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Lonsdale, Malcolm J (1990): Peak areas and heights for minerals of ODP Leg 113-696B (Table 1) [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.753957, Supplement to: Lonsdale, MJ (1990): The relationship between silica diagenesis, methane, and seismic reflections on the South Orkney Microcontinent. In: Barker, PF; Kennett, JP; et al. (eds.), Proceedings of the Ocean Drilling Program, Scientific Results, College Station, TX (Ocean Drilling Program), 113, 27-37, https://doi.org/10.2973/odp.proc.sr.113.177.1990

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Abstract:
Seismic data acquired over the eastern shelf and margin of the South Orkney microcontinent, Antarctica, have shown a high-amplitude reflection lying at a sub-bottom two-way traveltime (TWT) of 0.5-0.8 s. There appear to be two causes for the reflection which apply in different parts of the shelf. The more widespread cause of the reflection is a break-up unconformity associated with the opening of Jane Basin to the east. This is clearly seen where reflections in the underlying sequence are discordant. In contrast, in Eotvos Basin and the southeastern part of Bouguer Basin, the high-amplitude reflection in places cuts across bedding and is interpreted to be caused by silica diagenesis. A post-cruise analysis of core samples from Site 696 in Eotvos Basin by X-ray diffraction (XRD) and scanning electron microscopy (SEM) revealed the presence of a silica diagenetic front at 520-530 mbsf. The position of the unconformity at this site is uncertain, but probably coincides with a change of detrital input near 548 mbsf. Fluctuations of physical properties related to the depth of the diagenetic front are difficult to separate from those related to the variation of detrital composition over the same depth interval. Correlation of the drilling record with the seismic record is difficult but with a synthetic seismogram it is demonstrated that diagenesis is the probable cause of the high-amplitude reflection.
In Bouguer Basin at Site 695 the depth of the high-amplitude reflection was not reached by drilling; however, the reflection is probably also caused by silica diagenesis because of the biogenic silica-rich composition of the sediments cored. The estimated temperatures and ages of the sediments at the depths of the high-amplitude reflections at Sites 695 and 696 compare favorably with similar data from other diagenetic fronts of the world. The high-amplitude reflection in Bouguer Basin is commonly of inverse polarity, possibly caused either by interference between reflections from several closely-spaced reflecting layers, such as chert horizons, or by free gas trapped near the diagenetic front.
Project(s):
Coverage:
Latitude: -61.849000 * Longitude: -42.933300
Date/Time Start: 1987-02-24T16:30:00 * Date/Time End: 1987-03-02T04:15:00
Minimum Elevation: -661.0 m * Maximum Elevation: -661.0 m
Event(s):
113-696B * Latitude: -61.849000 * Longitude: -42.933300 * Date/Time Start: 1987-02-24T16:30:00 * Date/Time End: 1987-03-02T04:15:00 * Elevation: -661.0 m * Penetration: 645.6 m * Recovery: 156.69 m * Location: Weddell Sea * Campaign: Leg113 * Basis: Joides Resolution * Method/Device: Drilling/drill rig (DRILL) * Comment: 59 cores; 569 m cored; 0 m drilled; 27.5 % recovery
Comment:
Quartz (2 Theta = 26.7°); Plagioclase (27.8-28.3°); Amphibole (10.4°); Olivine (35.6°); Corundum (39.6°); Opal-A; Opal-CT (21.8°); Pyrite (33.2°); Chlorite (12.5°); Illite (8.9°); Halite (31.7°).
Parameter(s):
#NameShort NameUnitPrincipal InvestigatorMethod/DeviceComment
1Sample code/labelSample labelLonsdale, Malcolm JDSDP/ODP/IODP sample designation
2Quartz (peak area)Qz peak areaLonsdale, Malcolm J
3Quartz (peak height)Qz peak heightLonsdale, Malcolm J
4Plagioclase (peak area)Pl peak areaLonsdale, Malcolm J
5Plagioclase (peak height)Pl peak heightLonsdale, Malcolm J
6Amphibole (peak area)Amp peak areaLonsdale, Malcolm J
7Amphibole (peak height)Amp peak heightLonsdale, Malcolm J
8Olivine (peak area)Ol peak areaLonsdale, Malcolm J
9Olivine (peak height)Ol peak heightLonsdale, Malcolm J
10Opal-A (peak area)Opal-A peak areaLonsdale, Malcolm J
11Opal-A (peak height)Opal-A peak heightLonsdale, Malcolm J
12Opal-CT (peak area)Opal-CT peak areaLonsdale, Malcolm J
13Opal-CT (peak height)Opal-CT peak heightLonsdale, Malcolm J
14Pyrite (peak area)Py peak areaLonsdale, Malcolm J
15Pyrite (peak height)Py peak heightLonsdale, Malcolm J
16Chlorite (peak area)Chl peak areaLonsdale, Malcolm J
17Chlorite (peak height)Chl peak heightLonsdale, Malcolm J
18Illite (peak area)Ill peak areaLonsdale, Malcolm J
19Illite (peak height)Ill peak heightLonsdale, Malcolm J
20Halite (peak area)Hl peak areaLonsdale, Malcolm J
21Halite (peak height)Hl peak heightLonsdale, Malcolm J
22Corundum (peak area)Crn peak areaLonsdale, Malcolm J
23Corundum (peak height)Crn peak heightLonsdale, Malcolm J
24--Lonsdale, Malcolm JQzO = ratio of first (2 Theta = 26.7°) and second (20.9°) order quartz peak heights
Size:
256 data points

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