B, Li, and Associated Trace Element Chemistry of Alteration Minerals, Holes 597B and 597C

Berndt, M.; Seyfried, W.E.

doi:10.2973/dsdp.proc.92.130.1986

Cited by 5 publications

(3 citation statements)

References 19 publications

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“…Li is considered to be a mobile element during reaction of seawater with basalt at temperatures greater than 70°C (Seyfried et al, 1984); it is leached from basalt altered at moderate to high temperature. Evidence from dredged and drilled basalts from shallow in the crust suggests that Li is taken up from seawater into secondary alteration products under low temperature (0°-50°C) seafloor weathering conditions (Berndt and Seyfried, 1986;Ryan and Langmuir, 1987). Li concentrations in the borehole fluids show an excellent correlation with Mg (Fig 21).…”

Section: Water/rock Mass Ratiosmentioning

confidence: 95%

Borehole Fluid Chemistry in Hole 504B, Leg 137: Formation Water or In-Situ Reaction?

Magenheim¹,

Spivack²,

Alt³

et al. 1995

Proceedings of the Ocean Drilling Program

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Circulation of seawater through basaltic basement for several million years after crustal emplacement has been inferred from studies of surface heat flow, and may play a significant role in the exchange of elements between the oceanic crust and seawater. Without direct observation of the fluid chemistry, interpretations regarding the extent and timing of this exchange must be based on the integrated signal of alteration found in sampled basalts. Much interest has thus been expressed in obtaining and analyzing fluids directly from basaltic formations.It has been proposed that open oceanic boreholes can be used as oceanic groundwater wells to obtain fluids that are circulating within the formation. Water samples were collected from the open borehole in Hole 504B prior to drilling operations on Leg 137, with the original intention of collecting formation fluids from the surrounding basaltic rocks. Past results have yielded ambiguous conclusions as to the origin of the fluids recovered-specifically, whether or not the fluids were true formation fluids or merely the result of reaction of seawater in the borehole environment.The chemistry of eight borehole fluid samples collected during Leg 137 is discussed in this paper. Large changes in major, minor, and isotopic compositions relative to unaltered seawater were observed in the borehole fluids. Compositional changes increased with depth in the borehole. The samples exhibit the effect of simple mixing of seawater, throughout the borehole, with a single reacted fluid component. Analysis and interpretation of the results from Leg 137 in light of past results suggest that the chemical signals observed may originate predominantly from reaction with basaltic rubble residing at the bottom of the hole during the interim between drilling legs. Although this endeavor apparently did not recover formation waters, information on the nature of reaction between seawater and basalt at the prevalent temperatures in Hole 504B (>160°C) has been gained that can be related to reconstruction of the alteration history of the oceanic crust. Isotopic analyses allow calculation of element-specific water/rock mass ratios (Li and Sr) and are related to the extent of chemical exchange between the borehole fluids and basalt.

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Section: Water/rock Mass Ratiosmentioning

confidence: 95%

Borehole Fluid Chemistry in Hole 504B, Leg 137: Formation Water or In-Situ Reaction?

Magenheim¹,

Spivack²,

Alt³

et al. 1995

Proceedings of the Ocean Drilling Program

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“…Previous workers have suggested that uptake of Li in basalt during seafloor alteration is tied to the stabilization of secondary minerals such as smectite (saponite), celadonite, and phillipsite, with Li residing in octahedral sites in suitable phases (Chan et al, 2002;Vigier et al, 2008). Major and trace element analyses of these minerals in various modern sedimentary and altered basalt settings indicate that the LILE tend to be incorporated into interlayer sites in illite/celadonite (perhaps also K-rich phillipsite), whereas Li is more concentrated in Mg-rich phases such as saponite and other K-poor smectite phases (see Desprairies et al, 1984;Berndt and Seyfried, 1986;Heling et al, 1992;Porter et al, 2000). Varying relative modal abundances of these phases, among a suite of samples from the same site, would result in a general lack of correlation between concentrations of Li and LILE in the same rocks, whereas the LILE would tend to show co-enrichments because of their general similarity in geochemical behavior (see Fig.…”

Section: Fluid-mediated Addition Of LI To Metamafic Rocksmentioning

confidence: 97%

Lithium and its isotopes as tracers of subduction zone fluids and metasomatic processes: Evidence from the Catalina Schist, California, USA

Penniston‐Dorland

Bebout

Strandmann

et al. 2012

Geochimica et Cosmochimica Acta

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“…Bulk compositional trends documented in the preceding section, however, do indicate qualitative water/rock conditions. At lowtemperatures, mobile elements such as Rb and K are removed from seawater and incorporated into secondary phases [Richardson et al, 1980;Staudigel et al, 1981;Seyfried et al, 1984;Berndt and Seyfried, 1986]. Water/rock ratios may be calculated using bulk rock compositions if it is assumed that the difference between fresh and altered rock values reflects the amount of seawater seen by the rocks.…”

Section: Fluid Flow and Water/rock Ratiosmentioning

confidence: 99%

Patterns and processes of alteration in the lavas and dykes of the Troodos Ophiolite, Cyprus

Gillis¹,

Robinson²

1990

J. Geophys. Res.

114

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Alteration panenu in the lavas and dykes of the Troodos Ophiolite, Cypnu, record a compte~ ~st~ of axial hydrochennal alteration, crustal aging, and.subsequent uplift ~d c;rnptac~ent of ~e ophiolite. ~1eld mappina shows that distribution of five alteration zooes, each ~ith duunct rruneralog•cal, gcochermcal, and hydroloaic characteristics, is influenced by igneous stratigraphy, st~cture~ a~d the nature a.nd thickness of the overlying aedimenu. Paragenetic aequences of ICCOlldary ~erals indicate .that alteration conditions changed proareasively as the crust cooled and moved o(f~Uls. Along spreading axes, low temperatures ~SO"C) were mainuined by the rapid flow of seawater m and out of the lavas, and .only minimal alteration took place. In contrast, lower water/rock ratios and hlgh~r te.mperarures (>200°C) m the dykes promoted extensive seawater·rock interaction. Althou~~ the sharp rue .m ~perarure between the two reJ.imes generally coincides with the lava-dyke transJUoo, late· stage mtrus1ons or hydrothermal upwellina zooes locally cause high·temperarure alteration to extend upward .into the lavas. As a segment of crust moved off·axis, temperatures remained tow in the lavas and proaress1vety decreased, ~rom. >250" 10 <80"C in the dykes. High permeability in the uppermost lavas led to the downward rruarauon of an oxidati~e alteration front whose thickness and spatial distribution was dependent upon the. rate and nature of sedimentation and, thus, the original seafloor morphology. Although field relations sho.w that alteration has a consistent vertical pattern in Troodos, the alteration zooes are not laterally oonunuous, and the stratigraphic depth of their boundaries varies considerably. IN1ROOUC110NEarly studies of the massive sulfide deposits [Constantinou and Govett, 1973) and alteration patterns within the Troodos ophiolite [Gass and Smewing, 1973) contributed greatly to the development of models for oceanic hydrothermal systems [SpooMr et al., 1977; C haprno.n and SpooMr, 1977] and subseafloor metamorphism [Coleman, 1977]. Subsequent discovery of high-temperature vents at mid-ocean ridges [e.g., Edmond et al., 1979), seamounts [MalaJwff et al., 1982], and back arc basins [Horbie et al., 1986] showed that hydrothermal circulation is a fundamental process in many oceanic environments.Mineralogical and chemical zonations within the Troodos massive sulfide ore deposits indicate that they formed from hydrothermal flu1ds whose compositions were remarkably similar to those venting on the seafloor today [Adamides, 1987;Herzig and Friedrich , 1987;Richards et al., 1989). Fluid compositions in Troodos were buffered by epidosites at conditions similar to those inferred for the root-zones of active systems at mid-ocean ridges [Bowers and Taylor, 1985;Richardson et al., 1987;Schiffman et al., 1987;Schiffman and Smith, 1988;Seyfried et al., 1988;Von Damm, 1988] . Because of these and other similarities, the upflow zones of the Troodos hydrothermal systems are thought to be ancient analogues of modem active systems [Oud...

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B, Li, and Associated Trace Element Chemistry of Alteration Minerals, Holes 597B and 597C

Cited by 5 publications

References 19 publications

Borehole Fluid Chemistry in Hole 504B, Leg 137: Formation Water or In-Situ Reaction?

Borehole Fluid Chemistry in Hole 504B, Leg 137: Formation Water or In-Situ Reaction?

Lithium and its isotopes as tracers of subduction zone fluids and metasomatic processes: Evidence from the Catalina Schist, California, USA

Patterns and processes of alteration in the lavas and dykes of the Troodos Ophiolite, Cyprus

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