Abstract
A rocky shore developed in early Middle Jurassic times by transgression of the crystalline basement in Milne Land at the western margin of the East Greenland rift basin. The basement is onlapped by shallow marine sandstones of the Charcot Bugt Formation, locally with a thin fluvial unit at the base. The topography of the onlap surface suggests that a relative sea-level rise of at least 300 m took place in Early Bathonian – Middle Oxfordian times. The sea-level rise was punctuated by relative stillstands and falls during which progradation of the shoreline took place. Palynological data tied to the Boreal ammonite stratigraphy have greatly improved time resolution within the Charcot Bugt Formation, and the Jurassic succession in Milne Land can now be understood in terms of genetically-related depositional systems with a proximal to distal decrease in grain size. The sequence stratigraphic interpretation suggests that translation of the depositional systems governed by relative sea-level changes resulted in stacking of sandstone-dominated falling stage deposits in the eastern, basinwards parts of Milne Land, whereas thick, remarkably coarse-grained transgressive systems tract deposits formed along the western basin margin. The bulk of the Charcot Bugt Formation consists of stacked sandstone-dominated shoreface units that prograded during highstands. The overall aggradational to backstepping stacking pattern recognised in the Charcot Bugt Formation is comparable to that in the contemporaneous Pelion Formation of the Jameson Land Basin and in correlative units of the mid-Norway shelf and the Northern North Sea. We suggest that the long-term evolution of the depositional systems may have been controlled by long-term eustatic rise acting in concert with relative sea-level changes reflecting regionally contemporaneous phases of rift initiation, climax and gradual cessation of rifting.
Highlights
A rocky shore developed in early Middle Jurassic times by transgression of the crystalline basement in Milne Land at the western margin of the East Greenland rift basin
We suggest that the long-term evolution of the depositional systems may have been controlled by long-term eustatic rise acting in concert with relative sea-level changes reflecting regionally contemporaneous phases of rift initiation, climax and gradual cessation of rifting
Oxfordian) Crystalline basement Fault stratigraphy was based solely on macrofossils; we present new correlations combining the existing ammonite stratigraphy with dinoflagellate data
Summary
Ice Quaternary Palaeogene basalts Hartz Fjeld Formation (M.Volgian – Hauterivian). Kap Leslie Formation (Callovian – M.Volgian) Charcot Bugt Formation The Lower Bathonian – Middle Oxfordian Charcot Bugt Formation was deposited during a long-term transgression recognised throughout the East Greenland basin (Surlyk 1990, 1991, 2003, this volume), and a high gradient rocky shore was formed along the faulted western basin margin (Fig. 1). In the southern part of Visdal, it is only about 10 m thick, the exact position of the upper boundary in this area is difficult to establish (Callomon & Birkelund 1980; Piasecki 1980) It is overlain by the Upper Oxfordian Aldinger Elv Member, which forms a wedgeshaped sandstone body thinning westwards from about 90 m on the east coast of Milne Land to a few metres at Bays Fjelde (Fig. 4; Fürsich & Heinberg 1983). C. cordatum Q. mariae Q. lamberti P. athleta E. coronatum K. jason S. calloviense P. koenigi C. nordenskjoeldi C. apertum C. calyx C. variabile A. cranocephaloide A. ishmae A. greenlandicus A. arcticus C. pompeckji C. indistinctus C. borealis
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