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The geology and structure of the Bushveld Complex metamorphic aureole in the Olifants River area.Uken, Ronald. January 1998 (has links)
The contact metamorphic aureole of the Rustenburg Layered Suite of the Bushveld Complex extends to a depth of over 5 km into the underlying mainly argillaceous Pretoria Group. When compared to other parts of the metamorphic aureole, the Olifants River area is unique in that it is characterised by a high degree of syn-Bushveld Complex deformation and very coarse grained pelitic assemblages. This is believed to have resulted from a combination of greater magma thickness, a deeper emplacement depth and a high degree of subsidence related deformation that was focused along the Thabazimbi-Murchison Lineament. This area also contains a laterally extensive and deformed quartz-feldspar porphyry sill, the Roodekrans Complex that is shown to represent a hypabyssal equivalent of the volcanic Rooiberg Group. There are three main metamorphic zones. A wide andalusite zone dominated by staurolite, garnet and cordierite assemblages. This is followed by a narrow fibrolite zone without staurolite, and a wide inner aureole of migmatite. The migmatite zone is characterised by garnet-cordierite-aluminosilicate assemblages with corundum, spinel and orthopyroxene assemblages at the highest grades. Metamorphic pressure and temperature estimates indicate pressures of between 3 kb and 4 kb in the lower part of the andalusite zone at temperatures of approximately 550°C. Porphyroblast-matrix relationships reveal a close link between deformation and metamorphism resulting in a spectrum of textural relationships developed as a result of inhomogeneous strain. Porphyroblasts in low strain domains preserve textures of “static type" growth whereas syntectonic textures are found in foliated rocks. Pre-tectonic porphyroblasts in many foliated domains indicate that deformation outlasted porphyroblast growth and increased in intensity and extent with time. Retrograde porphyroblasts are post-tectonic. Evidence is presented for both rotation and non-rotation of porphyroblasts in relation to geographical coordinates during extensional top-to-south, down-dip shear in the floor. The unique structural setting in this area triggered the growth of large diapiric structures in the floor of the Rustenburg Layered Suite that are preserved as periclinal folds on the margin and within the northeastern Bushveld Complex. Extreme gravitational loading and heating of the floor by a thickness of up to 8 km of mafic magma resulted in the generation of evenly spaced, up to 7 km diameter wall-rock diapirs that penetrated the overlying magma chamber. Diapiric deformation is restricted to rocks above a decollement zone that is developed along competency contrasts and corresponds approximately with the 550 °C peak metamorphic isotherm. Strongly lineated, boudinaged and foliated rocks are developed in the interpericlinal domains between adjacent periclines. Migmatites in these domains are characterised by conjugate extensional ductile shears and associated asymmetrical boudinage suggesting bulk deformation by pure shear processes. The extension lineation was produced by lateral extension along flow lines directed toward dome culminations. Each of the four diapiric periclines is cut by a different erosional section enabling reconstruction of a typical diapir geometry. At the highest structural levels, periclines have bulbous shapes with overturned limb geometries forming overhangs. The surrounding layered igneous rocks are locally deformed into a series of outward verging folds that define a broad rim syncline. Deformation within the pericline cores is represented by constrictional deformation that produced radial curtain-type folds with steeply plunging lineations and concentrically orientated folds in the outer shell. Diapirism is closely linked to magma emplacement mechanisms. Floor folds in the country rocks were initiated in the interfinger areas of a fingered intrusion. With further magma additions and the coalescence of intrusion fingers into a single sheet, interfinger folds matured into large diapiric periclines which rose to the upper levels of the magma chamber. Strain rates estimated from strain analyses, pericline geometry and model cooling calculations are in the order of 10-14 S-1, corresponding to diapiric uplift rates of 0.6 cm/yr. Diapirism is broadly compatible with a N-S extension in the Olifants River area during emplacement of the Rustenburg Layered Suite. On a regional scale, this is indicated by existence of a major EW dyke swarm that coincides with the long axis of the Bushveld Complex. The accommodation of the Bushveld Complex into the Kaapvaal Craton was facilitated by a combination of craton-wide extension that accompanied plume related magmatic underplating, and loading of the Bushveld Complex. Isostatic adjustment in response to Bushveld Complex subsidence resulted in further development of large basement domes around the perimeter of the Bushveld Complex. / Thesis (Ph.D.)-University of Natal, Durban, 1998.
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Sedimentary models for coal formation in the Klip River coalfield.Christie, Angus David Mackay. January 1988 (has links)
The primary objective of this study was to establish sedimentary models for
peat formation in the southern part of the Klip River coalfield during Ecca
(Permian) times and to assess palaeoenvironmental controls on coal seam
behaviour and distribution. In order to achieve this approximately 2 400
borehole logs and 25 field sections were collected.
The coal-bearing Vryheid Formation records early to late Permian
fluvio-deltaic sedimentation within the northeastern main Karoo basin. Three
informal lithostratigraphic subdivisions, based on the investigations of
Blignaut and Furter (1940, 1952), are proposed: the Lower zone, Coal zone and
Upper zone.
An examination of the structural framework and history of the northeastern
Karoo basin reveals that the southern and western boundaries of the Klip River
coalfield are defined by zones of rapid basement subsidence : the Tugela and
Oannhauser Troughs respectively. There is some doubt as to the locality of the
source area to the rivers emptying into the Ecca sea. Ryan (1967) postulated
the "Eastern Highlands" situated off the present southeast African coast, but
it is contended that the Swaziland area, situated no more than 200 to 300 km to
the northeast of the Klip River coalfield, constituted a more plausible source
area.
The Lower zone represents sedimentation along a westerly to southeasterly
prograding coastline dominated by high-constructive lobate or braid deltas, but
also showing significant influence by wave processes. The Coal zone, which
varies in thickness from 35 to 60 m, represents a major phase of coastal
progradation and braided-river deposition on extensive alluvial plains.
Significant coal seams formed only during periods of fluvial inactivity, the
duration of which was dependent on source-area processes.
Coal seam geometry and behaviour in the Klip River coalfield were not
influenced by the depositional environments of associated clastic sediments.
The following factors were found to have of profound influence in determining
the extent, distribution and rate of peat accumulation:
1. Platform stability and temporal and spatial variations therein.
2. The absence or presence of penecontemporaneous clastic sedimentation.
3. Duration of periods of peat formation.
4. Lithology and topographic expression of clastic sediments underlying
peat-forming swamps.
The peat-forming phase of the Vryheid Formation was terminated by an
extensive transgression brought about by an eustatic rise in basin water-level
and/or an increased rate of platform subsidence. / Thesis (Ph.D.)-University of Natal, 1988.
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A combined sedimentological-mineralogical study of sediment-hosted gold and uranium mineralization at Denny Dalton, Pongola Supergroup, South Africa.Hicks, Nigel. January 2009 (has links)
The ~2.98 - 2.87 Ga Pongola Supergroup in South Africa is subdivided into the lower volcano-sedimentary Nsuze Group, and the upper sedimentary Mozaan Group, the latter comprising a several kilometres thick succession of fluvial to shallow marine sandstones and shales. Thin beds of gold and uranium-bearing conglomerates are locally present in the Mandeva Formation near the base of the Mozaan Group and have been mined at Denny Dalton in northern KwaZulu-Natal. The style of mineralization strongly resembles that of the Witwatersrand goldfields, however appears to be of low grade and limited tonnage. The ~1 m thick basal conglomerate, the “Mozaan Contact Reef” (MCR, herein referred to as CG 1), at Denny Dalton hosts erratic gold and uranium mineralization. The conglomerate is laterally discontinuous and occupies east-northeast trending scour channels. Polymict, matrix-supported conglomerates are common, while clast-supported conglomerates are rare. Well rounded, pebble to cobble-sized clasts of vein quartz and chert are hosted in a sandy matrix of quartz, pyrite and sericite. Where mineralized, the CG 1 hosts abundant rounded pyrite grains, interpreted as detrital in origin, with subordinate U-bearing minerals, such as brannerite and uraniferous leucoxene. Rounded detrital pyrite occurs in three phases, compact, porous and radial. Gold forms inclusions within massive pyrite grains, which are concentrated in shoots associated with the basal parts of the channel scours. SEM-EDX results, as well as the high reflectivity of the gold show a high Ag content, indicative of a primary origin for the gold within the pyrite grains. Uranium within CG 1 is hosted primarily as secondary inclusions of uranium within black chert pebbles within the basal cobble-sized regions of the conglomerate. Geochemical comparison of the chert pebbles at Denny Dalton with similar chert from the Nondweni Greenstone Belt indicates that the uranium is secondary in origin as no U anomalies occur in the Nondweni chert. Geochemical and SEM analysis of the uppermost conglomerate (CG 4) indicate the presence of uraninite and coffinite within the uppermost horizon as both fillings of voids within, and coatings on, detrital pyrite grains. Palaeocurrent data indicate a likely source terrain for the detrital material to the west of the inlier. This orientation, as well as differing mineralogical and sedimentological aspects between the Mandeva Formation and the correlative Sinqeni Formation within the main Pongola basin, indicate a separate and more proximal provenance for the auriferous conglomerates of the White Umfolozi Inlier. The Mandeva Formation is a fluvial to shallow marine sequence that has been affected by cyclic sea-level changes. The basal conglomerates of the Denny Dalton Member were deposited in a proximal braided alluvial plain environment. The conglomerates fine upwards into trough cross-bedded quartz arenites which appear to have been deposited as shallow marine sands in a shoreface environment. They are overlain with a sharp contact by a laterally extensive unit of polymictic conglomerate which represents a transgressive ravinement surface within the wave zone and marks the onset of a major marine transgression into the Pongola basin. The conglomerate is overlain by massive grits and coarse-grained quartz arenite. This unit is overlain with a sharp and locally sheared contact by shales and subordinate banded iron formation which can be traced into other parts of the Pongola basin and indicates continued rapid transgression onto large parts of the Kaapvaal Craton with deeper marine, sub-storm wave base sediments being deposited in quiet-water environments on a sediment-starved shelf. The heavy mineral assemblage as well as bulk geochemical data is consistent with a granitoid-greenstone source terrain for the conglomerates and sandstones. The geochemical composition of chert pebbles from the CG 1 is similar to the composition of cherts present in the Nondweni Greenstone Belt that is situated ~30 km west of the White Umfolozi Inlier. Multiple sulphur isotope (ä34S, ä33S) values for detrital pyrite from the MCR are consistent with an origin from mantle-like rocks, such as hydrothermal sulphide-quartz veins in a granitoid-greenstone setting. Palaeocurrent, mineralogical and geochemical data all point to a likely granitoid-greenstone provenance to the west of the White Umfolozi Inlier. / Thesis (M.Sc.)-University of KwaZulu-Natal, 2009.
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Rock mass rating and slope stability analysis of quarry faces within the dywka [i.e. dwyka] tillite of KwaZulu-Natal.Kujawa, Thomas. January 2002 (has links)
Dwyka tillite quarries in the Province of KwaZulu-Natal have shown remarkable stable slopes faces even though some of them were quarried over 30 years ago. This can be
attributed to their resistance to weathering, the high degree of joint surface roughness, the general lack of any joint infill and the limonitic staining found on most weathered joint surfaces. The latter appears to increase joint roughness. The high percentages of joints terminating within the rock mass or against other discontinuities as well as their low persistence results in a high degree of joint interlocking. These are shown to be very important factors contributing to the overall slope stability. Detailed discontinuity surveys were carried out at five different quarries located throughout the KwaZulu-Natal region. Only three of these quarries are presently being quarried. This allowed the study and comparison of joint and slope stability characteristics for both the older, more weathered rock faces and those of the recently quarried, and thus fairly unweathered rock faces. Joint orientation data from the various sites show that two to three sets of high angle joints and one low angle joint set are common. The potential of wedge and planar failure is therefore very high. The steeply dipping discontinuities also promote the potential for flexural toppling failure and this was noted in several of the quarry faces. Recognised geotechnical techniques and computer models were used to establish potential modes of failure and to estimate factors of safety. Wedge failure, at partially saturated and saturated conditions, was identified as being the main source of potential slope instability on the quarry rock faces. The quality of the rock mass of each slope was also classified according to various rock mass classification systems. The rock mass quality generally was rated as being 'fair' to
'good', meaning that slopes are partially stable to stable. The results of each rating system were also compared. / Thesis (M.Sc.)-University of Natal, Durban, 2002.
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The geology and rock mass quality of the Cenozoic Kalahari Group, Nchwaning Mine Northern Cape.Puchner, Richard A. January 2002 (has links)
With the extension of the Nchwaning Mine shaft complex in the Northern Cape
Province, various geological and geotechnical complications needed to be identified in
order to ensure correct use of tunnelling methods and support techniques. An
understanding of the geological history of the area and the resulting geotechnical nature
was important in defining the rock mass quality ahead of shaft development. A total of
12 geotechnical boreholes were drilled, and an additional 18 old boreholes revisited to
accurately detennine the stratigraphy, geological structure and associated weathering
effects. Various soils and rock testing helped quantify the materials encountered.
Sands of the Gordonia Fonnation form the surface cover of this area, and together with
the weathered calcrete, calc-arenite, conglomerate and clay, they form part of the
Cenozoic Kalahari Group. The 30m thick basal unit of red clay is common throughout
this region. This silty clay material is problematic in that it is expansive and
hygroscopic. The clay unit rests unconformably on folded, faulted and highly weathered
shale of the Proterozoic Lucknow and Mapedi Formations of the Olifantshoek
Supergroup. Unconformably below this sequence lies the manganiferous ore deposits of
the Hotazel Member, which is contained within the Voelwater Formation of the
Griqualand West Supergroup.
For the development of the decline shaft through the Gordonia Formation a box cut was
excavated to a depth of 25m. The anticipated poor geotechnical conditions for a further
125m below the Gordonia sands called for high quality permanent tunnel support in the
upper weathered horizons. Barton's Q-analysis was adopted as a recognized tunnelling
quality index to predict and quantify the rock mass characteristics ahead of the shaft.
The highly variable and generally low Q-values from borehole core analysis indicated
that precast tunnel lining be used for 800m (at 11.5°) through the entire weathered
Cenozoic sequence and into the weathered shales immediately below the Red Clay. / Thesis (M.Sc.)-University of Natal, Durban, 2002.
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Sedimentology, stratigraphy and geological history of part of the northern KwaZulu-Natal coastal dune cordon, South Africa.Sudan, Pascal. January 1999 (has links)
The northern KwaZulu-Natal coast is backed by a continuous aeolian dune cordon that rises
in places, to a height of more than 100 metres and a width of 2 kilometres. This MSc thesis
documents the geomorphology of the area, as well as the mineralogical, geochemical and
textural variation of nine boreholes within a small part of the coastal dune cordon between Lake
Nhlabane and Cape St.-Lucia. The results provide useful constraints on the identification of
individual beach and aeolian dune systems, their age relationships and spatial distribution.
Aeolian dunes within the coastal dune cordon were studied using aerial photographs and
grouped into five dune classes that reflect their relative age. These comprise 1) a system of
highly weathered dunes inland of the present coastal dune cordon, that are thought to represent
older dune cordons; 2) a system of weathered and reworked dunes located on the most inland
portion of the coastal dune cordon; 3) a less altered, large field of linear parallel dunes located in
the northern part of the study area; 4) a system of large scale parabolic dunes; and 5) a system of
coastal, relatively unweathered small parabolic dunes.
Mineralogy, geochemistry, texture and SEM analysis of borehole samples revealed a
complex internal structure within the present coastal dune cordon. In the most inland part of the
dune cordon, a basal light grey unit (Unit K) presents similar characteristics to the Kosi Bay
Formation. This is overlain by Unit A, comprising beach and dune systems, characterised by a
very high heavy mineral content. Unit A also forms the basal unit of the central and coastal
portions of the dune cordon. Unit B contains a mixture of reworked sediments from Unit A and
younger sediments. Aeolian Units D and E form the upper part of the dune cordon. Units D and
E were derived from beach - foredune systems and contain a high carbonate bioclast content.
All units are interpreted to be derived from immature sediment from the Tugela River and
mature sediment from the continental shelf. In the southern part of the study area, an additional
unit (Unit C) with unique characteristics has been interpreted as an aeolian deposit reworked
from local fluvial sediments. The units identified from their sedimentological characteristics can
be directly correlated to the regional dune classes identified from the geomorphology.
Luminescence dating of two calcareous dunes was undertaken, revealing that only the
sediment of the small coastal parabolic dunes (Dune Class 5, Unit E2) is of Holocene age. The
deposition of the large field of linear dunes (Dune Class 3, Unit D2) took place between 15 000
and 11 000 BP, during the marine transgression following the last glaciation. Luminescence
dating also indicated that both dunes were subject to at least one major reworking event.
A study on the weathering characteristics of the dunes can be used to attribute a relative age
to the nine sedimentological units. With the help of sea level curves and the two luminescence
dates, the nine units were attributed an approximate absolute age and regrouped into four
sediment packages thought to broadly represent four interglacial periods. The three younger
packages are attributed to the penultimate interglacial (lower part of Unit A), last interglacial
(upper part of Unit A, Units B and C) and "Holocene" interglacial (Units D and E). Hence the
northern KwaZulu-Natal coastal dune cordon under study represents a complex stacking of
three generations of coastal dune cordons, and appears to be constituted of sediments with age
ranging from at least two hundred thousand years ago to present.
The oldest sediment package (Unit K), interpreted as the Kosi Bay Formation, and the older
dune cordons (Dune Class I) must be older than 200 000 years, which is older than considered
by previous studies. The "Holocene" dune cordon (Units D and E) is interpreted as the Sibayi
Formation. / Thesis (M.Sc.)-University of Natal, Durban, 1999.
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Mechanisms of sill and dyke intrusion.Kattenhorn, Simon Allen. January 1994 (has links)
Mechanisms of sill and dyke intrusion require an understanding of fracture growth,stress distributions and intensities, dilation,intrusion rates, hydraulic pressure,host-rock effects,en echelon fracture arrays,and flow direction. The methods of previous studies have been applied to natural sill and dyke examples of the Karoo Igneous Province in northern Natal . An en echelon array of Jurassic dolerite sills occurs within Permian Ecca sediments along the Mhlatuze River, west of Empangeni. Dolerite emplacement occurred as two intrusive phases. The first phase resulted in thick, . coarse-grained dolerite sills. The second phase produced relatively thinner, fme-grained sills. The intrusion of fmegrained dolerite into older sills is demonstrated by abrupt variations in the whole-rock and mineral geochemistry profiles across the sills. Syn-crystallisation effects such as crystal settling and fractionation, and post-crystallisation hydrothermal activity is also manifested in the mineralogical and geochemical changes across the sills. The fine grained doleriteis associated with xenolithic dolerite which represents a contaminated magma propagation front of the fine-grained dolerite. The higher viscosity of the xenolithic dolerite hindered propagation, and was thus overtaken and engulfedby the mainmagmapulse. Consistent sinistral off setting of sill segments is interpreted to be the result of a fingered sill periphery intruding an en echelon fracture array. Dilation of individual segments, or fingers, occurred simultaneously. Subsequent interaction of near-tip stresses induced inwardly propagating curvature of adjacent segmentsin the array.Resultant linkage has produced a stepped-sill geometry; sill propagation and flow directions were orthogonal to the plane of linkage. The flow direction is confirmed by shape preferred-orientations of acicular mineral grains within the chilled margins of the sills, indicating the direction of flow to be perpendicular to the plane of the en echelon array, and parallel to strike directions of offset surfaces that link adjacent sill segments. Multiple dyke intrusion is examinedat an outcrop of the Rooi Rand Dyke Swarm, along the Pongola River. Individual intrusive episodes are identifiable on the basis of chill-zone relationships. The pattern along the Pongola River suggests that younger intrusive episodes frequently intrude through the centres of older dykes. A three dimensional analysis of en echelon dyke let segments allows a re-construction of the dilation history,and provides an explanation for the development of blunt-ended intrusion segments. Mineral geochemistry anomalies around dyke tips suggests possible facilitation of incipient fracture via decreases in mineral strengths manifested by geochemical changes. A statistical digital analysis of micro-phenocryst orientations within chilled dyke margins is shown to provide a viable method to ascertain magma flow directions within dykes, and may thus be a useful tool for future investigations. / Thesis (M.Sc.)-University of Natal, 1994.
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The geology and geochemistry of the Rooi Rand Dyke Swarm.Meth, Deanna Lorrine. January 1996 (has links)
The Jurassic Rooi Rand dolerite dyke swarm was emplaced sub-parallel to the Lebombo
Monocline during the initial stages of Gondwana breakup. The dykes extend northwards
from the southern Lebombo region in northern KwaZulu-Natal, into central Swaziland,
spanning a distance of approximately 200 kilometres with a width between 10 and 22
kilometres. Detailed mapping of a 600m-Iong section on the Pongolo River, established at
least eleven phases of intrusion. Each dyke age was systematically sampled and analysed for
whole-rock major, trace and rare earth element composition, as well as mineral chemistry.
Selected samples were analysed for stable isotopes.
In addition to notable intra-dyke chemical variations, there is also a high degree of inter-dyke
mineralogical and geochemical variation, each dyke age bearing distinct geochemical
characteristics. The apparent geochemical trend is not one of simple fractionation with time.
Dyke chemistries are closely linked to magma genesis and magma volumes with time.
Evolution of the magmas may be described in terms of varying degrees of partial melting and
fractional crystallization, with a small degree of crustal contamination.
Major, trace and rare earth element data indicate a lithospheric mantle source for the
majority of dyke phases, and an asthenospheric source for only two of the eleven ages.
Contrary to this, isotopic data (oxygen and radiogenic) indicate an enriched asthenospheric
source for all the dolerites. This suggests that all ages may have originally been derived
from the asthenosphere, with the majority of ages being intruded into the lithospheric mantle
to later undergo partial melting and fractional crystallization, with some contamination.
Previous studies assumed an asthenospheric source with depleted MORB-like rare earth
element profiles to be representative for the majority of Rooi Rand dolerites.
The Rooi Rand dolerites appear to display a geochemical link with the southern Sabie River
Basalt Formation, as well as the Lebombo rhyolites. Magmatic evolution of the dykes was
intimately linked to the initial rifting processes of lithospheric stretching and asthenospheric
upwelling, which in this case concluded in a classic failed rift situation. / Thesis (M.Sc.)-University of Natal, 1996.
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Assessment of the permeability of Vryheid formation sediments.Venter, Bernardus Jacobus. January 1994 (has links)
Permeability is that physical property of a porous medium that controls the flow of fluids through that medium. The flow of methane and water may be induced by the excavation of a mine opening in
methane-bearing strata. Methane flow into a mine opening constitutes one of the biggest hazards in the coal mining industry. It is poisonous to humans and can ignite at concentrations as low as 5 % per volume and create explosions in the presence of coal dust from mining. If the flow of methane and/or water into the mine opening becomes blocked by an impervious layer, excessive pressures may develop, particularly in the roof strata of the mined seam, which can lead to roof falls. In order to characterize the flow of methane and water into and around the openings in a mine, that was plagued by roof falls suspected of being the result of excessive fluid pressure build-up, a large scale laboratory investigation of the permeability of the roof sediments of the working coal seam in the area was undertaken. The permeability was measured under atmospheric conditions by means of a modified Ohle permeameter, and under triaxial conditions with the aid of a modified Hoek cell. The
permeability of the sediments towards methane and water was measured. Nitrogen was used as a control because it is much less reactive than methane towards the sediments used in this project.
It was found that the permeability decreases with increasing gas pressure, in the case of gas being the permeating fluid, and increased with increasing water pressure, in the case of water being the permeating fluid. In some instances anomalous plots of permeability versus reciprocal mean gas pressure were obtained. These were attributed to the effects of methane adsorption or the Klinkenberg effect, and a possible method to determine which of the two processes is dominant is discussed. To characterize the flow in the roof strata of the coal seam being mined, the permeability was
correlated to fades type. The different fades types were numbered from 1 to 14 with increasing grain size for ease of correlation. Due to the variable nature of the sediments, even in a fades type, no single
permeability could be obtained for a fades type. Instead permeability ranges were obtained for each fades type. The definition of the lower and upper limits for each range were found to be dependant on
the number of tests done on samples for that fades type. Nonetheless a relationship of increasing permeability with increasing grain size was found in the coarser grained fades (facies type 8 and higher). For the fIner grained fades types the permeability was found to decrease with increase in grain size. A graph could be constructed for use in predicting possible hazardous zones by identifying the fades type and then reading the permeability range that can be expected off the graph. Due to the variable nature of the sediments, the graph is, at this time, only applicable to the areas where the samples were obtained. A permeability prediction graph for all localities would be an ideal but is beyond the scope of this project. Such a graph, and the methods discussed have a wide range of applications in the coal mining and methane gas exploitation industries. / Thesis (M.Sc.)-University of Natal, Durban, 1994.
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The petrology, geochemistry and classification of the Bien Venue massive sulphide deposit, Barberton mountain land.Murphy, Philip William. January 1990 (has links)
The Bien Venue massive sulphide deposit is associated with a felsic volcanic succession
developed in the north-eastern part of the Barberton Greenstone Belt, Eastern Transvaal. The
deposit is situated 8km east-north-east of Louw's Creek between the Lily Syncline to the south
and the Stentor Pluton to the north. The stratigraphy of the Onverwacht, Fig Tree and
Moodies Groups in the vicinity of the deposit is poorly documented, and the exact stratigraphic
position of the host felsic volcanics is not known. They are tentatively correlated with the felsic
volcanics from the Theespruit Formation, Onverwacht Group.
The felsic volcanics have undergone low-grade greenschist facies metamorphism and occur as
quartz-sericite schists. Detailed petrography enables sub-division of the volcanic succession into
distinct units. A lapilli metatuff unit hosts the base metal and precious metal mineralisation.
The sulphides are best developed in the upper part of this unit, together with intercalated
barite-rich horizons and cherts. A series of structural events have modified the attitude of the
lithological units and disrupted the continuity of the orebody.
The orebody comprises stratabound lenses of massive to semi-massive and often banded
sulphides, as well as disseminated sulphide mineralisation. The dominant base metal mineralogy
consists of pyrite, sphalerite, chalcopyrite, galena and tennantite. Native silver and various
copper-silver sulphides are also associated with the base metal sulphides. A vertical zonation
of the mineralisation exists, from pyrite-chalcopyrite-rich ore in the footwall, to pyrite -
chalcopyrite-sphalerite-galena-barite-rich ore towards the hanging wall.
Geochemical studies indicate that the Bien Venue lithologies are rhyolitic to rhyodacitic in
composition and show a calc-alkaline affinity. The mobility of some elements at Bien Venue
has been clearly demonstrated. This is believed to be associated with hydrothermal alteration
that has led to SiO2 and MgO enrichment, as well as K2O depletion, in the wall rocks of the
deposit.
The geological setting and nature of the mineralisation at Bien Venue suggest that it is an
example of a volcanogenic exhalative sulphide deposit. In terms of the classification scheme
suggested by Hutchinson (1973, 1980), Bien Venue would best be described as a Primitive type
deposit that contains barite. / Thesis (M.Sc.)-University of Natal, 1990
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