Ground-penetrating radar study of Pleistocene ice scours on a glaciolacustrine sequence boundary

Ice scouring of lake and sea-floor substrates by the keels of drifting ice masses is a common geological process in modern northern lakes and continental shelves, and was widespread during the Pleistocene. Nonetheless, the importance of scouring as a geological process is not yet matched by many sedimentological studies of scour structures exposed in outcrop. This article presents an integrated study combining outcrop sedimentology and subsurface ground-penetrating radar (GPR) data from a relict late Pleistocene ice-scoured glacial lake floor now preserved below beach sediments in Ontario, Canada. Scours occur along a regressive sequence boundary where deep-water muddy facies are abruptly overlain by shallow-water sands resulting from an abrupt drop in water levels. This has allowed the keels of drifting ice masses to scour into muds. Three-dimensional data gained from the GPR survey show that scours are as much as 2.5 m deep and 7 m wide; they have berms of displaced sediment and are oriented parallel to the former shoreline. Scoured shoreface sediments that fill scours show abundant liquefaction structures, indicating substrate dewatering during repeated scouring events similar to that recently reported in the modern Beaufort Sea in Canada's far north. Marked changes in water depths are typical of glacially influenced lakes and seas, creating opportunities for drifting ice to scour into offshore muddy cohesive facies and be preserved. The data presented here may aid identification in ancient successions elsewhere.     

Na-rich Partial Melts from Newly Underplated Basaltic Crust: the Cordillera Blanca Batholith, Peru

The late Miocene Cordillera Blanca Batholith lies directly overthick (50 km) crust, inboard of the older Cretaceous CoastalBatholith. Its peraluminous ‘S’ type mineralogyand its position suggest recycling of continental crust, whichis commonly thought to be an increasingly important componentin magmas inboard of continental margins. However, the peraluminous,apparent ‘S’ type character of the batholith isan artefact of deformation and uplift along a major crustallineament. The batholith is a metaluminous ‘I’ typeand the dominant high-silica rocks (>70%) are Na rich withmany of the characteristics of subducted oceanic slab melts.However, the position of the batholith and age of the oceaniccrust at the trench during the Miocene preclude slab melting.Instead, partial melting of newly underplated Miocene crustis proposed. In this dynamic model newly underplated basalticmaterial is melted to produce high-Na, low HREE, high-Al ‘trondhjemitic’type melts with residues of garnet, clinopyroxene and amphibole.Such Na-rich magmas are characteristic of thick Andean crust;they are significantly different from typical cole-alkaline,tonalite-grano-diorite magmas, and their presence along thespine of the Andes provokes questions about models of trondhjemitegenesis by melting of subducted oceanic crust, as well as anygeneralized, circum-Pacific model involving consistent isotopicor chemical changes inboard from the trench. KEY WORDS: batholith; modified ‘I’ type granite; Na-rich magma; thick crust ^* Corresponding author.     

Lateglacial–Holocene shoreface progradation offshore eastern Scotland: a response to climatic and coastal hydrographic change

Seismic facies, provenance and marine faunal associations of a nearshore prograding sediment wedge offshore eastern Scotland are studied to investigate environmental changes in the adjacent North Sea during Lateglacial–Holocene time. The sediments form part of the St. Andrews Bay Member (Forth Formation), which is divided into four lithozones (L1–L4) that represent distinct pulses of sedimentation during the sequential growth of the sediment wedge. Radiocarbon dates, combined with the local curve of relative sea level change, indicate that progradation was initiated as a fluvio-deltaic deposit (L1) during the Younger Dryas Stadial. Further construction of the sediment package took place during the mid- to late Holocene by sublittoral tidal processes that deposited three discrete, highstand shoreface wedges (L2–L4), which display both progradation and longshore migration (to the NE), and may have experienced episodic brackish marine conditions. A depositional cyclicity of about 1000 years is proposed for lithozones L2–L4, separated by hiatuses of 1000–2000 years. We tentatively suggest that the Holocene development of the prograding wedge offshore eastern Scotland was a response to phases of strong westerly winds driving an enhanced influx of Atlantic Water into the North Sea. A concomitant increase in rainfall may account for the freshening of the coastal zone at this time. However, correlation with the recently postulated global periods of Holocene rapid climate change remains unclear.