Citation:

PANGAEA.763961

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Abstract:

The stability of gypsum in marine sediments has been investigated through the calculation of its saturation index at the sediment in situ temperature and pressure, using the entire ODP/IODP porewater composition database (14416 samples recovered from sediments collected during 95 ODP and IODP Legs). Saturation is reached in sediment porewaters of 26 boreholes drilled at 23 different sites, during 12 ODP/IODP Legs. As ocean bottom seawater is largely undersaturated with respect to gypsum, the porewater Ca content or its SO4 concentration, or both, must increase in order to reach equilibrium. At several sites equilibrium is reached either through the presence of evaporitic gypsum layers found in the sedimentary sequence, and/or through a salinity increase due to the presence of evaporitic brines with high concentrations of Ca and SO4. Saturation can also be reached in porewaters of seawater-like salinity (~ 35 per mil), provided sulfate reduction is limited. In this case, saturation is due to the alteration of volcanogenic material which releases large amounts of Ca to the porewaters, where the Ca concentration can reach 55 times its seawater value as for example at ODP Leg 134 site 833. At a few sites, saturation is reached in hydrothermal environments, or as a consequence of the alteration of the basaltic basement. In addition to the well known influence of brines on the formation of gypsum, these results indicate that the alteration of sediments rich in volcanogenic material is a major process leading to gypsum saturation in marine sediment porewaters. Therefore, the presence of gypsum in ancient and recent marine sediments should not be systematically interpreted as due to hypersaline waters, especially if volcanogenic material is present.

Related to:

Hoareau, Guilhem; Monnin, Christophe; Odonne, Francis (2011): The stability of gypsum in marine sediments using the entire ODP/IODP porewater composition database. Marine Geology, 279(1-4), 87-97, https://doi.org/10.1016/j.margeo.2010.10.014

Project(s):

Ocean Drilling Program (ODP)

Coverage:

Median Latitude: -1.216891 * Median Longitude: 115.745328 * South-bound Latitude: -50.228000 * West-bound Longitude: 4.509930 * North-bound Latitude: 41.000410 * East-bound Longitude: -75.772900

Date/Time Start: 1986-01-18T08:20:00 * Date/Time End: 2001-04-14T01:30:00

Minimum DEPTH, sediment/rock: 218 m * Maximum DEPTH, sediment/rock: 5709 m

Event(s):

107-652A * Latitude: 40.355000 * Longitude: 12.143200 * Date/Time Start: 1986-01-18T08:20:00 * Date/Time End: 1986-01-28T21:30:00 * Elevation: -3446.0 m * Penetration: 721.1 m * Recovery: 445.3 m * Location: Tirreno Sea * Campaign: * Basis: Joides Resolution * Method/Device: Drilling/drill rig (DRILL) * Comment: 75 cores; 721.1 m cored; 0 m drilled; 61.8 % recovery

107-654A * Latitude: 40.579300 * Longitude: 10.696700 * Date/Time Start: 1986-02-03T10:40:00 * Date/Time End: 1986-02-08T15:15:00 * Elevation: -2208.0 m * Penetration: 473.8 m * Recovery: 239.84 m * Location: Tirreno Sea * Campaign: * Basis: Joides Resolution * Method/Device: Drilling/drill rig (DRILL) * Comment: 52 cores; 473.8 m cored; 0 m drilled; 50.6 % recovery

119-737B * Latitude: -50.228000 * Longitude: 73.032400 * Date/Time Start: 1987-12-31T17:15:00 * Date/Time End: 1988-01-04T09:30:00 * Elevation: -575.0 m * Penetration: 715.5 m * Recovery: 298.35 m * Location: Indian Ocean * Campaign: * Basis: Joides Resolution * Method/Device: Drilling/drill rig (DRILL) * Comment: 50 cores; 481.3 m cored; 0 m drilled; 62 % recovery

Comment:

Sediment depth is given in mbsf.

i = saturation reached due to the presence of saline brines with high Ca and SO4 concentrations.

ii = saturation reached in porewaters with a salinity close to the seawater value and a high Ca concentration, in relation to the alteration of volcanic material.

iii = hydrothermal environment.

iv = saturation reached due to the alteration of the basaltic basement.

Parameter(s):

#	Name	Short Name	Unit	Principal Investigator	Method/Device	Comment
1	Event label	Event
2	Area/locality	Area		Hoareau, Guilhem
3	DEPTH, sediment/rock	Depth sed	m			Geocode
4	Depth, reconstructed	Reconstr depth	m	Hoareau, Guilhem		Porewater sample max depth (mbsf)
5	Saturation index	SI		Hoareau, Guilhem	Calculated	Gypsum saturation lower depth
6	Comment	Comment		Hoareau, Guilhem

License:

Creative Commons Attribution 3.0 Unported (CC-BY-3.0)

Size:

104 data points

Data

Download dataset as tab-delimited text — use the following character encoding:

1 Event	2 Area	3 Depth sed [m]	4 Reconstr depth [m]	5 SI	6 Comment
107-652A	Tyrrhenian Sea	3446	607	485	i
107-654A	Tyrrhenian Sea	2208	404	239	i
119-737B	Kerguelen Plateau	564	608	348	ii
121-757B	Ninetyeast Ridge	1652	340	136	ii
121-757C	Ninetyeast Ridge	1644	364	150	ii
126-787B	Izu-Bonin Forearc	3259	301	275	ii
126-792E	Izu-Bonin Forearc	1788	796	478	ii
126-793B	Izu-Bonin Forearc	2965	1258	724	ii
134-830B	Vanuatu	1018	341	215	ii
134-830C	Vanuatu	1018	341	215	ii
134-832B	Vanuatu	3089	833	408	ii
134-833B	Vanuatu	2629	764	281	ii
141-863B	Chile Triple Junction	2564	738	639	iii (?)
160-968A	Mediterranean Sea	1961	298	211	i
160-972A	Mediterranean Sea	3931	90	53	i
160-973A	Mediterranean Sea	3695	143	61	i
161-975B	Mediterranean Sea	2415	305	305	i
169-1038B	Juan de Fuca Ridge	3254	111	55	iii
182-1126B	Great Australian Bight	3967	409	69	i
182-1129D	Great Australian Bight	3874	541	541	i
182-1130A	Great Australian Bight	487	326	230	i
182-1130C	Great Australian Bight	487	326	230	i
182-1132C	Great Australian Bight	218	547	358	i
182-1134A	Great Australian Bight	701	350	28	i
194-1198B	Marion Plateau	319	505	488	iv
195-1201D	Philippine Sea	5709	387	267	ii