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Clay mineral distribution in surface sediments

Nürnberg, Dirk ; Levitan, Mikhail A ; Pavlidis, Yury A ; [et al.]

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In: Supplement to: Nürnberg, Dirk; Levitan, Mikhail A; Pavlidis, Yury A; Shelekhova, E S (1995): Distribution of clay minerals in surface sediments from the eastern Barents and south-western Kara seas. Geologische Rundschau, 84(3), 665-682, https://doi.org/10.1007/BF00284528

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Publication Date: 2023-05-12

Description: Surface samples from the eastern Barents and south-western Kara seas have been analysed for clay mineralogy. Transport paths, the role of regional sources and local bedrock outcrops and the influence of hydrodynamic and glacigenous processes for clay distribution on the shelves are discussed in relation to central Arctic Ocean deep sea and sea ice sediments. Franz Josef Land and Novaya Zemlya show significantly different clay mineral associations. Although smectite concentrations are fairly high, Franz Josef Land can be excluded as a source for central Arctic sea ice sediments, which are relatively rich in smectite. In the Kara Sea, smectite concentrations in coastal sediments surpass even the Franz Josef Land concentrations. The large cyclonic gyre in the eastern Barents Sea between Novaya Zemlya and Franz Josef Land, which serves as a mixing zone between Arctic and North Atlantic water, is apparently reflected within the smectite distribution pattern. With the exception of Franz Josef Land, the area of investigation is typically low in kaolinite. In particular, coastal areas and areas north of Novaya Zemlya, influenced by the inflow of Arctic waters, show the lowest kaolinite concentrations. A high kaolinite occurrence within the Nansen Basin is most probably related to Franz Josef Land and emphasizes the importance of long-range downslope transport of sediments across the continental slope. The surface water circulation pattern in close interaction with local outcrops onshore Novaya Zemlya and locally restricted occurrences within the eastern Barents Sea significantly alter the illite dispersal pattern. Illite concentrations are lowest around Franz Josef Land. Chlorite is generally low in the area of investigation. Submarine outcrops and important chlorite occurrences onshore Novaya Zemlya bias its distribution pattern.

Keywords: 01091-1; 10911; 180811; 18081-1; 180821; 18082-1; 190811; 19081-1; 200811; 20081-1; 200822; 20082-2; 200831; 20083-1; 210821; 21082-1; 210842; 21084-2; 220811; 22081-1; 220822; 22082-2; 230812; 23081-2; 240811; 24081-1; 250811; 25081-1; 260811; 26081-1; 270811; 27081-1; 270822; 27082-2; 280811; 28081-1; 300811; 30081-1; 300821; 30082-1; 300831; 30083-1; 310822; 31082-2; AWI_Paleo; Barents Sea; Camp; Chejsa Island; Chlorite; Dalniye Zelentsy; DEPTH, sediment/rock; DZ-68; Elevation of event; Event label; Giant box corer; GKG; Grain size, sieving/settling tube; Greem Bell Island; Hooker Island; Illite; Kaolinite; Kara Sea; Klagenfurt; Latitude of event; Longitude of event; Nordenskiöld Bay; off Franz Joseph Land; off Novaja Zemlya; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Professor Shtokman; Quaternary Environment of the Eurasian North; QUEEN; Russian Bay; SHT1265; SHT1266; SHT1267; SHT1268; SHT1269; SHT1271; SHT1272; SHT1273; SHT1275; SHT1277; SHT1280; SHT1282; SHT1284; SHT1286; SHT1289; SHT1292; SHT1293; SHT1294; SHT1295.1; SHT1295.2; SHT1298; SHT1299; SHT1300; SHT1301; SHT1302; SHT1303.1; SHT1303.2; SHT1305; SHT1306; SHT1307.1; SHT1307.2; SHT1308; SHT1310; SHT1311; SHT1317; SHT1322; SHT1323.1; SHT1323.2; SHT1324; SHT1325; SHT1326; SHT1327; SHT1328; SHT1332; SHT1333; SHT1334; SHT1335; SHT1339; SHT1341; SHT1342; SHT1343; SHT1346; SHT1350; SHT1352; SHT1367; SHT1369; SHT1371; SHT1372; SHT1373; SHT1374; SHT1375; SHT1376; SHT1378; SHT1379; SHT1380; SHT1381; SHT1382; SHT1385; SHT1386; SHT1387; SHT1388; SHT1389; SHT1391; SHT1394; SHT1395; SHT1396; SHT1397; SHT1399; SHT1400; SHT1401; SHT1402; SHT1403; SHT1407; SHT1409; SHT1412; SHT2146; SHT2149; SHT2163; SHT2167; SHT594; SHT595; SHT8/10/12; Size fraction 〈 0.001 mm, clay; Smectite; van Veen Grab; Velkitsky Bay; VGRAB; Water sample; Wiener Neustadt; WS; X-ray diffraction TEXTUR, clay fraction

Type: Dataset

Format: text/tab-separated-values, 540 data points

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Distribution of clay minerals in surface sediments of the Eurasian Arctic Ocean

Wahsner, Monika ; Müller, Claudia ; Stein, Ruediger ; [et al.]

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In: Supplement to: Wahsner, Monika; Müller, Claudia; Stein, Ruediger; Ivanov, Gennadiy I; Levitan, Mikhail A; Shelekhova, E S; Tarasov, Gennadiy A (1999): Clay-mineral distribution in surface sediments of the Eurasian Arctic Ocean and continental margin as indicator for source areas and transport pathways - a synthesis. Boreas, 28(1), 215-233, https://doi.org/10.1111/j.1502-3885.1999.tb00216.x

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Publication Date: 2023-06-27

Description: Clay-mineral distributions in the Arctic Ocean and the adjacent Eurasian shelf areas are discussed to identify source areas and transport pathways of terrigenous material in the Arctic Ocean. The main clay minerals in Eurasian Arctic Ocean sediments are illite and chlorite. Smectite and kaolinite occur in minor amounts in these sediments, but show strong variations in the shelf areas. These two minerals are therefore reliable in reconstructions of source areas of sediments from the Eurasian Arctic. The Kara Sea and the western part of the Laptev Sea are enriched in smectite, with highest values of up to 70% in the deltas of the Ob and Yenisey rivers. Illite is the dominant clay mineral in all the investigated sediments except for parts of the Kara Sea. The highest concentrations with more than 70% illite occur in the East Siberian Sea and around Svalbard. Chlorite represents the clay mineral with lowest concentration changes in the Eastern Arctic, ranging between 10 and 25%. The main source areas for kaolinite in the Eurasian Arctic are Mesozoic sedimentary rocks on Franz-Josef Land islands. Based on clay-mineral data, transport of the clay fraction via sea ice is of minor importance for the modern sedimentary budget in the Arctic basins.

Keywords: 41; 42; 4381-1; 4387-1; 4397-1; 4399-1; 4403-1; 4404-1; 4405-1; 4411-1; 4413-1; 4414-1; 4416-1; 4418-1; AG80; AG80/10-1; AG80/1-1; AG80/11-1; AG80/12-1; AG80/13-1; AG80/14-1; AG80/15-1; AG80/16-1; AG80/17-1; AG80/2-1; AG80/3-1; AG80/4-1; AG80/5-1; AG80/6-1; AG80/7-1; AG80/8-1; AG80/9-1; Akademik Golitsyn; Amundsen Basin; Arctic Ocean; ARK-IV/3; ARK-IX/4; ARK-VIII/2; ARK-VIII/3; ARK-XI/1; AWI_Paleo; Barents Sea; BC; BCR; Bear Island Trough; Box corer; Box corer (Reineck); Calculated; Chlorite; Chuk17; Chuk181; Chuk183; Chuk184; Chuk186; Chuk189; Chuk201; Chuk21; Chuk223; Chuk226; Chuk30; Chuk49; Chuk50; Chuk53; Chuk56; Chuk8; Chuk9; CTD/Rosette; CTD-RO; DEPTH, sediment/rock; DM49; Dmitry Mendeleev; East Siberian Sea; Elevation of event; ES281; ES282; ES284; ES285; ES286; ES288; ES289; ES290; ES291; ES292; ES293; ES295; ES314; ES315; ES316; ES317; ES318; ES320; ES323; ES326; Event label; Fram Strait; Franz Joseph Land/St. Anna Trough; Gakkel Ridge, Arctic Ocean; Giant box corer; Giant piston corer; GIK21520-10 PS11/310-10; GIK21521-13 PS11/340-13; GIK21522-19 PS11/358-19; GIK21523-14 PS11/362-14; GIK21524-1 PS11/364-1; GIK21525-2 PS11/365-2; GIK21526-5 PS11/370-5; GIK21527-18 PS11/371-18; GIK21528-7 PS11/372-7; GIK21529-7 PS11/376-7; GIK21530-3 PS11/382-3; GIK21532-1 PS11/396-1; GIK21534-6 PS11/423-6; GIK21535-5 PS11/430-5; GKG; GPC; Gravity corer (Kiel type); Gravity corer (Russian type); Illite; Jenissei; KAL; KAL_R; Kaolinite; Kaolinite/Chlorite ratio; Kara Sea; Kara Sea/St. Anna Trough; Kasten corer; Kasten corer RUS; Laptev Sea; Laptev Sea, Taymyr Island; LATITUDE; Lomonosov Ridge, Arctic Ocean; LONGITUDE; Makarov Basin; Men4376-1; Men4377-1; Men4378-1; Men4379-1; Men4380-1; Men4381-1; Men4382-1; Men4383-1; Men4384-1; Men4385-1; Men4386-1; Men4387-1; Men4390-1; Men4391-1; Men4394-1; Men4395-1; Men4397-1; Men4398-1; Men4399-1; Men4400-1; Men4401-1; Men4402-1; Men4403-1; Men4404-1; Men4405-1; Men4406-1; Men4409-1; Men4410-1; Men4411-1; Men4413-1; Men4414-1; Men4416-1; Men4417-1; Men4418-1; Mooring (long time); MOORY; Morris Jesup Rise; MUC; MULT; MultiCorer; Multiple investigations; Nansen Basin; Ob; OD-006-06; OD-007-02; OD-008-05; OD-009-08; OD-010-06; OD-011-03; OD-017-01; OD-024-06; OD-025-05; OD-026-09; OD-027-03; OD-031-03; OD-032-04; OD-035-02; OD-036-04; OD-041-04; OD-042-01; Oden; ODEN-96; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; PL-1994; PL94-01; PL94-02; PL94-03; PL94-04; PL94-05; PL94-07; PL94-08; PL94-09; PL94-10; PL94-11; PL94-12; PL94-13; PL94-16; PL94-18; PL94-19; PL94-20; PL94-22; PL94-23; PL94-25; PL94-26; PL94-28; PL94-30; PL94-31; PL94-32; PL94-34; PL94-35; PL94-37; PL94-38; PL94-39; PL94-40; PL94-41; PL94-42; PL94-44; PL94-46; PL94-50; PL94-51; PL94-53; PL94-54; PL94-55; PL94-56; PL94-57; PL94-58; PL94-60; PL94-62; PL94-63; PL94-64; PL94-65; PL94-67; PL94-68; PL94-70; Polarstern; Professor Logachev; PS11; PS11/269-12; PS1511-12; PS1520-10; PS1521-13; PS1522-19; PS1523-14; PS1524-1; PS1525-2; PS1526-5; PS1527-18; PS1528-7; PS1529-7; PS1530-3; PS1532-1; PS1534-6; PS1535-5; PS19/040; PS19/045; PS19/050; PS19/055; PS19/070; PS19/078; PS19/080; PS19/081; PS19/082; PS19/084; PS19/086; PS19/090; PS19/091; PS19/094; PS19/098; PS19/100; PS19/101; PS19/102; PS19/104; PS19/105; PS19/108; PS19/110; PS19/111; PS19/112; PS19/116; PS19/117; PS19/119; PS19/124; PS19/126; PS19/132; PS19/134; PS19/136; PS19/143; PS19/148; PS19/150; PS19/151; PS19/152; PS19/153; PS19/155; PS19/157; PS19/158; PS19/159; PS19/160; PS19/161; PS19/164; PS19/165; PS19/166; PS19/167; PS19/171; PS19/172; PS19/173; PS19/175; PS19/176; PS19/178; PS19/181; PS19/182; PS19/183; PS19/184; PS19/185; PS19/186; PS19/189; PS19/190; PS19/192; PS19/194; PS19/198; PS19/200; PS19/204; PS19/206; PS19/210; PS19/214; PS19/216; PS19/218; PS19/222; PS19/226; PS19/239; PS19/241; PS19/245; PS19/246; PS19/249; PS19/252; PS19 ARCTIC91; PS19 EPOS II; PS2111-2; PS2113-1; PS2114-1; PS2115-1; PS2116-1; PS2117-1; PS2119-2; PS2120-1; PS2121-1; PS2122-1; PS2123-3; PS2124-1; PS2125-2; PS2127-1; PS2128-1; PS2129-2; PS2130-2; PS2131-1; PS2132-3; PS2133-1; PS2134-1; PS2136-3; PS2137-4; PS2138-2; PS2142-3; PS2143-1; PS2144-3; PS2147-3; PS2148-1; PS2149-1; PS2150-1; PS2151-1; PS2153-1; PS2156-1; PS2157-1; PS2158-1; PS2159-6; PS2160-1; PS2162-1; PS2163-1; PS2164-6; PS2165-1; PS2166-3; PS2167-1; PS2168-1; PS2170-1; PS2171-1; PS2172-1; PS2174-1; PS2175-5; PS2176-4; PS2177-1; PS2178-1; PS2179-3; PS2180-1; PS2181-4; PS2182-1; PS2183-4; PS2184-1; PS2185-7; PS2186-1; PS2187-5; PS2189-1; PS2190-5; PS2192-3; PS2193-1; PS2194-1; PS2195-1; PS2196-2; PS2198-4; PS2199-1; PS2200-6; PS2202-11; PS2205-3; PS2209-3; PS2210-1; PS2212-1; PS2213-6; PS2214-1; PS2215-4; PS2439-1; PS2440-5; PS2441-1; PS2442-1; PS2443-3; PS2444-1; PS2445-4; PS2446-1; PS2447-5; PS2448-1; PS2449-3; PS2450-2; PS2451-2; PS2452-2; PS2453-2; PS2455-3; PS2456-2; PS2457-1; PS2458-3; PS2459-2; PS2460-3; PS2461-2; PS2462-3; PS2463-3; PS2466-3; PS2467-3; PS2468-3; PS2469-3; PS2470-4; PS2471-3; PS2472-3; PS2473-3; PS2474-2; PS2475-1; PS2476-3; PS2477-3; PS2478-3; PS2481-2; PS2482-3; PS2483-2; PS2484-2; PS2486-2; PS27; PS27/001; PS27/006; PS27/007; PS27/014; PS27/016; PS27/017; PS27/019; PS27/020; PS27/024; PS27/025; PS27/027; PS27/028; PS27/029; PS27/030; PS27/031; PS27/033; PS27/034; PS27/035; PS27/038; PS27/039; PS27/040; PS27/041; PS27/043; PS27/044; PS27/048; PS27/049; PS27/050; PS27/052; PS27/053; PS27/054; PS27/056; PS27/058; PS27/059; PS27/060; PS27/062; PS27/064; PS27/065; PS27/068; PS27/069; PS27/070; PS27/071; PS27/073; PS2718-6; PS2721-6; PS2722-1; PS2723-4; PS2724-4; PS2725-5; PS2726-1; PS2727-7; PS2728-2; PS2729-6; PS2730-3; PS2740-1; PS2741-1; PS2742-3; PS2744-6; PS2745-7; PS2749-3; PS2750-1; PS2752-1; PS2753-1; PS2755-1; PS2756-1; PS2757-8; PS2758-1; PS2759-1; PS2760-6; PS2761-1; PS2762-6; PS2763-1; PS2764-8; PS2765-1; PS2767-1; PS2768-4; PS2773-1; PS2774-2; PS2775-1; PS2778-2; PS2779-1; PS2780-6; PS2781-1; PS2787-1; PS2791-1; PS2792-6; PS36; PS36/002; PS36/004; PS36/006; PS36/007; PS36/008; PS36/009; PS36/010; PS36/011; PS36/012; PS36/016; PS36/017; PS36/027; PS36/028; PS36/030; PS36/032; PS36/033; PS36/044; PS36/045; PS36/047; PS36/048a; PS36/050; PS36/051LOMO-2; PS36/052; PS36/053; PS36/055; PS36/056; PS36/057; PS36/059; PS36/060; PS36/062; PS36/064; PS36/066; PS36/067; PS36/075; PS36/076; PS36/079; PS36/082; PS36/083; PS36/084; PS36/085; PS36/091; PS36/095; PS36/096; Quaternary Environment of the Eurasian North; QUEEN; RGC; RUS_unspec; SL; Smectite; Smectite/Illite ratio; SPASIBAIII; Svalbard; van Veen Grab; VGRAB; Vilkitsky Strait; Water sample; WS; X-ray diffraction TEXTUR, clay fraction; Yermak Plateau

Type: Dataset

Format: text/tab-separated-values, 2010 data points

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Distribution of clay minerals in surface sediments from the eastern Barents and south-western Kara seas (1995)

Nürnberg, D. ; Levitan, M. A. ; Pavlidis, J. A. ; [et al.]

Springer

Geologische Rundschau 84 (1995), S. 665-682

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ISSN: 0016-7835

Keywords: Key words Clay mineralogy ; Eurasian Arctic shelves ; Dispersal processes ; Potential source areas ; Lithogenic tracers ; Sea ice transport

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract Surface samples from the eastern Barents and south-western Kara seas have been analysed for clay mineralogy. Transport paths, the role of regional sources and local bedrock outcrops and the influence of hydrodynamic and glacigenous processes for clay distribution on the shelves are discussed in relation to central Arctic Ocean deep sea and sea ice sediments. Franz Josef Land and Novaya Zemlya show significantly different clay mineral associations. Although smectite concentrations are fairly high, Franz Josef Land can be excluded as a source for central Arctic sea ice sediments, which are relatively rich in smectite. In the Kara Sea, smectite concentrations in coastal sediments surpass even the Franz Josef Land concentrations. The large cyclonic gyre in the eastern Barents Sea between Novaya Zemlya and Franz Josef Land, which serves as a mixing zone between Arctic and North Atlantic water, is apparently reflected within the smectite distribution pattern. With the exception of Franz Josef Land, the area of investigation is typically low in kaolinite. In particular, coastal areas and areas north of Novaya Zemlya, influenced by the inflow of Arctic waters, show the lowest kaolinite concentrations. A high kaolinite occurrence within the Nansen Basin is most probably related to Franz Josef Land and emphasizes the importance of long-range downslope transport of sediments across the continental slope. The surface water circulation pattern in close interaction with local outcrops onshore Novaya Zemlya and locally restricted occurrences within the eastern Barents Sea significantly alter the illite dispersal pattern. Illite concentrations are lowest around Franz Josef Land. Chlorite is generally low in the area of investigation. Submarine outcrops and important chlorite occurrences onshore Novaya Zemlya bias its distribution pattern.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00284528

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Distribution of clay minerals in surface sediments from the eastern Barents and south-western Kara seas (1995)

Nürnberg, D. ; Levitan, M. A. ; Pavlidis, J. A. ; [et al.]

Springer

International journal of earth sciences 84 (1995), S. 665-682

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ISSN: 1437-3262

Keywords: Clay mineralogy ; Eurasian Arctic shelves ; Dispersal processes ; Potential source areas ; Lithogenic tracers ; Sea ice transport

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract Surface samples from the eastern Barents and south-western Kara seas have been analysed for clay mineralogy. Transport paths, the role of regional sources and local bedrock outcrops and the influence of hydrodynamic and glacigenous processes for clay distribution on the shelves are discussed in relation to central Arctic Ocean deep sea and sea ice sediments. Franz Josef Land and Novaya Zemlya show significantly different clay mineral associations. Although smectite concentrations are fairly high, Franz Josef Land can be excluded as a source for central Arctic sea ice sediments, which are relatively rich in smectite. In the Kara Sea, smectite concentrations in coastal sediments surpass even the Franz Josef Land concentrations. The large cyclonic gyre in the eastern Barents Sea between Novaya Zemlya and Franz Josef Land, which serves as a mixing zone between Arctic and North Atlantic water, is apparently reflected within the smectite distribution pattern. With the exception of Franz Josef Land, the area of investigation is typically low in kaolinite. In particular, coastal areas and areas north of Novaya Zemlya, influenced by the inflow of Arctic waters, show the lowest kaolinite concentrations. A high kaolinite occurrence within the Nansen Basin is most probably related to Franz Josef Land and emphasizes the importance of long-range downslope transport of sediments across the continental slope. The surface water circulation pattern in close interaction with local outcrops onshore Novaya Zemlya and locally restricted occurrences within the eastern Barents Sea significantly alter the illite dispersal pattern. Illite concentrations are lowest around Franz Josef Land. Chlorite is generally low in the area of investigation. Submarine outcrops and important chlorite occurrences onshore Novaya Zemlya bias its distribution pattern.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00284528

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