De Jonge, Cindy; Stadnitskaia, Alina; Hopmans, Ellen C; Cherkashov, Georgy A; Fedotov, Andrey; Streletskaya, Irina; Vasiliev, Alexander A; Sinninghe Damsté, Jaap S (2015): Branched GDGT and crenarchaeol lipids, and bulk parameters (TOC, TN, C/N, δ¹³C and d15N) in the Yenisei River and its outflow in the Kara Sea [dataset publication series]. PANGAEA, https://doi.org/10.1594/PANGAEA.877971, Supplement to: De Jonge, C et al. (2015): Drastic changes in the distribution of branched tetraether lipids in suspended matter and sediments from the Yenisei River and Kara Sea (Siberia): Implications for the use of brGDGT-based proxies in coastal marine sediments. Geochimica et Cosmochimica Acta, 165, 200-225, https://doi.org/10.1016/j.gca.2015.05.044
Always quote citation above when using data! You can download the citation in several formats below.
Abstract:
The distribution of branched glycerol dialkyl glycerol tetraethers (brGDGTs) in soils has been shown to correlate with pH and mean annual air temperature. Because of this dependence brGDGTs have found an application as palaeoclimate proxies in coastal marine sediments, based on the assumption that their distribution is not altered during the transport from soils to marine systems by rivers. To study the processes acting on the brGDGT distributions, we analysed the full suite of brGDGTs, including the recently described 6-Me brGDGTs, in both the suspended particulate matter (SPM) of the Siberian Yenisei River and the SPM and sediments of its outflow in the Kara Sea. The brGDGT distribution in the SPM of the Yenisei River was fairly constant and characterized by high abundances of the 6-Me brGDGTs, reflecting their production at the neutral pH of the river water. However, the brGDGT distribution showed marked shifts in the marine system. Firstly, in the Yenisei River Mouth, the fractional abundance of the 6-Me brGDGTs decreases sharply. The brGDGT signature in the Yenisei River Mouth possibly reflects brGDGTs delivered during the spring floods that may carry a different distribution. Also, coastal cliffs were shown to contain brGDGTs and to influence especially those sites without major river inputs (e.g. Khalmyer Bay). Further removed from the river mouth, in-situ production of brGDGTs in the marine system influences the distribution. However, also the fractional abundance of the tetramethylated brGDGT Ia increases, resulting in a distribution that is distinct from in-situ produced signals at similar latitudes (Svalbard). We suggest that this shift may be caused by preferential degradation of labile (riverine in-situ produced) brGDGTs and the subsequent enrichment in less labile (soil) material. The offshore distribution indeed agrees with the brGDGT distribution encountered in a lowland peat. This implies that the offshore Kara Sea sediments possibly carry a soil-dominated signal, indicating potential for palaeoclimate reconstructions at this site.
Both in the river system and coastal cliffs, brGDGTs were much more abundant than crenarchaeol, an archaeal isoprenoid GDGT, resulting in high (>0.93) Branched and Isoprenoid Tetraether (BIT) index values. Moving downstream in the marine sediments, a decrease in brGDGT concentrations, coeval with an increase in crenarchaeol, resulted in decreasing BIT index values. This decrease correlates with changes in bulk proxies for terrigenous input (d13Corg, C/N), confirming the use of the BIT index to trace the delivery of river-transported and coastal cliff-derived terrigenous organic matter.
Project(s):
Coverage:
Median Latitude: 70.040887 * Median Longitude: 81.576476 * South-bound Latitude: 51.728280 * West-bound Longitude: 65.981060 * North-bound Latitude: 78.483210 * East-bound Longitude: 107.462810
Date/Time Start: 2009-08-25T00:00:00 * Date/Time End: 2014-09-09T00:00:00
License:
Creative Commons Attribution 3.0 Unported (CC-BY-3.0)
Size:
5 datasets
Download Data
Datasets listed in this publication series
- De Jonge, C; Stadnitskaia, A; Hopmans, EC et al. (2015): (Table 6) Fractional abundances of the brGDGT compounds of the core lipid and intact polar lipidfractions in the permafrost cliffs at the Yenisei River mouth. https://doi.org/10.1594/PANGAEA.877970
- De Jonge, C; Stadnitskaia, A; Hopmans, EC et al. (2015): (Table 5) Fractional abundances of the brGDGT compounds of the core lipid and intact polar lipidfractions in the sediment samples. https://doi.org/10.1594/PANGAEA.877969
- De Jonge, C; Stadnitskaia, A; Hopmans, EC et al. (2015): (Table 3) Total organic carbon content, the stable carbon isotope signal, the total nitrogen content and the stable nitrogen isotope signal of the sediments and coastal cliff samples. https://doi.org/10.1594/PANGAEA.877964
- De Jonge, C; Stadnitskaia, A; Hopmans, EC et al. (2015): (Table 4) Fractional abundances of the brGDGT compounds of the core lipid and intact polar lipidfractions in the suspended particulate matter samples. https://doi.org/10.1594/PANGAEA.877965
- De Jonge, C; Stadnitskaia, A; Hopmans, EC et al. (2015): (Table 2) Particulate organic carbon contentand the stable carbon isotope signal of suspended particulate matter samples. https://doi.org/10.1594/PANGAEA.877962