper burial cements by trace elements, cathodoluminescence, staining, and fluid inclusion analysis in the Mississippian Newman Limestone, eastern Kentucky. Aquifer cements are nonferroan, and show a nonluminescent to dull to nonluminescent to bright cathodoluminescent zonation. They fill leached ooids and fossils indicating waters initially were undersaturated. Early nonluminescent cement (35 ppm Mn, 35 ppm Fe) formed from oxidizing waters in a regional paleoaquifer that became reducing (dull cement; 180 ppm Mn, 565 ppm Fe) but underwent later recharge to form a second nonluminescent cement. Most cementation appears to have been associated with post-Newman unconformities reflecting a shift to a wetter climate in Late Mississippian-Pennsylvanian time which generated regional aquifers. Aquifer cement abundance decreases away from recharge areas and is determined by staining for late burial calcite and then using image analysis to determine the amount of early unstained cement. Later, iron rich burial cements (780 ppm Mn, 4295 ppm Fe) fill remaining pore spaces, compaction-induced fractures, spalled cement rims and tectonic fractures (lined with saddle dolomite and pyrite). Irregular dull/very dull zone patterns relate to preferential concentration of iron along certain crystal faces rather than burial leaching. Secondary fluid inclusions chemically complex brines suggest late stage fluids were (7-17 wt% NaCl) having minimum temperatures of 51 to 156°C, that resided in the formation for such short times that conodont alteration values (consistent with estimated burial temperatures of 38-40°C) were not affected. / Master of Science

LD5655.V855 1984.N535

Cementation (Petrology)

Geology, Stratigraphic

Petrology -- Kentucky

Petrographic image analysis as a tool to quantify porosity and cement distribution

Nejedlik, John.

January 2001

Includes bibliographical references (leaves 153-157). Petrographic image analysis proved particularly useful in determining the parameters for statistical analysis for the simple mineralogies displayed in the samples from the Hutton Sandstone. Concentrates on establishing techniques for statistical study of data collected by PIA to subdivide the framework grains from the porosity or cement.

Petrofabric analysis

Rocks Permeability

Cementation (Petrology)

Rocks Analysis

Petrology Eromanga Basin

The genetic association between brittle deformation and quartz cementation: examples from burial compaction and cataclasis

Makowitz, Astrid

28 August 2008

Not available / text

Sandstone--Frio Clay (Tex. and La.)

Sandstone--Illinois Basin

Quartz

Cementation (Petrology)

Rock deformation

Sediment compaction