Rodrigo-Gámiz, Marta; Rampen, Sebastiaan W; Schouten, Stefan; Sinninghe Damsté, Jaap S (2016): Long chain alkyl diol distribution in Arabian Sea surface sediments [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.863586, Supplement to: Rodrigo-Gámiz, M et al. (2016): The impact of oxic degradation on long chain alkyl diol distributions in Arabian Sea surface sediments. Organic Geochemistry, 100, 1-9, https://doi.org/10.1016/j.orggeochem.2016.07.003
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Abstract:
Oxygen exposure has a large impact on lipid biomarker preservation in surface sediments and may affect the application of organic proxies used for reconstructing past environmental conditions. To determine its effect on long chain alkyl diol and keto-ol based proxies, the distributions of these lipids was studied in nine surface sediments from the Murray Ridge in the Arabian Sea obtained from varying water depths (900 to 3000 m) but in close lateral proximity and, therefore, likely receiving a similar particle flux. Due to substantial differences in bottom water oxygen concentration (<3 to 77 µmol/L) and sedimentation rate, substantial differences exist in the time the biomarker lipids are exposed to oxygen in the sediment. Long chain alkyl diol and keto-ol concentrations in the surface sediments (0-0.5 cm) decreased progressively with increasing oxygen exposure time, suggesting increased oxic degradation. The 1,15-keto-ol/diol ratio (DOXI) increased slightly with oxygen exposure time as diols had apparently slightly higher degradation rates than keto-ols. The ratio of 1,14- vs. 1,13- or 1,15-diols, used as upwelling proxies, did not show substantial changes. However, the C30 1,15-diol exhibited a slightly higher degradation rate than C28 and C30 1,13-diols, and thus the Long chain Diol Index (LDI), used as sea surface temperature proxy, showed a negative correlation with the maximum residence time in the oxic zone of the sediment, resulting in ca. 2-3.5 °C change, when translated to temperature. The UK'37 index did not show significant changes with increasing oxygen exposure. This suggests that oxic degradation may affect temperature reconstructions using the LDI in oxic settings and where oxygen concentrations have varied substantially over time.
Coverage:
Median Latitude: 22.256481 * Median Longitude: 63.430740 * South-bound Latitude: 21.926670 * West-bound Longitude: 62.895000 * North-bound Latitude: 22.565000 * East-bound Longitude: 64.063330
Date/Time Start: 2009-01-12T00:00:00 * Date/Time End: 2009-01-21T00:00:00
Minimum DEPTH, sediment/rock: 0 m * Maximum DEPTH, sediment/rock: 0 m
Event(s):
PA900 * Latitude: 22.548330 * Longitude: 64.040000 * Date/Time: 2009-01-12T00:00:00 * Elevation: -885.0 m * Location: Northern Arabian Sea * Campaign: 64PE301 (PASOM) * Basis: Pelagia * Method/Device: Box corer (BC)
Parameter(s):
| # | Name | Short Name | Unit | Principal Investigator | Method/Device | Comment |
|---|---|---|---|---|---|---|
| 1 | Event label | Event | Rodrigo-Gámiz, Marta | |||
| 2 | Latitude of event | Latitude | Rodrigo-Gámiz, Marta | |||
| 3 | Longitude of event | Longitude | Rodrigo-Gámiz, Marta | |||
| 4 | Elevation of event | Elevation | m | Rodrigo-Gámiz, Marta | ||
| 5 | DEPTH, sediment/rock | Depth sed | m | Rodrigo-Gámiz, Marta | Geocode – surface samples from 0-0.5 cm depth | |
| 6 | Oxygen penetration depth | OPD depth | mm | Rodrigo-Gámiz, Marta | ||
| 7 | Residence time | RT | a | Rodrigo-Gámiz, Marta | toz = residence time the organic matter spends in the oxic zone | |
| 8 | Carbon, organic, total | TOC | % | Rodrigo-Gámiz, Marta | ||
| 9 | Carbon, organic, per unit sediment mass | C org/sed | mg/g | Rodrigo-Gámiz, Marta | ||
| 10 | Alkenone, unsaturation index UK'37 | UK'37 | Rodrigo-Gámiz, Marta | |||
| 11 | Sea surface temperature, annual mean | SST (1-12) | °C | Rodrigo-Gámiz, Marta | Calculated from UK'37 (Müller et al, 1998) | |
| 12 | Alkenone, unsaturation index UK'37 | UK'37 | Rodrigo-Gámiz, Marta | duplicate | ||
| 13 | Sea surface temperature, annual mean | SST (1-12) | °C | Rodrigo-Gámiz, Marta | Calculated from UK'37 (Müller et al, 1998) | duplicate |
| 14 | Alkenone, C37:3 | C37:3 | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 9.6 %, per dry sediment | |
| 15 | Alkenone, C37:2 | C37:2 | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 7.8 %, per dry sediment | |
| 16 | Alkenone, C37:3 | C37:3 | ng/g | Rodrigo-Gámiz, Marta | duplicate, Relative Preservation Efficiency: 14.3 %, per dry sediment | |
| 17 | Alkenone, C37:2 | C37:2 | ng/g | Rodrigo-Gámiz, Marta | duplicate, Relative Preservation Efficiency: 13.4 %, per dry sediment | |
| 18 | Long chain diol index | LDI | Rodrigo-Gámiz, Marta | |||
| 19 | Sea surface temperature, annual mean | SST (1-12) | °C | Rodrigo-Gámiz, Marta | Calculated after Rampen et al. (2012) | |
| 20 | Long chain diol index | LDI | Rodrigo-Gámiz, Marta | duplicate | ||
| 21 | Sea surface temperature, annual mean | SST (1-12) | °C | Rodrigo-Gámiz, Marta | Calculated after Rampen et al. (2012) | duplicate |
| 22 | Diol upwelling index | Upw index | Rodrigo-Gámiz, Marta | 1,15 upwelling | ||
| 23 | Diol upwelling index | Upw index | Rodrigo-Gámiz, Marta | 1,13 upwelling | ||
| 24 | Long chain diol, C28:1 1,14-diol | C28:1 1.14 | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 6.9 %, per dry sediment | |
| 25 | Long chain diol, C28 1,14-diol | C28 1,14 | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 5.2 %, per dry sediment | |
| 26 | Long chain diol, C28 1,13-diol | C28 1,13-diol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 10.5 %, per dry sediment | |
| 27 | Long chain diol, C30 1,15-diol | C30 1,15-diol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 4.3 %, per dry sediment | |
| 28 | Long chain diol, C30:1 1,14-diol | C30:1 1,14-diol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 1.5 %, per dry sediment | |
| 29 | Long chain diol, C30 1,14-diol | C30 1,14-diol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 5.7 %, per dry sediment | |
| 30 | Long chain diol, C30 1,13-diol | C30 1,13-diol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 10.1 %, per dry sediment | |
| 31 | Long chain diol, C32 1,15-diol | C32 1,15-diol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 4.2 %, per dry sediment | |
| 32 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C28 1,15 | ||
| 33 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C30 1,15 | ||
| 34 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C32 1,15 | ||
| 35 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C34 1,15 | ||
| 36 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C28 1,15 duplicate | ||
| 37 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C30 1,15 duplicate | ||
| 38 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C32 1,15 duplicate | ||
| 39 | Diol oxidation index | DOXI | Rodrigo-Gámiz, Marta | C34 1,15 duplicate | ||
| 40 | C30 1,15-keto-ol | C30 1,15-keto-ol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 7.2 %, per dry sediment | |
| 41 | C32 1,15-keto-ol | C32 1,15-keto-ol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 8.5 %, per dry sediment | |
| 42 | C34 1,15-keto-ol | C34 1,15-keto-ol | ng/g | Rodrigo-Gámiz, Marta | Relative Preservation Efficiency: 7.1 %, per dry sediment | |
| 43 | C30 1,15-keto-ol | C30 1,15-keto-ol | ng/g | Rodrigo-Gámiz, Marta | duplicate, Relative Preservation Efficiency: 6.8 %, per dry sediment | |
| 44 | C32 1,15-keto-ol | C32 1,15-keto-ol | ng/g | Rodrigo-Gámiz, Marta | duplicate, Relative Preservation Efficiency: 9.0 %, per dry sediment | |
| 45 | C34 1,15-keto-ol | C34 1,15-keto-ol | ng/g | Rodrigo-Gámiz, Marta | duplicate, Relative Preservation Efficiency: 8.9 %, per dry sediment |
License:
Creative Commons Attribution 3.0 Unported (CC-BY-3.0)
Size:
358 data points