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Abstract
Muzzle Group strata exposed along southeast‐flowing tributaries of the Clarence River valley, Marlborough, record hemipelagic‐pelagic sedimentation across a high latitude (c. 55°S), terrigenous sediment‐starved, continental margin from latest Cretaceous to middle Eocene times. Studies of dinoflagellates, foraminifera, calcareous nannofossils, and radiolarians have been integrated with bulk carbonate δ13C profiles to establish the chronostratigraphy for two stratigraphic sections along Bluff and Muzzle Streams, middle Clarence valley. The two sections comprise similar successions. Uppermost Cretaceous (upper Haumurian) micritic limestone of Mead Hill Formation is overlain unconformably by Teredo Limestone, a c. 0.25 m thick bed of highly glauco‐nitic, calcareous sandstone. This unit, the basal member of Amuri Limestone, is overlain conformably by c. 15 m thick Lower Limestone, micritic limestone that is glauconitic at base and progressively more marl‐rich in its upper part. Lower Limestone grades up into Lower Marl, a poorly exposed, 40–70 m thick unit of alternating marl and micritic limestone beds. Biostratigraphy indicates that the base of Amuri Limestone is younger at Bluff Stream (earliest Eocene, early Waipawan) than at Muzzle Stream (late Paleocene, late Teurian). In the condensed (12 m) upper Paleocene‐lower Eocene Amuri Limestone sequence at Muzzle Stream, a trend in δ13C from high (≥2.4‰) to low (≤1‰) values is consistent with global records across three major climate or carbon cycle perturbations: the late Paleocene carbon isotope maximum (PCIM, 59–56 Ma), the initial Eocene thermal maximum (IETM, 55.5 Ma), and the early Eocene climatic optimum (EECO, 53–50 Ma). Probably only the upper PCIM is preserved in the 4 m thick siliceous limestone interval overlying Teredo Limestone. The IETM is well‐defined by a 1‰ negative δ13C excursion at the base of a 0.8 m thick marl‐rich unit (Dee Marl), 5 m above the base of Lower Limestone at Muzzle Stream, and the abrupt appearances of Eocene‐restricted species or distinctly warm‐water elements within dinoflagellate, foraminiferal, calcareous nannofossil, and radiolarian assemblages. The lithological expression of the IETM as a recessive marly unit has now been identified in three Clarence valley sections (Muzzle, Dee, and Mead Streams), representing a 20 km continental margin transect. Sedimentation rate trends across this margin indicate that the local effects of extreme global warming were increased supply of terrigenous mud, probably due to enhanced precipitation, weathering and erosion, and a decrease in pelagic sedimentation, reflecting a decrease in oceanic productivity. Bluff section lacks an IETM record but contains an expanded (20 m) early Eocene succession that records the onset of the EECO as a progressive increase in marl‐rich units associated with consistently low δ13C (<1‰). Both Muzzle and Bluff sections indicate that local environmental changes associated with the EECO were a more gradual and extended version of those inferred for the IETM: an increase in terrigenous mud supply coupled with a decrease in oceanic productivity.
Notes
Institute of Geological and Nuclear Sciences Ltd, P.O. Box 30 368, Lower Hutt, New Zealand. [email protected]
Department of Earth Sciences, Rice University, Houston, TX 77005, USA.
