Citation:

j.margeo.2008.12.008

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Abstract:

Continental shelves represent areas of highest economical and ecological importance. Nevertheless, these sedimentary systems remain poorly understood due to a complex interplay of various factors and processes which results in highly individual construction schemes. Previous studies of sedimentary shelf systems have mainly focused on a limited number of cores, retrieved from Holocene fine-grained depocentres. As such, the relation between shelf architecture and sedimentary history remains largely obscure. Here, we present new data from the NW Iberian shelf comprising shallow-seismic profiles, a large number of sediment cores, and an extended set of radiocarbon dates to reveal the Late Quaternary evolution of a low-accumulation shelf system in detail.

On the NW Iberian shelf, three main seismic units are identified. These overly a prominent erosional unconformity on top of the basement. The lowermost Unit 1 is composed of maximal 75-m thick, Late Tertiary to Pleistocene deposits. The youngest sediments of this unit are related to the last glacial sea-level fall. Unit 2 was controlled by the deglacial sea-level rise and shows a maximum thickness of 15 m. Finally, Unit 3 comprises deposits related to the late stage of sea-level rise and the modern sea-level highstand with a thickness of 4 m in mid-shelf position. Two pronounced seismic reflectors separate these main units from each other. Their origin is related to (1) exposure and ravinement processes during lower sea level, and (2) to reworking and re-deposition of coarse sediments during subsequent sea-level rise.

According to the sediment core ground-truthing, sediments of the Late Tertiary to Pleistocene unit predominantly display homogenous fine sands with exceptional occurrences of palaeosols that indicate an ancient exposure surface. Fine sands which were deposited in the run of the last sea-level rise show a time-transgressive retrogradational development. The seismic reflectors, bounding the individual units, appear in the cores as 0.1 to 1-m thick deposits consisting either of shell gravels or siliceous coarse sands with gravels. The modern sea-level highstand stage is characterised by zonal deposition of mud forming a mud belt in mid-shelf position, and sediment starvation on outer shelf zones. Radiocarbon ages indicate that this mud belt was the main depocentre for river-supplied fine material on the NW Iberian shelf at least over the past 5.32 ka BP. The initial onset of this depocentre is proposed to be related to a shift in the balance between rate of sea-level rise and amount of terrigenous sediment supply.

Various other stratigraphical shelf reconstructions reveal analogies in architecture which indicate that timing and shaping of the individual units on low-accumulation shelves is fundamentally controlled by eustatic sea-level changes. Other factors of local importance such as differential elevation of the basement and the presence of morphological barriers formed by rocky outcrops on the seafloor have additionally modifying influence on the sedimentary processes.

Project(s):

Center for Marine Environmental Sciences (MARUM)

Coverage:

Median Latitude: 42.226977 * Median Longitude: -9.180259 * South-bound Latitude: 41.633500 * West-bound Longitude: -9.516667 * North-bound Latitude: 42.769722 * East-bound Longitude: -8.974167

Date/Time Start: 2006-08-22T07:20:00 * Date/Time End: 2008-06-15T13:43:00

Minimum DEPTH, sediment/rock: 0.49 m * Maximum DEPTH, sediment/rock: 4.89 m

Event(s):

GeoB11002-3 * Latitude: 42.166694 * Longitude: -8.990167 * Date/Time: 2006-08-22T07:20:00 * Elevation: -111.0 m * Recovery: 4.39 m * Campaign: * Basis: * Method/Device: Vibro corer (VC)

GeoB11003-3 * Latitude: 42.166833 * Longitude: -9.040139 * Date/Time: 2006-08-22T09:08:00 * Elevation: -129.0 m * Recovery: 4.54 m * Campaign: * Basis: * Method/Device: Vibro corer (VC)

GeoB11004-2 * Latitude: 42.166750 * Longitude: -9.104861 * Date/Time: 2006-08-22T10:37:00 * Elevation: -141.0 m * Recovery: 3.5 m * Campaign: * Basis: * Method/Device: Vibro corer (VC)

Comment:

Age, minimum/young and Age, maximum/old: For reservoir correction, the conventional age of 400 years is applied using CALIB 5.0.1. (Stuiver et al., 1998).

b: Reservoir correction based on the function of Bard et al. (1998).

bF = benthic foraminifers; E. crispum = Elphidium crispum (monospecific sample); bv = bivalve; gp = gastropod

Parameter(s):

#	Name	Short Name	Unit	Principal Investigator	Method/Device	Comment
1	Event label	Event
2	Latitude of event	Latitude
3	Longitude of event	Longitude
4	Elevation of event	Elevation	m
5	DEPTH, sediment/rock	Depth sed	m			Geocode
6	Sample, optional label/labor no	Lab no		Lantzsch, Hendrik		KIA = Leibniz Laboratory in Kiel (Germany); Poz = Poznan Radiocarbon Laboratory (Poland)
7	Age, dated material	Dated material		Lantzsch, Hendrik
8	Age, dated	Age dated	ka BP	Lantzsch, Hendrik	Age, 14C AMS	BP
9	Age, dated standard deviation	Age dated std dev	±	Lantzsch, Hendrik		BP
10	Age, minimum/young	Age min	ka	Lantzsch, Hendrik	see comment	1 Sigma calibrated
11	Age, maximum/old	Age max	ka	Lantzsch, Hendrik	see comment	1 Sigma calibrated
12	Comment	Comment		Lantzsch, Hendrik
13	Age, dated	Age dated	ka	Lantzsch, Hendrik		Intercept
14	Age, dated standard deviation	Age dated std dev	±	Lantzsch, Hendrik		Intercept
15	Stratigraphy	Stratigraphy		Lantzsch, Hendrik		Stratigraphic position

License:

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

Size:

283 data points

Data

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

1 Event	2 Latitude	3 Longitude	4 Elevation [m]	5 Depth sed [m]	6 Lab no (KIA = Leibniz Laboratory in K...)	7 Dated material	8 Age dated [ka BP] (BP, Age, 14C AMS)	9 Age dated std dev [±] (BP)	10 Age min [ka] (1 Sigma calibrated, see comment)	11 Age max [ka] (1 Sigma calibrated, see comment)	12 Comment	13 Age dated [ka] (Intercept)	14 Age dated std dev [±] (Intercept)	15 Stratigraphy (Stratigraphic position)
GeoB11002-3	42.1667	-8.9902	-111	2.50	KIA 33665	bF	2.715	0.035	2.342	2.455		2.40	0.06	U3
GeoB11002-3	42.1667	-8.9902	-111	4.35	KIA 33664	bF, bv pieces, gp	4.955	0.045	5.249	5.388		5.32	0.07	U3
GeoB11003-3	42.1668	-9.0401	-129	2.40	Poz-24670	bF	7.840	0.050	8.259	8.371		8.32	0.06	U3
GeoB11003-3	42.1668	-9.0401	-129	3.60	Poz-22923	bF	10.770	0.050	12.101	12.321		12.21	0.11	U3
GeoB11003-3	42.1668	-9.0401	-129	3.99	Poz-24771	bF	13.080	0.070	14.814	15.107		14.96	0.15	U2
GeoB11004-2	42.1668	-9.1049	-141	2.77	KIA 33668	bv piece	14.660	0.100	16.793	17.297		17.05	0.25	R1
GeoB11005-2	42.1667	-9.1806	-161	2.50	Poz-22944	E. crispum	18.470	0.100	21.160	21.689		21.42	0.26	R1
GeoB11005-2	42.1667	-9.1806	-161	3.00	Poz-22945	bF, bv pieces	46.000	3.000	48.878	54.952	b	51.91	3.04	U1
GeoB11010-2	42.4167	-9.1079	-119	3.77	Poz-22946	E. crispum	15.540	0.080	18.220	18.690		18.46	0.24	R1
GeoB11012-2	42.7082	-9.2667	-119	1.00	Poz-22925	bF	3.995	0.035	3.949	4.068		4.01	0.06	U3
GeoB11012-2	42.7082	-9.2667	-119	3.20	Poz-22948	E. crispum	14.820	0.080	17.073	17.554		17.31	0.24	R1
GeoB11014-2	42.7082	-9.4608	-153	4.41	KIA 33675	bF, bv pieces	>42580.000				uncalibrated	>42.58		U1
GeoB11015-2	42.7697	-9.4661	-159	4.30	KIA 33692	bF, bv pieces	30.710	0.670	35.016	36.496	b	35.76	0.74	U1
GeoB11015-2	42.7697	-9.4661	-159	4.48	KIA 33781	plant debris, char coal	49.140	2.930	52.154	57.976	b	55.07	2.91	U1
GeoB11017-2	42.5196	-9.2446	-120	2.47	KIA 33683	E. crispum	28.520	0.480	32.787	33.860	b	33.32	0.54	U1
GeoB11017-2	42.5196	-9.2446	-120	4.17	KIA 33684	E. crispum	>42090.000				uncalibrated	>42.09		U1
GeoB11017-2	42.5196	-9.2446	-120	4.86	KIA 33685	bF	>44990.000				uncalibrated	>44.99		U1
GeoB11027-2	41.9666	-9.1764	-136	0.49	KIA 33699	E. crispum	17.040	0.130	19.567	19.900		19.74	0.17	U2
GeoB11027-2	41.9666	-9.1764	-136	4.54	KIA 33700	E. crispum	19.120	0.160	22.141	22.419		22.28	0.14	U2
GeoB11028-2	41.9666	-9.0916	-127	1.40	Poz-21470	bF	2.555	0.030	2.184	2.290		2.24	0.05	U3
GeoB11028-2	41.9666	-9.0916	-127	4.16	Poz-21471	E. crispum	16.780	0.080	19.444	19.756		19.60	0.16	U2
GeoB11028-2	41.9666	-9.0916	-127	4.29	Poz-22950	E. crispum	17.310	0.190	19.862	20.243		20.05	0.19	R1
GeoB11029-2	41.9666	-9.0451	-114	1.03	KIA 33687	bF	0.850	0.030	4.585	0.503		0.48	0.02	U3
GeoB11029-2	41.9666	-9.0451	-114	3.26	KIA 33688	bF, bv pieces	2.830	0.035	2.533	2.676		2.61	0.07	U3
GeoB11029-2	41.9666	-9.0451	-114	3.60	Poz-24772	bF	2.910	0.035	2.669	2.737		2.70	0.03	U3
GeoB11029-2	41.9666	-9.0451	-114	4.88	KIA 33689	echinoderm pieces	12.740	0.080	14.082	14.475		14.28	0.20	U2
GeoB11030-2	41.9667	-8.9900	-94	2.20	Poz-21472	bF	2.940	0.035	2.693	2.749		2.72	0.03	U3
GeoB11030-2	41.9667	-8.9900	-94	4.60	Poz-21473	bF, bv	10.740	0.050	12.035	12.255		12.15	0.11	U2
GeoB11038-2	41.6342	-8.9742	-78	1.20	Poz-22951	bF	3.165	0.035	2.888	3.013		2.95	0.06	U3
GeoB11038-2	41.6342	-8.9742	-78	4.60	Poz-22952	bF, gp	16.880	0.090	19.501	19.793		19.65	0.15	U2
GeoB13089-2	42.7080	-9.5167	-190	4.89	Poz-26862	E. crispum	17.850	0.100	20.414	20.742		20.58	0.16	U2
GeoB130207-3	41.6335	-9.2283	-146	4.30	Poz-26864	bF	18.280	0.110	20.900	21.338		21.12	0.22	U2