Godard, Marguerite; Carter, Elliot; Decrausaz, Thierry; Lafay, Romain; Bennett, Emma; Kourim, Fatma; de Obeso, Juan Carlos; Michibayashi, Katsuyoshi; Harris, Michelle; Coggon, Jude; Teagle, Damon A H; Kelemen, Peter B; The Oman Drilling Project Phase 1 Science Party (2021): Lithology, major, volatile and trace element composition of Hole BT1B samples (Semail ophiolite; ICDP Oman drilling project) [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.937490
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Abstract:
This database reports the results of bulk rock geochemical measurements realized on 84 rock samples collected from Hole BT1B drilled during ICDP Oman Drilling Project (OmanDP, Kelemen et al. [2020]). 15 samples were collected on-site every 20m during the drilling operations (February-March 2017). 59 samples were selected by the shipboard science party as representative of the different lithologies recovered from Hole BT1B during the description of the cores, on board D/V Chikyu (August 2017). 10 additional listvenites and serpentinites were selected from Sections C5704B-73Z-1 to -75Z-2 (180.01-186.945mbg) for a coordinated on-shore study of the lower serpentinite intervals and neighboring listvenites (thereafter referred to as consortium samples). The purpose of the study was to obtain a high-density and high analytical quality bulk geochemical characterization along the 300.05 meters of continuous cores recovered from OmanDP Hole BT1B, through the transition from the variously carbonated peridotites at the base of the Semail ophiolite mantle section to the underlying metamorphic lithologies. 51 listvenites, 14 serpentinites, and 19 greenshists and greenstones were analyzed. The rock names and grouping by Units were determined on-board D/V Chikyu from macroscopic observations (Visual Core Description; Kelemen et al. [2020]). Major and trace element concentrations were measured by X-ray fluorescence (XRF). XRF analyses of shipboard and on-site samples noted * in the Method columns were realized on-board D/V Chikyu (Note that major oxide concentrations in Kelemen et al. [2020] are recalculated to 100 wt.%) and those noted † in the Method columns were realized at the University of St. Andrews (see Table BT1-T12 in Kelemen et al. [2020]). XRF analyses of consortium samples were realized at Geolabs. FeO concentrations were measured by titration at the University of Lausanne (Switzerland). Total H and C concentrations (noted TH and TC) were determined on-board D/V Chikyu by combustion CHNS elemental analysis (EA) and used to recalculate H2O and CO2 contents. Concentrations of carbon in Ca-carbonates (total inorganic carbon; noted TIC) were determined by coulometry. Trace element compositions were determined using a Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) at the University of Montpellier (France). All analyses were performed on samples prepared from non ignited rock-powders, except for XRF major element analyses realized on beads on-board D/V Chikyu. Concentrations are reported in wt.% (10-2g/g) and in ppm (10-6 g/g). Abbreviations: mbg: meters below ground (Chikyu curated depth); Fu-listvenite : fuchsite-bearing listvenite; LOI : Loss on ignition; XRF B : XRF analyses on beads; XRF P : XRF analyses on powder pellets; XRF B/P : XRF major element analyses on beads except for K measured on pellets and recalculated as volatile free; n.a.: not analysed; n.d.: not determined. (Notes, abbreviations & reference at the bottom of the file) ‡ Sample C5704B-60Z-4-1, 24.0--29.0 cm: Green matrix (Host: Sample C5704B-60Z-4-1, 24.0--29.0 cm - H) crosscut by pink vein (Vein : Sample C5704B-60Z-4-1, 24.0--29.0 cm - V) Reference : Kelemen, P. B., J. M. Matter, D. A. H. Teagle, J. A. Coggon, and the Oman Drilling Project Science Team (2020), Proceedings of the Oman Drilling Project, College Station, TX.
Keyword(s):
Related to:
Godard, Marguerite; Carter, Elliot; Decrausaz, Thierry; Lafay, Romain; Bennett, Emma; Kourim, Fatma; de Obeso, Juan Carlos; Michibayashi, Katsuyoshi; Harris, Michelle; Coggon, Jude; Teagle, Damon A H; Kelemen, Peter B (2021): Geochemical Profiles Across the Listvenite- Metamorphic Transition in the Basal Megathrust of the Semail Ophiolite: Results from Drilling at Oman DP Hole BT1B. Geophysical Research Letters, https://doi.org/10.1002/essoar.10507497.1
Coverage:
Latitude: 23.364496 * Longitude: 58.182396
Date/Time Start: 2017-03-23T00:00:00 * Date/Time End: 2017-03-23T00:00:00
Minimum DEPTH, sediment/rock: 8.610 m * Maximum DEPTH, sediment/rock: 299.470 m
Event(s):
OmanDP_BT1B * Latitude: 23.364496 * Longitude: 58.182396 * Date/Time: 2017-03-23T00:00:00 * Location: Wadi Mansah, Samail, Oman * Method/Device: Core drilling (CDRILL) * Comment: Total depth: 300.5 m
Comment:
This database reports the results of bulk rock geochemical measurements realized on 51 listvenites, 14 serpentinites, and 19 greenshists and greenstones collected from OmanDP Hole BT1B.
The rock names and grouping by Units were determined on-board D/V Chikyu from macroscopic observations (Visual Core Description; Kelemen et al. [2020]). Major and trace element concentrations were measured by X-ray fluorescence (XRF). XRF analyses of shipboard and on-site samples noted * in the Method columns were realized on-board D/V Chikyu (Note that major oxide concentrations in Kelemen et al. [2020] are recalculated to 100 wt.%) and those noted † in the Method columns were realized at the University of St. Andrews (see Table BT1-T12 in Kelemen et al. [2020]). XRF analyses of consortium samples were realized at Geolabs. FeO concentrations were measured by titration at the University of Lausanne (Switzerland). Total H and C concentrations (noted TH and TC) were determined on-board D/V Chikyu by combustion CHNS elemental analysis (EA) and used to recalculate H2O and CO2 contents. Concentrations of carbon in Ca-carbonates (total inorganic carbon; noted TIC) were determined by coulometry. Trace element compositions were determined using a Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) at the University of Montpellier (France). All analyses were performed on samples prepared from non ignited rock-powders, except for XRF major element analyses realized on beads on-board D/V Chikyu. Concentrations are reported in wt.% (10-2g/g) and in ppm (10-6 g/g).
Empty cells = n.a
#1 = n.d.
Parameter(s):
# | Name | Short Name | Unit | Principal Investigator | Method/Device | Comment |
---|---|---|---|---|---|---|
1 | Sample code/label | Sample label | Godard, Marguerite | |||
2 | Sampling | Sampling | Godard, Marguerite | |||
3 | DEPTH, sediment/rock | Depth sed | m | Godard, Marguerite | Geocode – mbg (meters below ground (Chikyu curated depth)) | |
4 | Unit | Unit | Godard, Marguerite | |||
5 | Rock type | Rock | Godard, Marguerite | Rock name | ||
6 | Rock type | Rock | Godard, Marguerite | |||
7 | Series | Series | Godard, Marguerite | |||
8 | Series | Series | Godard, Marguerite | |||
9 | Sample method | Sample method | Godard, Marguerite | Major elements | ||
10 | Method comment | Method comm | Godard, Marguerite | Major elements | ||
11 | Silicon dioxide | SiO2 | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
12 | Titanium dioxide | TiO2 | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
13 | Aluminium oxide | Al2O3 | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
14 | Iron oxide, Fe2O3 | Fe2O3 | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
15 | Magnesium oxide | MgO | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
16 | Manganese oxide | MnO | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
17 | Calcium oxide | CaO | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
18 | Sodium oxide | Na2O | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
19 | Potassium oxide | K2O | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
20 | Phosphorus pentoxide | P2O5 | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
21 | Chromium(III) oxide | Cr2O3 | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
22 | Elements, total | Total | % | Godard, Marguerite | X-ray fluorescence (XRF) | |
23 | Loss on ignition | LOI | % | Godard, Marguerite | X-ray fluorescence (XRF) | wt.% |
24 | Magnesium number | Mg# | Godard, Marguerite | X-ray fluorescence (XRF) | ||
25 | Calcium number | Ca# | Godard, Marguerite | X-ray fluorescence (XRF) | ||
26 | Sample method | Sample method | Godard, Marguerite | |||
27 | Iron oxide, FeO | FeO | % | Godard, Marguerite | Fe-titration | |
28 | Iron 3+/Iron total | Fe3+/Fetotal | Godard, Marguerite | Fe-titration | ||
29 | Sample method | Sample method | Godard, Marguerite | Coulometry | Volatiles | |
30 | Method comment | Method comm | Godard, Marguerite | Coulometry | Volatiles | |
31 | Hydrogen, total | TH | % | Godard, Marguerite | Element analyser CHNS | wt.% |
32 | Carbon, total | TC | % | Godard, Marguerite | Element analyser CHNS | wt.% |
33 | Carbon, inorganic, total | TIC | % | Godard, Marguerite | Coulometry | wt.% |
34 | Water in rock | H2O | % | Godard, Marguerite | Element analyser CHNS | wt.% |
35 | Carbon dioxide | CO2 | % | Godard, Marguerite | Element analyser CHNS | wt.% |
36 | Sample method | Sample method | Godard, Marguerite | Transition and trace elements | ||
37 | Method comment | Method comm | Godard, Marguerite | Transition and trace elements | ||
38 | Vanadium | V | mg/kg | Godard, Marguerite | X-ray fluorescence (XRF) | Original unit = ppm |
39 | Chromium | Cr | mg/kg | Godard, Marguerite | X-ray fluorescence (XRF) | Original unit = ppm |
40 | Cobalt | Co | mg/kg | Godard, Marguerite | X-ray fluorescence (XRF) | Original unit = ppm |
41 | Nickel | Ni | mg/kg | Godard, Marguerite | X-ray fluorescence (XRF) | Original unit = ppm |
42 | Copper | Cu | mg/kg | Godard, Marguerite | X-ray fluorescence (XRF) | Original unit = ppm |
43 | Zinc | Zn | mg/kg | Godard, Marguerite | X-ray fluorescence (XRF) | Original unit = ppm |
44 | Zirconium | Zr | mg/kg | Godard, Marguerite | X-ray fluorescence (XRF) | Original unit = ppm |
45 | Sample method | Sample method | Godard, Marguerite | |||
46 | Lithium | Li | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
47 | Scandium | Sc | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
48 | Titanium | Ti | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
49 | Vanadium | V | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
50 | Manganese | Mn | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
51 | Cobalt | Co | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
52 | Nickel | Ni | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
53 | Copper | Cu | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
54 | Zinc | Zn | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
55 | Gallium | Ga | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
56 | Arsenic | As | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
57 | Rubidium | Rb | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
58 | Strontium | Sr | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
59 | Yttrium | Y | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
60 | Zirconium | Zr | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
61 | Niobium | Nb | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
62 | Tin | Sn | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
63 | Antimony | Sb | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
64 | Caesium | Cs | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
65 | Barium | Ba | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
66 | Lanthanum | La | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
67 | Cerium | Ce | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
68 | Praseodymium | Pr | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
69 | Neodymium | Nd | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
70 | Samarium | Sm | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
71 | Europium | Eu | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
72 | Gadolinium | Gd | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
73 | Terbium | Tb | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
74 | Dysprosium | Dy | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
75 | Holmium | Ho | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
76 | Erbium | Er | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
77 | Thulium | Tm | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
78 | Ytterbium | Yb | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
79 | Lutetium | Lu | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
80 | Hafnium | Hf | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
81 | Tantalum | Ta | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
82 | Lead | Pb | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
83 | Thorium | Th | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
84 | Uranium | U | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
85 | Tungsten | W | mg/kg | Godard, Marguerite | Quadrupole Inductively-Coupled-Plasma-Mass Spectrometer (Q-ICP-MS) | Original unit = ppm |
License:
Creative Commons Attribution 4.0 International (CC-BY-4.0)
Status:
Curation Level: Enhanced curation (CurationLevelC)
Size:
6672 data points
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