Recent geological fieldwork, radiometric age dating of volcanic rocks, gravity and seismic reflection surveys have considerably refined our understanding of the tectonic evolution of the northern Kenya Rift. These data reveal that deep, half-graben basins up to 7 km thick were initiated west of Lake Turkana probably during Late Oligocene-Early Miocene times. The basins, bounded by easterly dipping faults, trend along the western side of the rift from Lake Turkana to the Elgayo Escarpment-Tugen Hills area. Some rift basins were episodically active from the Oligocene to the Pliocene while others were only active for a few million years. Some sag basins may have developed during periods of rifting quiescence. In the Turkana area the location of faulting gradually shifted eastwards with time. Volcanism both preceded and accompanied rifting. Within the Turkana area, volcanism moved south and east with time, beginning about 33 Ma (probably preceding half graben formation by a few million years) and continued to the present day. Extension along faults is greater in the Turkana area (between 25-40 km) and decreases southwards to probably 5-10 km or less in the southern Kenya rift. This pattern of extension values agrees with deep seismic refraction work (KRISP), which indicates thin crust in the Turkana area (about 20 km) that thickens to about 35 km south of Lake Baringo. The extension values, crustal thinning, age of volcanism and the timing of faulting to the south all point towards a southerly propagation of the rift.
This bulletin reviews Precambrian geology, including lithology, geochemistry, petrogenesis, structure, and metamorphism, in the vicinity of Atikokan, northwestern Ontario. The area spans approximately 1100 km2 of the volcano-plutonic Wabigoon Subprovince and the metasedimentary Quetico Subprovince - two large linear lithostructural elements of the Superior craton. Nineteen major rock units are classified into pre- to synvolcanic intrusions, supracrustal rocks, and syn- to postvolcanic intrusions. The early intrusive suite comprises four varieties of tonalite and tonalite gneiss, the oldest of which is dated at 3001 Ma (U/Ph zircon). Tonalite is concentrated mainly in the Marmion batholith whereas gneisses occupy belts and a large complex in the north. These rocks probably originated by melting of a pyroxene granulite of tholeiitic composition. The Marmion batholith is unconformably overlain by supracrustal rocks of the Steep Rock Group consisting of discontinuous metaconglomerate and 111etasandstone (Wagita Formation) , limestone beds (Mosher Carbonate Formation), ironsto11es (Jolliffe Ore Zone Formation), and an ultramafic pyroclastic rock (Dismal Ashrock Forma1ion). The unconformity typically comprises a 2 to 10 m transition zone from tonalite through altered.friable to11alite and quartz-sericite "grit" 10 bedded metasediments. The Jolliffe Ore Zone Formation was mined from 1944to1979 and yielded 100 million tonnes of mainly goethite ore. The upper contact of the Dismal Ash rock Formation is tectoni:ed and poorly exposed and precludes clear definition of stratigraphic relations of the Steep Rock Group to contiguous metavolcanic rocks. Jn addition to the ashrock, metavolcanic rocks include mafic pillow flows and intermediate to felsic flows, tuffs, and breccias. The ashrock is unusual amo11g Archean komatiites in its dominantly pyroclastic mode of occurrence and enriched incompatible trace element composition. The ultramafic magma may have formed by melting of anomalously enriched mantle or by interaction with sialic crust. The mafic lavas are typical Archean tholeiites. They probably evolved by fractio11ation of more primitive high-magnesium basalt. The intermediate to felsic metavolcanic rocks have relatively high contents of compatible trace elements and other geochemical characteristics, which are i11consiste11t with an origin by fractionation of the mafic lavas. Processes of magma mixing or assimilation are required to explain the petrogenesis of these rocks. Units of elastic metasediments i11 the metavolcanic belts are made up of agglomerate, sandstone, conglomerate, and greywackelargillite. Volumi11ous turbidites were derived mainly from an intermediate to felsic volcanic source with a lesser component of tonalite and mafic vo/r·c,11,",- detritus and were deposited in the Quetico basin about 2695 Ma ago. Although some metagabbro dykes predate deposition of the Steep Rock Group, the majority are grouped with syn- to postvolcanic intrusions. Metagabbro dykes and sills are partirnlarly common in the Steep Rock belt and compose up to 30 per ce11t of some felsic intrusions such as the Marmion batholith. Dioritelhornblendite occupies a stock central in the area and thi11 units marginal to metavolcanic and gneiss belts. The syn- to postvolcanic felsic intrusions range in size and form from small dykes in gneisses to plutons. U!Pb zircon dates range from 2936 Ma for tonalite to 2665 Ma for granite of the Eye-Dashwa pluton. The monzodiorite rim of this youngest pluton could have been derived by partial melting of a lithophile-element-enriched mantle source. The regional linear disposition of Quetico metasediments adjacent to Wabigoon metavolcanic rocks has been attributed to subduction-driven accretion of trench-fill turbidites (Quetico) against the Wabigoon volcanic arc about 2695 Ma ago. Accretion was followed hy strong dexrral transpression and imposed a pervasive east-west strike to foliations, bedding, and isoclinal folds in Quetico metasediments. Metamorphic grade increases south toward late granites at the central axis of the Quetico Suhprovince. The Wabigoon Subprovince is dominated hy large felsic oval structures that typically have a felsic plutonic core, an outer gneissic envelope, and concentric foliations. Belts of folded supracrustal rocks and mafic gneisses separate oval structures and can be metamorphically zoned with greenschist cores and amphiholite rims. This structural and metamorphic pattern may result from emplacement and spreading of hot, low-density felsic plutons and gneisses in oval structures that shortened and contact metamorphosed supracrustal rocks in adjacent belts. Dip-slip faults occur at the southwestern margin of the Dashwa oval structllre and within the Steep Rock belt; the Marmion batho!ith is cut by a complex, northeast-trending network of faults. The Eye-Dashwa pluton was pervasively faulted and fractured during a brittle deformation event at about 2300 Ma. Mild fracturing occurred at about 1100 Ma. Fractures are open and transmit groundwater mainly within 200 m of surface.
The concept of a risk related value of the spend for saving a statistical life (VSSSL) is advanced for use in cost-benefit studies across the power generation sector, and the nuclear industry in particular. For illustrative purposes, a best estimate VSSSL is set based on HSE guidance at 2 M pounds. Above a risk of 10(-3) y(-1) it is assumed that the VSSSL may approach this maximum sustainable value. As the risk reduces so does the VSSSL. At a risk level of 10(-6) y(-1) a VSSSL of 0.5 M pounds is applied. For risks below 10(-9) y(-1) the value of further risk reduction approaches zero, although a nominal VSSSL of 10 k pounds is applied as a pragmatic way forward in this study. The implications of adopting this concept as an aid to decision making in determining the spend on radiological dose reduction measures are illustrated through a worked example with a banded approach to estimating collective dose.
Abstract.A risk related Value of Spend for Saving a Statistical Life (VSSSL) is proposed for cost-benefit studies across the power generation sector, and the nuclear industry in particular. An upper bound on VSSSL is set based on the UK government standard of around £1M or, in particular circumstances, £2M and the observation that excessive spend (probably of the order of more than £5M per statistical life) will cost lives. Above a risk of 10 -3 a -1 it is assumed that VSSSL approaches a value around £2M (broad range £1M to £5M). At risks around 10 -6 a -1 it is proposed that an appropriate VSSSL lies at £0.5M (range £0.25M to £1M). Where risks to the individual fall to the order of 10 -9 a -1 , or less, a low residual VSSSL of £0.01M is applied. A practical example is explored with respect to radiological protection where a total collective dose determination is disaggregated to resolve broad bands of individual exposure, and hence risk. Where collective doses are dominated by individual doses no more than a few µSv, the detriment arising from a manSv can be valued at about £15k to £60k, which can have a major effect on cost-benefit approaches to spend decisions.
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