Description
Complete data from piston core CD166/19, which was recovered from the Agadir Basin during the RRS Charles Darwin expedition CD166 in 2004 (Wynn and Cronin, 2005). The core site is located at 31°31’ N, 17°11.77’ W at a water depth of 4502 m. The coring operation recovered 4.3 m of sediment composed of hemipelagite and turbidites. The hemipelagic sediments range from cream-brown carbonate-rich marl/ooze to red-brown clays. The turbidites include siliciclastic, volcaniclastic and calcareous sediments.
The split core sections were analysed using the Cox Analytical Systems Itrax core scanner at the British Ocean Sediment Core Research Facility, National Oceanography Centre (Southampton, UK). The split core surfaces were cleaned and loaded to the core scanner along with a radiographic reference sample (Francus, Kanamaru, and Fortin, 2015) and a colour card. The cores were first scanned to measure the sample surface height and to obtain optical images. The core sections were then covered with Mylar film to reduce sample desiccation during XRF scanning and x-radiography.
XRF data were acquired using a Molybdenum X-ray tube set at 30 kV and 30 mA with a dwell time of 30 seconds and a step size of 1 mm. X-radiographs were acquired with voltage and current set to 55 kV and 50 mA, respectively, and dwell time set to 500 ms. Step size for the x-radiography was set to 200 µm. Two replicate XRF scans were also performed for each of the three core sections that make up this core. The XRF settings for the replicates were kept consistent with those of the main XRF scan. The interval selected for the replicate scans ranged from 10 cm to 15 cm of the total sample length. All raw XRF raw data were reprocessed using the QSpec spectral analysis software to optimise peak fitting.
The split core sections were analysed using the Cox Analytical Systems Itrax core scanner at the British Ocean Sediment Core Research Facility, National Oceanography Centre (Southampton, UK). The split core surfaces were cleaned and loaded to the core scanner along with a radiographic reference sample (Francus, Kanamaru, and Fortin, 2015) and a colour card. The cores were first scanned to measure the sample surface height and to obtain optical images. The core sections were then covered with Mylar film to reduce sample desiccation during XRF scanning and x-radiography.
XRF data were acquired using a Molybdenum X-ray tube set at 30 kV and 30 mA with a dwell time of 30 seconds and a step size of 1 mm. X-radiographs were acquired with voltage and current set to 55 kV and 50 mA, respectively, and dwell time set to 500 ms. Step size for the x-radiography was set to 200 µm. Two replicate XRF scans were also performed for each of the three core sections that make up this core. The XRF settings for the replicates were kept consistent with those of the main XRF scan. The interval selected for the replicate scans ranged from 10 cm to 15 cm of the total sample length. All raw XRF raw data were reprocessed using the QSpec spectral analysis software to optimise peak fitting.
Date made available | Feb 2023 |
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Publisher | PANGAEA |
Date of data production | 2023 |
Geospatial point | 31.516667, -17.196167Show on map |
Keywords
- core scanner
- Itrax
- ocean core
- radiograph
Equipment
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School of Environment, Education and Development (SEED) Laboratories
Bishop, T. (Platform Lead), Yarwood, J. (Technical Specialist), Self, R. (Technician), Bell, B. (Technician), Moore, J. (Platform Lead), Ryan, P. (Academic lead), Flannaghan, H. (Technician) & Liebrand, D. (Technician)
School of Environment, Education and DevelopmentFacility/equipment: Facility