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  • 1975-1979  (865,706)
  • 1960-1964  (438,949)
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Year
  • 1
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    Chemical composition of East Pacific Rise basal sediments (1976)
    PANGAEA
    In:  Department of Earth Science and Engineering, Imperial College London | Supplement to: Cronan, David S (1976): Basal metalliferous sediments from the eastern Pacific. Geological Society of America Bulletin, 87(6), 928-934, https://doi.org/10.1130/0016-7606(1976)87%3C928:BMSFTE%3E2.0.CO;2
    Details
    Publication Date: 2024-07-01
    Description: Analyses by atomic absorption spectrophotometry and spark-source mass spectrography of 25 basal metalliferous sediment units from widely spaced locations on the western flank of the East Pacific Rise show that the deposits are enriched relative to normal pelagic sediment in Fe, Mn, Ni, Cu, Pb, Zn, and many trace elements. The elements are partitioned differently between the various mineralogic constituents of the sediment, with Fe and Mn largely in separate phases and many of the remaining elements primarily associated with reducible ferromanganese oxide minerals but also with iron minerals and other phases. Most of the iron in the deposits is probably of volcanic origin, and much of the manganese and minor elements is derived from sea water. The bulk composition of the deposits varies with age; this is thought to be due to variations in the incidence of volcanic activity at the East Pacific Rise crest where the deposits were formed.
    Keywords: 16-162; 5-37; 5-38; 5-39; 7-66; 8-74; 8-75; 9-77B; 9-78; 9-80; 9-82; Deep Sea Drilling Project; DRILL; Drilling/drill rig; DSDP; Glomar Challenger; Leg16; Leg5; Leg7; Leg8; Leg9; North Pacific/BASIN; North Pacific/CONT RISE; North Pacific/HILL; South Pacific/BASIN; South Pacific/CONT RISE; South Pacific/VALLEY
    Type: Dataset
    Format: application/zip, 2 datasets
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  • 2
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    Unknown
    C4-C7 alkenones in deep sea sediments (1975)
    PANGAEA
    In:  Supplement to: Hunt, John M (1975): Origin of gasoline range alkanes in the deep sea. Nature, 254(5499), 411-413, https://doi.org/10.1038/254411a0
    Details
    Publication Date: 2024-07-01
    Description: It is believed that C4 to C7 hydrocarbons in petroleum are formed by the cracking of organic matter at depths generally exceeding 1,000 m at temperatures in excess of 50 °C (Cordel, 1972; Dow, 1974; Tissot et al., 1974)). Also, none of the alkanes in the butane-heptane range are formed biologically as far as is known at present. Consequently, it is thought that they do not occur in shallow, Recent sediments. In 1962, I analysed 22 samples of Recent sediments from 7 different environments and verified that these hydrocarbons were not present at the p.p.m. level (Dunton and Hunt, 1962) although traces of a few hydrocarbons such as butane, isobutane, isopentane and n-heptane have been found (Sokolov, 1957; Veber and Turkeltaub, 1958; Erdman et al., 1958; Emery and Hoggan, 1958). No identification of individual hexanes or heptanes has been reported except when there has been clear evidence of seepage from deeper source sediments (McIver, 1973).
    Keywords: 1-3; 22-217; 22-218; 24-233A; 26-250A; 26-254; 29-280A; 29-282; 31-299; 5-34; Antarctic Ocean/CONT RISE; Antarctic Ocean/Tasman Sea; Deep Sea Drilling Project; DRILL; Drilling/drill rig; DSDP; Glomar Challenger; Gulf of Mexico/PLAIN; Indian Ocean//BASIN; Indian Ocean//FAN; Indian Ocean//RIDGE; Indian Ocean/Gulf of Aden/TRENCH; Leg1; Leg22; Leg24; Leg26; Leg29; Leg31; Leg5; North Pacific/Japan Sea; North Pacific/PLAIN
    Type: Dataset
    Format: application/zip, 2 datasets
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  • 3
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    Description and composition iron-manganese concretions from the Pacific (1964)
    PANGAEA
    In:  Supplement to: Skornyakova, Nadezhda S; Andrushchenko, Polina F; Fomina, Lidiya S (1964): Chemical composition of the Pacific ocean's iron-manganese concretions. Deep Sea Research and Oceanographic Abstracts, 11(1), 93-104, https://doi.org/10.1016/0011-7471(64)91086-1
    Details
    Publication Date: 2024-07-01
    Description: One the most interesting features of ocean sedimentation is the manganese formations on the surface of the ocean floor in some areas. These are especially widespread in the Pacific Ocean as concretions, grains, and crusts on rock fragments and bedrock outcrops. Iron-manganese concretions are the most abundant as they completely cover about 10% of the bottom of the Pacific Ocean where there are ore concentrations. The concretions occupy from 20-50% of the bottom and up to 80-90% on separate submarine rises. Such concretions are found in different types of bottom deposits, from abyssal red clays to terrigenous muds, but they occur most widely in red clays and quite often in carbonate muds. Their shape and their dimensions are very diverse and change from place to place, from station to station, varying from 0.5-20 cm. They may be oval, globular, reniform, or slaggy and often they are fiat or isometric concretions of an indefinite shape. The concretions generally have nuclei of pumice, basalt fragments, clayey and tuffaceous material, sharks' teeth, whale ossicles, and fossil sponges. Most concretions have concentric layers, combined with dendritic ramifications of iron and manganese oxides.
    Keywords: DNWB0ABD; DOWNWIND-B1; DOWNWIND-H; Dredge; DRG; DWBD15; DWBD4; DWHD47; DWHD72; GC; Gravity corer; Horizon; Mariana Basin, Pacific Ocean; NOAA and MMS Marine Minerals Geochemical Database; NOAA-MMS; Northwestern Basin, Pacific Ocean; OKEAN; Okean Grab; Pacific Ocean; Spencer F. Baird; TRAWL; Trawl net; VITYAZ; Vityaz (ex-Mars); Vityaz-25; Vityaz-29; VITYAZ3150-TR; VITYAZ3631-GR-1; VITYAZ3729-GC-1; VITYAZ3802-TR; VITYAZ3899-GR-1; VITYAZ3996-TR; VITYAZ4074-TR; VITYAZ4084-GR-1; VITYAZ4090-TR; VITYAZ4104-TR; VITYAZ4191-TR; VITYAZ4217-TR; VITYAZ4265-TR; VITYAZ4281-TR; VITYAZ4331-GR-1; VITYAZ4351-GR; VITYAZ4359-GR-1; VITYAZ4362-GR-1; VITYAZ4370-TR
    Type: Dataset
    Format: application/zip, 3 datasets
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  • 4
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    Composition of Pacific sea-floor manganese nodules (1964)
    PANGAEA
    Details
    Publication Date: 2024-07-01
    Description: This collection of data on manganese nodules on the floor of the Pacific Ocean represents all the information that was available to the authors in May, 1964. It is compiled from both published references and original data. No attempt is made here to generalize or to speculate on the origin of the manganese or associated elements further discussion of these aspects of the subject may be had by reference to the literature.
    Keywords: ALB-13; ALB-173; ALB-31; Albatross (1882-1921); Albatross1899-1900; Albatross1904-1905; ALBTR-13; ALBTR-173; ALBTR-31; ALBTR-4660; ALBTR-4662; ALBTR-4676; ALBTR-4681; ALBTR-4685; ALBTR-4701; ALBTR-4711; ALBTR-4721; CARN_Revelle_46; CARN_Revelle_78; CARN7-150; CARN7-86; CARN-Cruise7; Carnegie; CASC-5D; CASCADIA; CHA-299; CHA-302; Challenger1872; CHIN02BD; CHIN02BD-016G; CHINOOK; CHNK-16G; CHUB01BD; CHUB01BD-002G; CHUB01BD-034G; CHUB-2; CHUB-34; CHUB5; CHUBASCO; Core; CORE; DNWB0ABD; DNWB0ABD-016G; DNWB0ABD-017G; DNWB0ABD-019G; DNWB0BBD; DNWB0BBD-037G; DNWB0BBD-040G; DNWB0BBD-043G; DNWB0BBD-048G; DNWB0BBD-052G; DNWB0BBD-054G; DNWB0BBD-055G; DNWB0BBD-056G; DNWB0DBD; DNWB0DBD-147GB; DNWH0AHO-004H; DNWH0BHO-034G; DNWH0DHO-092H; DOWNWIND-B1; DOWNWIND-B2; DOWNWIND-B4; DOWNWIND-H; Dredge; Dredge, rock; DRG; DRG_R; DWBD1; DWBD2; DWBD4; DWBD5; DWBD7; DWBG147B; DWBG16; DWBG17; DWBG19; DWBG37; DWBG40; DWBG43; DWBG48; DWBG52; DWBG54; DWBG55; DWBG56; DWBG78; DWHD15; DWHD16; DWHD47; DWHD55; DWHD72; DWHG34; DWHH4; DWHH92; Eastern Basin, Pacific Ocean; Epce; GC; Grab; GRAB; Gravity corer; H.M.S. Challenger (1872); Horizon; MDPC02HO-MP-025F-1; MDPC02HO-MP-033D; MDPC03HO-MP-043A; MIDPAC; MPC-25F-1; MPC-33D; MPC-43A; NAGA; NAGA8C; NOAA and MMS Marine Minerals Geochemical Database; NOAA-MMS; North-East Pacific Ocean; Pacific Ocean; SIO-DX-1; Spencer F. Baird; Stranger; TRAWL; Trawl net; V15; V15-126; Vema; Vityaz (ex-Mars); Vityaz-29; VITYAZ4239-TR; VITYAZ4289-TR
    Type: Dataset
    Format: application/zip, 3 datasets
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  • 5
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    Manganese analysis from equatorial Pacific sediments (1975)
    PANGAEA
    Details
    Publication Date: 2024-07-01
    Description: Analysis of manganese in sediments of the equatorial Pacific.
    Keywords: BC; Box corer; Dredge, bucket; DRG_BU; FFGR; Free-fall grab; Mn-74-01-001-FFG-001; Mn-74-01-001-FFG-002; Mn-74-01-001-FFG-003; Mn-74-01-002-FFG-004; Mn-74-01-002-FFG-006; Mn-74-01-003-FFG-007; Mn-74-01-003-FFG-009; Mn-74-01-005-B2; Mn-74-01-006-FFG-016; Mn-74-01-006-FFG-017; Mn-74-01-006-FFG-018; Mn-74-01-006-FFG-019; Mn-74-01-006-FFG-020; Mn-74-01-006-FFG-021; Mn-74-01-006-FFG-022; Mn-74-01-006-FFG-023; Mn-74-01-006-FFG-025; Mn-74-01-006-FFG-026; Mn-74-01-007-FFG-028; Mn-74-01-007-FFG-029; Mn-74-01-008-FFG-032; Mn-74-01-009-FFG-036; Mn-74-01-010-FFG-037; Mn-74-01-010-FFG-038; Mn-74-01-010-FFG-039; Mn-74-01-010-FFG-042; Mn-74-01 IODE; Mn-74-02-13A-FFG-004; Mn-74-02-13B-D-001; Mn-74-02-13B-FFG-005; Mn-74-02-13B-FFG-007; Mn-74-02-13B-FFG-008; Mn-74-02-13C-D-002; Mn-74-02-13C-D-004; Mn-74-02-13C-FFG-009; Mn-74-02-13C-FFG-011; Mn-74-02-13C-FFG-012; Mn-74-02-15-FFG-021; Mn-74-02-15-FFG-025; Mn-74-02-16-FFG-030; Mn-74-02-16-FFG-037; Mn-74-02 IDOE DOMES; Moana Wave; MW7401; MW7401-01G01; MW7401-01G02; MW7401-01G03; MW7401-02G04; MW7401-02G06; MW7401-03G07; MW7401-03G09; MW7401-05B02; MW7401-06G16; MW7401-06G17; MW7401-06G18; MW7401-06G19; MW7401-06G20; MW7401-06G21; MW7401-06G22; MW7401-06G23; MW7401-06G25; MW7401-06G26; MW7401-07G28; MW7401-07G29; MW7401-08G32; MW7401-09G36; MW7401-10G37; MW7401-10G38; MW7401-10G39; MW7401-10G42; MW7402; MW7402-13D01; MW7402-13D02; MW7402-13D04; MW7402-13G04; MW7402-13G05; MW7402-13G07; MW7402-13G08; MW7402-13G09; MW7402-13G11; MW7402-13G12; MW7402-15G21; MW7402-15G25; MW7402-16G30; MW7402-16G37; MW7402D-SBT1; MW7402D-SBT2; MW7402D-SBT4; NOAA and MMS Marine Minerals Geochemical Database; NOAA-MMS; Pacific Ocean; TRAWL; Trawl net
    Type: Dataset
    Format: application/zip, 3 datasets
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  • 6
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    Analysis of clay and Mn deposits from the Pacific (1976)
    PANGAEA
    In:  Supplement to: Krishnaswami, Seth (1976): Authigenic transition elements in Pacific pelagic clays. Geochimica et Cosmochimica Acta, 40(4), 425-434, https://doi.org/10.1016/0016-7037(76)90007-7
    Details
    Publication Date: 2024-07-01
    Description: The concentrations of Sc, Ti, Fe, Mn, Co, Ni, Cu, La, Th and U have been measured in several Pacific pelagic clays having widely different accumulation rates, 0.4-9.0 mm/103 yr. The authigenic fractions and deposition rates of these elements have been estimated from the measured concentrations using various models. The results show that in Pacific clays about 90% Mn, 80% Co and Ni and 50% Cu are authigenic whereas the major fraction (〉90%) of Sc, Ti, Fe, La, Th and U are of detrital origin. Anticorrelation between the clay accumulation rates and the concentrations of Mn, Co, Ni and Cu is observed. This suggests a uniform authigenic deposition of these elements superimposed on varying amounts of detrital materials. The concentrations of Sc, Ti and Th are almost independent of sedimentation rates, indicating that their authigenic deposition is small compared to their detrital contribution. Comparison of the authigenic deposition and river input rates shows that Mn, Co and Ni are accumulating in excess of their supply by factors of 2-10, whereas the converse is true for Cu and U. Additional sources to account for the budgetary discrepancies of Mn, Co and Ni are discussed, with particular reference to in situ leaching of detrital phases transported to the oceans via rivers.
    Keywords: 2P-50; 2P-52; Argo; ARRH-TF; CARR2_9D; CARROUSEL2; DODO; DODO-009D-1; Dredge; DRG; East Pacific Ocean; NOAA and MMS Marine Minerals Geochemical Database; NOAA-MMS; Pacific Ocean; Prospector; Prospector-63; SAN_JUAN_1963; SNJ-DH2; Spencer F. Baird; TRI-02D; TRIP03AR; TRIPOD_3; ZETES; ZTES03AR; ZTES03AR-003D; ZTES-3D
    Type: Dataset
    Format: application/zip, 2 datasets
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  • 7
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    Uranium in marine basalts (1977)
    PANGAEA
    In:  Supplement to: MacDougall, J Douglas (1977): Uranium in marine basalts: Concentration, distribution and implications. Earth and Planetary Science Letters, 35(1), 65-70, https://doi.org/10.1016/0012-821X(77)90029-2
    Details
    Publication Date: 2024-07-01
    Description: The uranium content of glass from chilled margins of oceanic tholeiitic basalt flows is generally 〈0.1 ppm, even for old samples with highly altered crystalline interiors. Such low values represent the original whole rock concentrations, although subsequent to eruption low-temperature weathering has added uranium, and other elements, to the crystalline portions of these basalts. Consideration of the K/U ratios of altered samples suggests that basalt weathering may provide the major oceanic sink for these two elements.
    Keywords: 16-163; 18-177A; 2-10; 22-211; 22-213; 22-215; 23-220; 24-231; 24-236; 24-238; 25-240; 34-319; 34-320; 5-32; 5-36; 5-37; 5-39; Deep Sea Drilling Project; DRILL; Drilling/drill rig; DSDP; Glomar Challenger; Indian Ocean//BASIN; Indian Ocean//FRACTURE ZONE; Indian Ocean/Arabian Sea/HILL; Indian Ocean/Gulf of Aden/BASIN; Leg16; Leg18; Leg2; Leg22; Leg23; Leg24; Leg25; Leg34; Leg5; North Atlantic/CONT RISE; North Pacific/CONT RISE; North Pacific/HILL; North Pacific/PLAIN; North Pacific/RIDGE; South Pacific/BASIN
    Type: Dataset
    Format: application/zip, 2 datasets
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  • 8
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    Concentrations and accumulation rates of chemical elements and sediment components in sediments of central equatorial Pacific, DSDP data (1979)
    PANGAEA
    In:  Supplement to: Leinen, Margaret W; Stakes, Debra S (1979): Metal accumulation rates in the central equatorial Pacific during Cenozoic time. Geological Society of America Bulletin, 90(4), 357-375, https://doi.org/10.1130/0016-7606(1979)90%3C357:MARITC%3E2.0.CO;2
    Details
    Publication Date: 2024-07-01
    Description: Accumulation rates of Mg, Al, Si, Mn, Fe, Ni, Cu, Zn, opal, and calcium carbonate have been calculated from their concentrations in samples from equatorial Deep Sea Drilling Project sites. Maps of element accumulation rates and of Q-mode factors derived from raw data indicate that the flux of trace metals to equatorial Pacific sediments has varied markedly through time and space in response to changes in the relative and absolute influence of several depositional influences: biogenic, detrital, authigenic, and hydrothermal sedimentation. Biologically derived material dominates the sediment of the equatorial Pacific. The distributions of Cu and Zn are most influenced by surface-water biological activity, but Ni, Al, Fe, and Mn are also incorporated into biological material. All of these elements have equatorial accumulation maxima similar to those of opal and calcium carbonate at times during the past 50 m.y. Detritus distributed by trade winds and equatorial surface circulation contributes Al, non-biogenic Si, Fe, and Mg to the region. Detrital sediment is most important in areas with a small supply of biogenic debris and low bulk-accumulation rates. Al accumulation generally increases toward the north and east, indicating its continental source and distribution by the northeast trade winds. Maxima in biological productivity during middle Eocene and latest Miocene to early Pliocene time and concomitant well-developed surface circulation contributed toward temporal maxima in the accumulation rates of Cu, Zn, Ni, and Al in sediments of those ages. Authigenic material is also important only where bulk-sediment accumulation rates are low. Ni, Cu, Zn, and sometimes Mn are associated with this sediment. Fe is almost entirely of hydrothermal origin. Mn is primarily hydrothermal, but some is probably scavenged from sea water by amorphous iron hydroxide floes along with other elements concentrated in hydrothermal sediments, Ni, Cu, and Zn. During the past 50 m.y. all of these elements accumulated over the East Pacific Rise at rates nearly an order of magnitude higher than those at non-rise-crest sites. In addition, factor analysis indicates that some of this material is carried substantial distances to the west of the rise crest. Accumulation rates of Fe in basal metalliferous sediments indicate that the hydrothermal activity that supplied amorphous Fe oxides to the East Pacific Rise areas was most intense during middle Eocene and late Miocene to early Pliocene time.
    Keywords: 16-159; 16-160; 16-161; 16-162; 16-163; 5-42; 8-69; 8-70; 8-71; 8-72; 8-73; 8-74; 8-75; 9-77; 9-78; 9-79; 9-80; 9-81; 9-82; 9-83; Deep Sea Drilling Project; DRILL; Drilling/drill rig; DSDP; Glomar Challenger; Leg16; Leg5; Leg8; Leg9; North Pacific; North Pacific/BASIN; North Pacific/CONT RISE; North Pacific/HILL; North Pacific/PLAIN; North Pacific/VALLEY; South Pacific; South Pacific/BASIN; South Pacific/CONT RISE; South Pacific/VALLEY
    Type: Dataset
    Format: application/zip, 41 datasets
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  • 9
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    (Table 1, page 1376) Chemical analyses of manganese nodules and crusts from the Pacific Ocean (1961)
    PANGAEA
    In:  Supplement to: Mero, John L (1961): Sea floor manganese nodules. Unpublished report to the Daniel C. Jackling Award Fellowship Committee; American Institute of Mining, Metallurgical, and Petroleum Engineers (AIME), https://www.ngdc.noaa.gov/mgg/geology/data/1599/15995009/15995009.pdf
    Details
    Publication Date: 2024-07-01
    Description: A compilation of chemical analyses of Pacific Ocean nodules using an x-ray fluorescence technique. The equipment used was a General Electric XRD-5 with a tungsten tube. Lithium fluoride was used as the diffraction element in assaying for all elements above calcium in the atomic table and EDDT was used in conjunction with a helium path for all elements with an atomic number less than calcium. Flow counters were used in conjunction with a pulse height analyzer to eliminate x-ray lines of different but integral orders in gathering count data. The stability of the equipment was found to be excellent by the author. The equipment was calibrated by the use of standard ores made from pure oxide forms of the elements in the nodules and carefully mixed in proportion to the amounts of these elements generally found in the manganese nodules. Chemically analyzed standards of the nodules themselves were also used. As a final check, a known amount of the element in question was added to selected samples of the nodules and careful counts were taken on these samples before and after the addition of the extra amount of the element. The method involved the determination and subsequent use of absorption and activation factors for the lines of the various elements. All the absorption and activation factors were carefully determined using the standard ores. The chemically analyzed samples of the nodules by these methods yielded an accuracy to at least three significant figures.
    Keywords: 248; Acapulco Trench, Pacific ocean; ALB-13; ALB-173; ALB-2; ALB-31; Albatross (1882-1921); Albatross1899-1900; Albatross1904-1905; Albatross IV (1963); ALBTR-13; ALBTR-173; ALBTR-2; ALBTR-31; ALBTR-4622; ALBTR-4656; ALBTR-4658; ALBTR-4660; ALBTR-4662; ALBTR-4676; ALBTR-4681; ALBTR-4685; ALBTR-4701; ALBTR-4711; ALBTR-4721; Aluminium; Argo; B1 VS-78; Barium; Calcium; Calculated from weight loss after ignition at 450 °C; CAP-50BG-1; CAPB01BD-050BG-01; CAPRICORN-B; CARN_Revelle_46; CARN_Revelle_78; CARN7-150; CARN7-86; CARN-Cruise7; Carnegie; CASC-5D; CASCADIA; CHA-248; CHA-252; CHA-276; CHA-285; CHA-289; CHA-299; CHA-302; Challenger1872; CHUB01BD; CHUB01BD-001G; CHUB01BD-002G; CHUB01BD-003G; CHUB01BD-009G; CHUB01BD-017G; CHUB01BD-019G; CHUB01BD-039G; CHUB-1; CHUB-11G; CHUB-17; CHUB-19; CHUB-2; CHUB-3; CHUB-39; CHUB5; CHUB-7G; CHUB-9; CHUBASCO; Cobalt; Copper; Core; CORE; core_48; CRU9121; CUSP1954; CUSP8P; DEPTH, sediment/rock; Description; DNWB0ABD; DNWB0ABD-017G; DNWB0ABD-019G; DNWB0BBD; DNWB0BBD-037G; DNWB0BBD-040G; DNWB0BBD-043G; DNWB0BBD-048G; DNWB0BBD-054G; DNWB0DBD; DNWB0DBD-147GB; DNWH0AHO-004H; DOWNWIND-B1; DOWNWIND-B2; DOWNWIND-B4; DOWNWIND-H; Dredge; Dredge, rock; DRG; DRG_R; DWBD1; DWBD2; DWBD4; DWBD7; DWBG147B; DWBG17; DWBG19; DWBG37; DWBG40; DWBG43; DWBG48; DWBG54; DWBG78; DWHD15; DWHD16; DWHD47; DWHD55; DWHD72; DWHH4; Epce; Event label; GC; Grab; GRAB; Gravity corer; H.M.S. Challenger (1872); Henderson Seamount, Pacific Ocean; Horizon; Identification; Iron; Lead; Loss on ignition; Manganese; MDPC01HO-005-02; MDPC02HO-032; MDPC02HO-MP-025F-2; MDPC02HO-MP-026A-3; MDPC02HO-MP-033K; MDPC02HO-MP-037A; MDPC03HO-MP-043D; MIDPAC; Molybdenum; Monegasque Trawl; MONS01AR-MONS08AR; MONS08AR-139D; MONSOON; MPC-25F-2; MPC-26A-3; MPC-32; MPC-33K; MPC-37A; MPC-43D; MPC-5-2; MSN-07G; MSN-10G; MSN-11G; MSN-139D; MSN-17G; MSN-18G; MSN G; MSNK; MSN Q; MSN S; MTRW; NEL-HEND; Nickel; NOAA and MMS Marine Minerals Geochemical Database; NOAA-MMS; NODC-0418; North-East Pacific Ocean; Northern_Holiday; North Pacific Ocean; Northwest Pacific Ocean; North-West Pacific Ocean; NTHL02HO-010PH; NTHL-10; Pacific Ocean; Page(s); PAS-19121; Phosphorus; Potassium; Sample code/label; SDSE_073; Sediment type; Silicon; Size; SOB; SOB-005D; SOB-010D; SOB-013D; SOB-020D; SOB-022D; SOB-025D; SOB-027D; SOBO03BD-005D; SOBO03BD-010D; SOBO03BD-013D; SOBO04BD-020D; SOBO04BD-022D; SOBO04BD-025D; SOBO04BD-027D; Southern Borderland; Specific gravity; Spencer F. Baird; Strontium; SwedishDeepSeaExpedition; Titanium; TRANS_14C; TRANS_14D; TRAWL; Trawl net; UNK_BH2; UNK_MS; VERMILION_SEA; Vermilion Sea, Pacific Ocean; Vityaz (ex-Mars); Vityaz-29; VITYAZ4191-TR; VITYAZ4199-TR; VITYAZ4217-TR; VITYAZ4221-TR; VS BII-35; VSS35D; VSS78D; Water in rock; WIG-6; WIGWAM; Wired profile sonde; WP; X-ray fluorescence (XRF); Zinc
    Type: Dataset
    Format: text/tab-separated-values, 2243 data points
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  • 10
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    Annotated record of the detailed examination of Mn deposits from the QUEBRADA (1969) and SIQUEIROS (1974) expeditions around the East Pacific Rise (1977)
    PANGAEA
    In:  Supplement to: Batiza, Rodey; Rosendahl, Bruce R; Fisher, Robert L (1977): Evolution of oceanic crust: 3. Petrology and chemistry of basalts from the East Pacific Rise and the Siqueiros Transform Fault. Journal of Geophysical Research, 82(2), 265-276, https://doi.org/10.1029/JB082i002p00265
    Details
    Publication Date: 2024-07-01
    Description: Basalt samples obtained from the Siqueiros transform fault/fracture zone and the adjacent East Pacific Rise are mostly very fresh oceanic tholeiite and fractionated oceanic tholeiite with Fe+3/ Fe+2 ? 0.25; however, alkali basalts occur in the area as well. The rocks of the tholeiitic suite are ol + pl phyric and ol + pl + cpx phyric basalts, while the alkali basalts are ol and ol + pl phyric. Microprobe analyses of the tholeiitic suite phenocrysts indicate that they are Fo68-Fo86, An58-An75, and augite (Ca34Mg50Fe16). The range of olivine and plagioclase compositions represents the chemical variation of the phenocryst compositions with fractionation. The phenocyrsts in the alkali basalts are Fo81 and An69. The suite of tholeiites comprises a fractionation series characterized by relative enrichment of Fe, Ti, Mn, V, Na, K, and P and depletion of Ca, Al, Mg, Ni, and Cr. The fractionated tholeiites occur on the median ridge (which is a sliver of normal oceanic crust) of the double Siqueiros transform fault, on the western Siqueiros fracture zone, and on the adjoining East Pacific Rise, while the two transform fault troughs contain mostly unfractionated or only slightly fractionated tholeiite. We suggest that the fractionated tholeiites are produced by fractional crystallization of more 'primitive' tholeiitic liquid in a crustal magma chamber below the crest of the East Pacific Rise. This magma chamber may be disrupted by the transform fault troughs, thus explaining the paucity of fractionated tholeiites in the troughs. The alkali basalts are found only on the flanks of a topographic high near the intersection of the northern transform trough with the East Pacific Rise.
    Keywords: Deposit type; DEPTH, sediment/rock; Description; Dredge; DRG; Event label; Identification; NOAA and MMS Marine Minerals Geochemical Database; NOAA-MMS; Pacific Ocean; Position; QBR-17D; QBR-19D; Quantity of deposit; QUEBRADA; SIQR-2D; SIQR-3D; SIQR-4D; SIQUEIROS; Substrate type; Thomas Washington; Uniform resource locator/link to image; Visual description
    Type: Dataset
    Format: text/tab-separated-values, 31 data points
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