The structure of the Swansea Valley Disturbance between Clydach and Hay-on-Wye,South Wales

The Swansea Valley Disturbance is one of four NE-SW belts of faulting and folding which cross the northern limb of the South Wales Coalfield syncline at variance with the normal E-W Variscan structures. The Disturbance extends from Hay-on-Wye (Herefordshire) southwestwards to Clydach (near Swansea) and may extend northeastwards to Titterstone Clee Hill (near Ludlow) and southwestwards along the Tircanol Fault to Swansea Bay. The main structural elements of the Disturbance are: impersistent NE-SW folds; NE-SW normal faults; and NE-SW and NNW-SSE wrench faults. The NE-SW structures are confined to a narrow zone which seldom exceeds two kilometres in width. It is suggested that this narrow belt of faulting and folding has been controlled mainly by sub-Devonian basement structures, which involve faulting and/or folding. The effect of the Variscan compression was to reactivate the basement structure, which had the effect of resolving this compression along the disturbed zone to produce sinistral wrench movements. The structure of the Disturbance has been complicated by folding, produced by the Variscan force driving the Upper Palaeozoic rocks against the Lower Palaeozoic block. It is concluded that the main movements are of Variscan age and that vertical movements may have taken place in post-Carboniferous and post-Neogene times.     

The form of the intrusive complex at mount dromedary,New South Wales

In the past the Mount Dromedary igneous complex has been regarded as a differentiated laccolith, with the more felsic banatite at the summit of the mountain, monzonite on the lower slopes and pyroxenite at sea‐level.

Evidence is put forward to show that this is not the case and that the form is that of a stock or ring‐dyke with very steep contacts.

The monzonite has been emplaced by forceful injection and the banatite by permissive emplacement along a vertical, cylindrical fracture in the monzonite. The pyroxenite may form a separate dyke or stock.     

Granite-hosted gold mineralization at Timbarra, northern New South Wales, Australia

The Timbarra gold deposits, located in the southern New England Fold Belt of New South Wales, Australia, represent an economically significant and distinctive member of the intrusion-related class of gold deposits. The five known deposits possess a total identified mineral resource of 16.8 Mt at 0.73 g/t gold, for a total of 396,800 contained ounces. The granites in the Timbarra region form a texturally complex, zoned pluton. The gold deposits are found within the Stanthorpe leucomonzogranite (242 to 238 Ma), which intrudes and forms a core to the more mafic, barren, Bungulla monzogranite (248 to 243 Ma). Gold is disseminated in the roof zone (upper 240 m) of a fractionated, magnetite- and ilmenite-bearing, I-type leucomonzogranite phase of the Stanthorpe body. The entire gold resource occurs in the areally extensive main leucomonzogranite pluton and is hosted by a medium- to coarse-grained granite. Disseminated ore is present in all five deposits, comprises >95% of the overall resource at Timbarra, and occurs predominantly as gently dipping, tabular to lenticular bodies that are conformably constrained beneath a fine-grained aplite carapace and internal aplite layers. The disseminated ore consists of gold-bearing muscovite-chlorite-carbonate alteration and infill of primary miarolitic cavities within massive leucomonzogranite or microgranite, and contains no discernable vein, joint, or fracture control at the outcrop or hand specimen scale. Structurally controlled mineralization forms the remaining 5% of the Timbarra resource, and comprises minor, low-density (0.02 to 0.25 per meter), vein-dikes and quartz-molybdenite veins emplaced along steeply dipping east-southeast, east-northeast, and north-northeast striking cooling joints. Both mineralization styles and alteration share a common paragenetic sequence of mineral precipitation. Quartz, perthitic K-feldspar, minor biotite, and albite are the earliest and most abundant infill minerals and commonly line primary cavities and vein-dikes. Subsequent minerals include coeval arsenopyrite, pyrite, fluorite, and molybdenite. The latest minerals include muscovite, chlorite, gold, calcite, silver-bismuth telluride, lead-bismuth telluride, and rare galena and chalcopyrite. The gold ore has a low total sulfide mineral concentration (Б%). Ore contains elevated concentrations of Bi, Ag, Te, As, Mo, and Sb; gold is strongly correlated with Bi, Ag, and Te, but only weakly with Mo, As, and Sb. Gold grains are generally <1 to 50 µm in size, but rarer grains as large as 1 mm in diameter have been observed. Gold fineness ranges from 950 to 600, and varies both within and between individual grains for a given deposit. The moderately oxidized I-type host granite, low-sulfide (Б%) ores, Au-Bi-Ag-Te geochemical signature, muscovite-chlorite-carbonate alteration assemblage, and low-salinity aqueous and carbonic fluids suggest that Timbarra is part of the newly recognized intrusion-related gold deposit class. Timbarra is distinguished from other intrusion-related gold deposits by the disseminated mineralization style within pervasively altered granite, forming gently dipping, tabular to lenticular ore zones.     

Morphometry of gibber gravel at Mt Sturt,New South Wales

Mt Sturt is a duricrusted residual, from which particles of silcrete are discharged on to flanking slopes and surrounding pediments. Dimensional analysis of the particles yields log‐normal curves, bimodal on the crest but unimodal elsewhere, with an orderly downslope decrease in median dimensions. The rate of decrease appears insufficient to reduce the particles to sand size within conceivable limits of pediment length. Analysis of shape indices gives normal distributions with no significant down‐slope change of index, except for the roundness index which tends to assume distributions of the Poisson type and to increase in value downslope. The general correspondence between observed distributions and theoretical curves is close, although it seems likely that gilgai can disturb to some extent the distribution of dimensions in particular samples.     

Arsenic contamination at the Mole River mine,northern New South Wales

Mining and processing of arsenopyrite ore at the Mole River mine in the 1920–1930s resulted in abandoned mine workings, waste dumps and an arsenic oxide treatment plant. Weathering of waste material (2.6–26.6 wt% As) leads to the formation of water soluble, As‐bearing mineral salts (pharmacolite, arsenolite, krautite) and sulfates which affect surface waters after rainfall events. Highly contaminated soils, covering about 12 ha at the mine, have extreme As (mean 0.93 wt%) and elevated Fe, Ag, Cu, Pb, Sb and Zn values compared with background soils (mean 8 ppm As). Regionally contaminated soils have a mean As content of 55 ppm and the contaminated area is estimated to be 60 km². The soils have acquired their metal enrichments by hydromorphic dispersion from the dissolution of As‐rich particulates, erosion of As‐rich particulates from the dumps, and atmospheric fall‐out from processing plant emissions. Stream sediments within a radius of 2 km of the mine display metal enrichments (62 ppm to 27.5 wt% As) compared with the mean background of 23 ppm As. This enrichment has been caused by erosion and collapse of waste‐dump material into local creeks, seepages and ephemeral surface runoff, and erosion and transportation of contaminated soil into the local drainage system. Water samples from a mine shaft and waste‐dump seepages have the lowest pH (4.1) and highest As values (up to 13.9 mg/L), and contain algal blooms of Klebsormidium sp. The variable flow regime of the Mole River causes dilution of As‐rich drainage waters to background values (mean 0.0086 mg/L As) within 2.5 km downstream. Bioaccumulation of As and phytotoxicity to lower plants has been observed in the mine area, but several metal‐tolerant plant species (Angophora floribunda, Cassinia laevis, Chrysocephalum apiculatum, Cymbopogon refractus, Cynodon dactylon, Juncus subsecundus and Poa sieberiana) colonise the periphery of the contaminated site.     

The Prospect Alkaline Diabase-Picrite Intrusion New South Wales, Australia

The Prospect intrusion is a dish-shaped alkaline diabase-picritemass 315–400 ft thick intruded into shale at a depth ofabout 600 ft. Picrite, containing more than 25 per cent olivine,occupies the lower half of the intrusion. In the upper half,alkaline diabase, averaging less than 5 per cent olivine, isconcentrated under structural highs of the contact, and alkalineolivine diabase, containing 10 to 25 per cent olivine, is concentratedunder structural lows. These rocks are separated from the shaleby a fine-grained chilled margin. Vertical sections through the picrite zone show a regular antipatheticvariation of modal olivine and plagioclase with a zone of maximumolivine concentration near the bottom; bulk rock compositionsshow an antipathetic relation between MgO plus total iron andall other constituents. Modal and bulk composition variationsare more erratic in the upper half of the intrusion, but analcite,alkali feldspar, and opaque minerals reach maximum concentrationsin this part of the intrusion. The pyroxene content remainsnearly constant in the major rock types. Trends of olivine andplagioclase composition and grain size vary regularly with heightin the intrusion and cross boundaries between major rock typeswithout deflexion. Olivine becomes progressively more fayaliticfrom the base of the picrite zone to the upper chilled margin,but the plagioclase curve has a trend toward more calcic compositionsin the picrite zone. Mean sizes of plagioclase, pyroxene, andolivine increase upwards between the chilled margins. The lower chilled margin is slightly less mafic than the bulkcomposition of the intrusion and may represent a pre-emplacementdifferentiate, but the major part of the differentiation occurredduring emplacement at the present site. Grain size and otherdata indicate that crystallization took place more rapidly fromthe base than from the top of the intrusion, and a variety ofinternal structures indicate that crystallization and differentiationtook place as the magma was intruded over a considerable periodof time. As consolidation of the intrusion proceeded, the liquid becameenriched in all constituents except magnesium and ferrous ironuntil consolidation of alkaline diabase began (when about 70per cent of the whole intrusion had solidified); at that stagethe proportion of calcium, titanium, and ferric iron in theliquid was reduced and the proportion of silica, alumina, andalkalis increased. Processes of differentiation that contributed most to the originof the main rock types are: diffusion, independently of crystallization,of volatiles, alkalis, and possibly calcium into the structurallyhigh parts of the intrusion; gravity accumulation of olivinethat crystallized a short distance above the main front of consolidationas it moved upwards from the base of the intrusion; and upwarddiffusion of salic constituents and downward diffusion of maficones over concentration gradients produced by crystallization. Removal of volatiles from the lower part of the intrusion beforecrystallization reduced the oxidation ratio in the liquid andresulted in a low proportion of ferric iron minerals; crystallizationof abundant olivine (average composition about Fo₇₀), however,prevented enrichment of the liquid in iron. Addition of volatilesto the upper part of the intrusion retarded crystallizationand raised the oxidation ratio to a level at which a relativelyhigh proportion of ferric iron minerals crystallized. Subordinate processes that contributed to the formation of themain rock types as well as to less abundant ones include gravityaccumulation of heavy minerals that were dispersed in the magmaat the time of emplacement, filter pressing caused by localbuttressing around irregularities of the contact, crystal sortingby viscous flow, and gas transfer. Pegmatitic differentiates are ascribed to a complex diffusionprocess along pressure and concentration gradients caused byshear on laminar flow planes. Syenite may have originated byreplacement of pegmatite, but aplites occupy true dilationaistructures and apparently represent liquid remaining after crystallizationof the adjacent rock.     

The present-day stress field of New South Wales,Australia

The Australian continent displays the most complex pattern of present-day tectonic stress observed in any major continental area. Although plate boundary forces provide a well-established control on the large-scale (>500 km) orientation of maximum horizontal stress (S_Hmax), smaller-scale variations, caused by local forces, are poorly understood in Australia. Prior to this study, the World Stress Map database contained 101 S_Hmax orientation measurements for New South Wales (NSW), Australia, with the bulk of the data coming from shallow engineering tests in the Sydney Basin. In this study we interpret present-day stress indicators analysed from 58.6 km of borehole image logs in 135 coal-seam gas and petroleum wells in different sedimentary basins of NSW, including the Gunnedah, Clarence-Moreton, Sydney, Gloucester, Darling and Bowen–Surat basins. This study provides a refined stress map of NSW, with a total of 340 (A–E quality) S_Hmax orientations consisting of 186 stress indicators from borehole breakouts, 69 stress measurements from shallow engineering methods, 48 stress indicators from drilling-induced fractures, and 37 stress indicators from earthquake focal mechanism solutions. We define seven stress provinces throughout NSW and determine the mean orientation of the S_Hmax for each stress province. The results show that the S_Hmax is variable across the state, but broadly ranges from NE–SW to ESE–WNW. The S_Hmax is approximately E–W to ESE–WNW in the Darling Basin and Southeastern Seismogenic Zone that covers the west and south of NSW, respectively. However, the present-day S_Hmax rotates across the northeastern part of NSW, from approximately NE–SW in the South Sydney and Gloucester basins to ENE–WSW in the North Sydney, Clarence-Moreton and Gunnedah basins. Comparisons between the observed S_Hmax orientations and Australian stress models in the available literature reveal that previous numerical models were unable to satisfactorily predict the state of stress in NSW. Although clear regional present-day stress trends exist in NSW, there are also large perturbations observed locally within most stress provinces that demonstrate the significant control on local intraplate sources of stress. Local S_Hmax perturbations are interpreted to be due to basement topography, basin geometry, lithological contrasts, igneous intrusions, faults and fractures. Understanding and predicting local stress perturbations has major implications for determining the most productive fractures in petroleum systems, and for modelling the propagation direction and vertical height growth of induced hydraulic fractures in simulation of unconventional reservoirs.     

A pediment survey at middle pinnacle,near broken hill,New South Wales

Extensive and well‐developed pediments and pediplains in western New South Wales have hitherto received less than due attention in the literature. This paper records the details of instrumental survey and of excavation at The Pinnacles, near Broken Hill. It presents observation and analysis of slope, rock‐type, structure, and surficial cover, and discusses the significance of a peripediment which contains multiple soil profiles.     

Retrograde Schists of the Amphibolite Facies at broken hill,New South Wales

Aluminous, mafic, felsic, calcareous, and sulphide‐rich rocks have been involved in localized deformation and retrograde metamorphism at Broken Hill, western New South Wales, where retrograde schist‐zones intersect high‐grade, regional metamorphic rocks of the lower granulite facies (or the amphibolite‐granulite facies transition). Although technically retrograde, the schists contain mineral assemblages indicative of the lower amphibolite facies. The schist‐zones were formed by local folding, apparently as part of the third stage of deformation in the Broken Hill area.     

Ferrian tourmaline from Bungonia,New South Wales

New chemical, X‐ray and cell dimension data are presented for ferrian tourmaline in quartz‐tourmaline rock at three localities near Bungonia, New South Wales. The tourmaline is fine‐grained, normally euhedral, and forms up to 90% of the rock. It shows restricted solid solution between dravite and ferridravite, although some grains are zoned and others have an irregular, bipartite chemical variation. Tourma‐linisation is interpreted as being.related to late‐stage volatile emanations from the Marulan Batholith.     

The bedrock topography of the botany basin,New South Wales

The bedrock topography of the Botany Basin has been determined from seismic‐sparker records made in Botany Bay and Bate Bay, and from seismic‐refraction and gravity measurements on the Kurnell Peninsula. Supplementary information has been obtained from boreholes both on land and in the sea.

The Cooks and Georges Rivers formerly constituted the main drainage of the Basin and flowed generally southeastwards (beneath the present Kurnell Peninsula) and joined the Port Hacking River east of Cronulla. The depth of the bedrock channel of the former Georges River is 75–80 m b.s.l. at Taren Point, 90–95 m beneath the Kurnell Peninsula and 110–115 m at its junction with the Port Hacking River channel. The bedrock channel of the former Cooks River is about 30 m b.s.l. at Kyeemagh, its present entrance to Botany Bay, and it joined the Georges River at a location now 90 m b.s.l. beneath the Kurnell Peninsula.

A second drainage system existed in the north and east of Botany Bay and generated the present mouth beneath which the bedrock is now 110 m b.s.l. This channel followed a southeasterly course parallel to the present northern shore of Botany Bay and was separated from that of the ‘Cooks and Georges Rivers’ by a bedrock ridge which extended from beneath Sydney Airport to the northern extremity of the Kurnell Peninsula. Over much of its length this divide had a depth of about 30 m b.s.l.

The formation of the Kurnell Peninsula tombolo led to the diversion of the ‘Cooks/Georges River’ through the mouth of Botany Bay and subsequently led to the development of the bay. This change in the drainage system occurred when the sea was less than 30 m below the present sea level.     

Garnet Compositions at Broken Hill, New South Wales, as Indicators of Metamorphic Processes

Electron microprobe analyses of garnets in the finely bedded‘banded iron formations’ (BIF) of the Willyama Complexat Broken Hill reveal marked compositional changes from onegarnet to the next on a scale of 1–2 mm. Further, systematicanalytical traverses across bedding and along bedding show thecompositions of the garnets to change markedly from one finebed to the next, but to remain extremely uniform within individualbeds. In view of the minuteness of the domains involved it appearsevident that compositional variation cannot be attributed tovariations in metamorphic pressures, temperatures or oxygenfugacities. Neither can they be attributed to variation in garnet-matrixpartition functions, as most of the garnets occur in one simplematrix—quartz. It is concluded that in spite of the high (sillimanite) gradeof the relevant metamorphism, any equilibration of garnet compositions,and hence any associated inter-grain metamorphic diffusion,has been restricted to a scale of less than 1 mm; that garnetcompositions here reflect original rock composition on an ultra-finescale, and have no connotations concerning metamorphic grade;that, hence, the garnets must derive from a single precursormaterial, earlier suggested to be a manganiferous chamositicseptechlorite; and that the between-bed variation: within-beduniformity of garnet composition reflects an original patternof chemical sedimentation—a pattern preserved with theutmost delicacy through a period of 1800 x 10⁶ years and a metamorphicepisode of sillimanite grade.     

Foliation development in serpentinites, Glenrock, New South Wales

At Glenrock, near the southern end of the Peel Fault System, two fault zones are delineated by mélanges in which serpentinite is the main rock type.Protogranular and mylonitic textures are present in relicts of the parent peridotite and in blocks of massive pseudomorphic serpentinite that are surrounded by schistose serpentinite. In schistose serpentinite, the earliest foliation (S₁) is defined, microscopically, by the parallel alignment of platy and fibrous serpentine minerals (lizardite and chrysotile) and by trains of magnetite and flattened serpentine pseudomorphs after olivine and pyroxene. It is considered that the schistosity formed perpendicular to the direction of maximum shortening, under conditions in which lizardite and chrysotile were ductile, but antigorite was not, by breakdown of pre-existing serpentine minerals and new growth of lizardite and chrysotile.Post-s₁ foliations (S₂andS₃) superficially resemble crenulation cleavages in the field but, microscopically, show evidence of shear displacement and are referred to as microshear sets. They probably originated in the ductile-brittle transitional field of serpentine behaviour (Raleigh and Paterson, 1965).     

Eclogite from serpentinite near Attunga,New South Wales

Eclogite of high‐pressure low‐temperature origin occurs within the Great Serpentine belt of New South Wales. The presence of glaucophane‐bearing rocks and other medium to high‐pressure assemblages associated with the belt is similar in many respects to the Californian and Oregon occurrences. The chemical composition of the eclogite is characterized by low K₂O values comparable to many oceanic tholeiites, although one analysis is nepheline‐normative. Ti‐Zr‐Y ratios also show affinities to ocean‐floor basalts.

The garnet contains approximately 30% grossular and is strongly zoned from almandine (Alm 56%, Py 9%) at the core towards pyrope (Alm 44%, Py 27%) at the margin. Sodic augite contains 30–33% Jd, 4–7% Ac, and 72–74% Di+He.

Distribution of Fe and Mg between co‐existing garnet and pyroxene would suggest an increasing temperature during eclogite crystallization with a possible range from 290°C to 600°C and a minimum pressure of 7–12 kb.     

Zincian dolomite from broken hill,New South Wales

Many Broken Hill (New South Wales) specimens labelled ‘zinco‐calcite’ in museum and private collections are snow‐white, globular forms with a sparkling appearance, on a coronadite or limonite matrix. X‐ray diffraction and microprobe analyses show the globules have a core of nearly pure calcite, overlain by colourless, drusy zincian dolomite with up to 4 mol % ZnCO₃ and up to 7 mol % excess CaCO₃. Although Zn is abundant in the Broken Hill orebody, it apparently entered carbonate, mainly as smithsonite, only during formation of the oxidised zone.