Chemistry of altered basaltic glass shards and zeolites of volcaniclastic sediments from ODP Hole 157-953C


Autoria(s): Utzmann, Achim; Hansteen, Thor H; Schmincke, Hans-Ulrich
Cobertura

LATITUDE: 28.650200 * LONGITUDE: -15.144500 * DATE/TIME START: 1994-08-24T07:25:00 * DATE/TIME END: 1994-09-04T09:40:00

Data(s)

19/10/2002

Resumo

Trace element concentrations of altered basaltic glass shards (layer silicates) and zeolites in volcaniclastic sediments drilled in the volcanic apron northeast of Gran Canaria during Ocean Drilling Program (ODP) leg 157 document variable element mobilities during low-temperature alteration processes in a marine environment. Clay minerals (saponite, montmorillonite, smectite) replacing volcanic glass particles are enriched in transition metals and rare earth elements (REE). The degree of retention of REE within the alteration products of the basaltic glass is correlated with the field strength of the cations. The high field-strength elements are preferentially retained or enriched in the alteration products by sorption through clay minerals. Most trace elements are enriched in a boundary layer close to the interface mineral-altered glass. This boundary layer has a key function for the physico-chemical conditions of the subsequent alteration process by providing a large reactive surface and by lowering the fluid permeability. The release of most elements is buffered by incorporation into secondary precipitates (sodium-rich zeolites, phillipsite, Fe- and Mn-oxides) as shown by calculated distribution coefficients between altered glasses and authigenic minerals. Chemical fluxes change from an open to a closed system behavior during prograde low-temperature alteration of volcaniclastic sediments with no significant trace metal flux from the sediment to the water column.

Formato

application/zip, 4 datasets

Identificador

https://doi.pangaea.de/10.1594/PANGAEA.666903

doi:10.1594/PANGAEA.666903

Idioma(s)

en

Publicador

PANGAEA

Direitos

CC-BY: Creative Commons Attribution 3.0 Unported

Access constraints: unrestricted

Fonte

Supplement to: Utzmann, Achim; Hansteen, Thor H; Schmincke, Hans-Ulrich (2002): Trace element mobility during sub-seafloor alteration of basaltic glass from Ocean Drilling Program site 953 (off Gran Canaria). International Journal of Earth Sciences, 91(4), 661-679, doi:10.1007/s00531-001-0247-6

Palavras-Chave #157-953C; Al2O3; Al2O3 std dev; Aluminium oxide; Aluminium oxide, standard deviation; Analcite; Anl; Ba; Ba max; Ba min; Barium; Barium, maximum; Barium, minimum; Barium, standard deviation; Ba std dev; Calcium oxide; Calcium oxide, standard deviation; Calculated; calculated average/mean values; Canarias Sea; CaO; CaO std dev; Ce; Ce max; Ce min; Cerium; Cerium, maximum; Cerium, minimum; Cerium, standard deviation; Ce std dev; Chl; Chlorite; Copper; Copper, maximum; Copper, minimum; Copper, standard deviation; Cu; Cu max; Cu min; Cu std dev; Depth; DEPTH, sediment/rock; DRILL; Drilling/drill rig; Dy; Dy max; Dy min; Dysprosium; Dysprosium, maximum; Dysprosium, minimum; Dysprosium, standard deviation; Dy std dev; Electron microprobe; Fe2O3; Fe2O3 std dev; from difference of the total of all major oxides to 100%; Ga; Gadolinium; Gadolinium, maximum; Gadolinium, minimum; Gadolinium, standard deviation; Gallium; Gallium, maximum; Gallium, minimum; Gallium, standard deviation; Ga max; Ga min; Ga std dev; Gd; Gd max; Gd min; Gd std dev; Gme; Gmelinite; Gobbinsite; H2O; Heulandite; Hul; Iron oxide, Fe2O3; Iron oxide, Fe2O3, standard deviation; Joides Resolution; K2O; K2O std dev; La; Label; La max; La min; Lanthanum; Lanthanum, maximum; Lanthanum, minimum; Lanthanum, standard deviation; La std dev; Leg157; Magnesium oxide; Magnesium oxide, standard deviation; Manganese; Manganese, maximum; Manganese, minimum; Manganese dioxide, standard deviation; Manganese oxide; Manganese oxide, standard deviation; Merlinoite; MgO; MgO std dev; Minerals; Mn; Mn max; Mn min; MnO; MnO2 std dev; MnO std dev; Mnt; Montmorillonite; Na2O; Na2O std dev; Natrolite; Nb; Nb max; Nb min; Nb std dev; Nd; Nd max; Nd min; Nd std dev; Neodymium; Neodymium, maximum; Neodymium, minimum; Neodymium, standard deviation; Ni; Nickel; Nickel, maximum; Nickel, minimum; Nickel, standard deviation; Ni max; Ni min; Niobium; Niobium, maximum; Niobium, minimum; Niobium, standard deviation; Ni std dev; NOBS; Ntr; Number of observations; Ocean Drilling Program; ODP; ODP sample designation; P2O5; P2O5 std dev; Paulingite; Phillipsite; Phosphorus oxide; Phosphorus oxide, standard deviation; Php; Potassium oxide; Potassium oxide, standard deviation; Pr; Praseodymium; Praseodymium, maximum; Praseodymium, minimum; Praseodymium, standard deviation; Pr max; Pr min; Pr std dev; Rb; Rb max; Rb min; Rb std dev; Rubidium; Rubidium, maximum; Rubidium, minimumimum; Rubidium, standard deviation; Samarium; Samarium, maximum; Samarium, minimumimum; Samarium, standard deviation; Sample code/label; Sap; Saponite; Ser; Sericite; Silicon dioxide; Silicon dioxide, standard deviation; SiO2; SiO2 std dev; Sm; Sme; Smectite; Sm max; Sm min; Sm std dev; Sn; Sn max; Sn min; Sn std dev; Sodium oxide; Sodium oxide, standard deviation; Sr; Sr max; Sr min; Sr std dev; Strontium; Strontium, maximum; Strontium, minimumimum; Strontium, standard deviation; Synchrotron X-ray fluorescence SYXRF; Ti; Ti max; Ti min; Tin; Tin, maximum; Tin, minimum; Tin, standard deviation; TiO2; TiO2 std dev; Ti std dev; Titanium; Titanium, maximum; Titanium, minimum; Titanium, standard deviation; Titanium oxide; Titanium oxide, standard deviation; V; Vanadium; Vanadium, maximum; Vanadium, minimum; Vanadium, standard deviation; V max; V min; V std dev; Water in rock; X-ray diffraction (XRD); Y; Y max; Y min; Y std dev; Yttrium; Yttrium, maximum; Yttrium, minimum; Yttrium, standard deviation; Zinc; Zinc, maximum; Zinc, minimum; Zinc, standard deviation; Zirconium; Zirconium, maximum; Zirconium, minimum; Zirconium, standard deviation; Zn; Zn max; Zn min; Zn std dev; Zr; Zr max; Zr min; Zr std dev
Tipo

Dataset