TY - JOUR
T1 - Inter- and intra-specific variability in shell chemistry of well-preserved bivalve shells from the Early Campanian (Late Cretaceous) Kristianstad Basin in Scania, Sweden
AU - De Winter, Niels
AU - Vinzenz Ullmann, Clemens
AU - Sorenson, Anne
AU - Thibault, Nicolas
AU - Claeys, Philippe
N1 - M1 - 4332
PY - 2018/4/14
Y1 - 2018/4/14
N2 - The Campanian age (Late Cretaceous) is generally considered as a period of globally ice-free, warm greenhouse climate (Huber et al., 2002). Understanding controls and modes of Earth’s climate change in such a greenhouse world is essential for predictions of future climate change due to anthropogenic greenhouse gas emissions. Most of the literature on Late Cretaceous climate changes focuses on reconstructing the evolution of humid/arid conditions on land and/or past atmospheric and oceanic temperatures. Assessing the extent of seasonal change has seldom been studied so far, although such data constitute a fundamental component of the climate system. Fossil bivalve shells offer a valuable record for studying past climates at a seasonal scale. The chemistry of bivalve shells can record information about the environment in which bivalves grew, and incremental measurements of chemical changes in growth direction have the potential to yield records of seasonal changes in this environment. Examples of chemical proxies used for these palaeoseasonality reconstructions are stable carbon and oxygen isotopes and trace element ratios (e.g. de Winter et al., 2017). However, many open questions still exist regarding the incorporation of these chemical proxies into bivalve shells. Many of these challenges arise from the influence of so-called vital effects on the chemistry of precipitated carbonate in the shells (Weiner and Dove, 2003). In modern bivalves, these vital effects have been shown to interfere with characteristic relationships between shell chemistry and the environment and these vital effects appear to be distinct not only between different bivalve species but also between specimens of different ontogenetic age (Freitas et al., 2008). In this study, an attempt is made to isolate the effects of environmental change from vital effects recorded in stable isotope and trace element records from fossil bivalves. This is achieved by comparing results from different species and different individuals of the same species in the same palaeoenvironmental setting. The Early Campanian Kristianstad Basin localities used in this study offer abundant bivalve fossils from various taxa (Sørensen et al., 2015). Comparing multi-proxy records both within and between species sheds light on the influence of species-specific and age-specific effects on the expression of seasonal variations in shell chemistry. It also allows disentangling vital effects from environmental influences in an effort to improve palaeoseasonality reconstructions in the Late Cretaceous greenhouse. de Winter et al. (2017). Tropical seasonality in the late Campanian (late Cretaceous): Comparison between multiproxy records from three bivalve taxa from Oman. Palaeogeography, Palaeoclimatology, Palaeoecology, 485, 740-760. Freitas et al. (2008). Inter-and intra-specimen variability masks reliable temperature control on shell Mg/Ca ratios in laboratory and field cultured Mytilus edulis and Pecten maximus (bivalvia). Biogeosciences Discussions, 5(1), 531-572. Huber et al. (2002). Deep-sea paleotemperature record of extreme warmth during the Cretaceous. Geology, 30(2), 123-126. Sørensen et al. (2015). Geochemical signatures of the early Campanian belemnite Belemnellocamax mammillatus from the Kristianstad Basin in Scania, Sweden. Palaeo3 433, 191-200. Weiner & Dove (2003). An overview of biomineralization processes and the problem of the vital effect. Reviews in mineralogy and geochemistry, 54(1), 1-29.
AB - The Campanian age (Late Cretaceous) is generally considered as a period of globally ice-free, warm greenhouse climate (Huber et al., 2002). Understanding controls and modes of Earth’s climate change in such a greenhouse world is essential for predictions of future climate change due to anthropogenic greenhouse gas emissions. Most of the literature on Late Cretaceous climate changes focuses on reconstructing the evolution of humid/arid conditions on land and/or past atmospheric and oceanic temperatures. Assessing the extent of seasonal change has seldom been studied so far, although such data constitute a fundamental component of the climate system. Fossil bivalve shells offer a valuable record for studying past climates at a seasonal scale. The chemistry of bivalve shells can record information about the environment in which bivalves grew, and incremental measurements of chemical changes in growth direction have the potential to yield records of seasonal changes in this environment. Examples of chemical proxies used for these palaeoseasonality reconstructions are stable carbon and oxygen isotopes and trace element ratios (e.g. de Winter et al., 2017). However, many open questions still exist regarding the incorporation of these chemical proxies into bivalve shells. Many of these challenges arise from the influence of so-called vital effects on the chemistry of precipitated carbonate in the shells (Weiner and Dove, 2003). In modern bivalves, these vital effects have been shown to interfere with characteristic relationships between shell chemistry and the environment and these vital effects appear to be distinct not only between different bivalve species but also between specimens of different ontogenetic age (Freitas et al., 2008). In this study, an attempt is made to isolate the effects of environmental change from vital effects recorded in stable isotope and trace element records from fossil bivalves. This is achieved by comparing results from different species and different individuals of the same species in the same palaeoenvironmental setting. The Early Campanian Kristianstad Basin localities used in this study offer abundant bivalve fossils from various taxa (Sørensen et al., 2015). Comparing multi-proxy records both within and between species sheds light on the influence of species-specific and age-specific effects on the expression of seasonal variations in shell chemistry. It also allows disentangling vital effects from environmental influences in an effort to improve palaeoseasonality reconstructions in the Late Cretaceous greenhouse. de Winter et al. (2017). Tropical seasonality in the late Campanian (late Cretaceous): Comparison between multiproxy records from three bivalve taxa from Oman. Palaeogeography, Palaeoclimatology, Palaeoecology, 485, 740-760. Freitas et al. (2008). Inter-and intra-specimen variability masks reliable temperature control on shell Mg/Ca ratios in laboratory and field cultured Mytilus edulis and Pecten maximus (bivalvia). Biogeosciences Discussions, 5(1), 531-572. Huber et al. (2002). Deep-sea paleotemperature record of extreme warmth during the Cretaceous. Geology, 30(2), 123-126. Sørensen et al. (2015). Geochemical signatures of the early Campanian belemnite Belemnellocamax mammillatus from the Kristianstad Basin in Scania, Sweden. Palaeo3 433, 191-200. Weiner & Dove (2003). An overview of biomineralization processes and the problem of the vital effect. Reviews in mineralogy and geochemistry, 54(1), 1-29.
M3 - Article
SN - 1029-7006
VL - 20
JO - Geophysical Research Abstracts
JF - Geophysical Research Abstracts
IS - 4332
ER -