Stratigraphic significance of siliceous microfossils collected during Nautiperc dives (Off Peru, 5°-6° S)

The geological evolution of the northern Peru convergent margin can be traced using samples collected during deep-sea dives of the submersible Nautile. In the Paita area (5 degrees-6 degrees S), the sedimentary sequence was intensively sampled along the main scarp of the middle slope area. It consists of Upper Miocene (7-9 Ma) to Pleistocene siltstone, sandstone and rare dolostone. The age distribution of these samples is the basis for a new geologic interpretation of the multichannel seismic line CDP3. Siliceous microfossils (both diatoms and radiolarians) show influence of both cold and temperate waters (local species mixed with upwelling ones). Diatom assemblages studied from the NP1-13 and NP1-15 dives bear a strong resemblance to assemblages from the Pisco Formation of southern Peru. Micropaleontological data from siliceous microfossils, provide evidence for two main unconformities, one is at the base of the Quaternary sequence and the other corresponds to a hiatus of 1 Myr, separating the Upper Miocene (7-8 Ma) sediments from uppermost Miocene (5-6 Ma) sediments. During the past 400 kyr, a wide rollover fold developed in the middle slope area associated with a major seaward dipping detachment fault. A catastrophic debris avalanche occurred as the result of an oversteepening of the landward flank of the rollover fold. The gravity failure of the slope, recognized by SeaBEAM and hydrosweep mapping, displaced enough material to produce a destructive tsunami which occurred 13.8 +/- 2.7 kyr ago.

Sr, C and O isotope systematics in the Pucara Basin, central Peru - Comparison between Mississippi Valley-type deposits and barren areas

A combined Sr, O and C isotope study has been carried out in the Pucara basin, central Peru, to compare local isotopic trends of the San Vicente and Shalipayco Zn-Pb Mississippi Valley-type (MVT) deposits with regional geochemical patterns of the sedimentary host basin. Gypsum, limestone and regional replacement dolomite yield Sr-87/Sr-86 ratios that fall within or slightly below the published range of seawater Sr-87/Sr-86 values for the Lower Jurassic and the Upper Triassic. Our data indicate that the Sr isotopic composition of seawater between the Hettangian and the Toarcian may extend to lower Sr-87/Sr-86 ratios than previously published values. An Sr-87-enrichment is noted in (1) carbonate rocks from the lowermost part of the Pucara basin, and (2) different carbonate generations at the MVT deposits. This indicates that host rocks at MVT deposits and in the lowermost part of the carbonate sequence interacted with Sr-87-enriched fluids. The fluids acquired their radiogenic nature by interaction with lithologies underlying the carbonate rocks of the Pucara basin. The San Ramon granite, similar Permo-Triassic intrusions and their elastic derivatives in the Mitu Group are likely sources of radiogenic Sr-87. The Brazilian shield and its erosion products are an additional potential source of radiogenic Sr-87. Volcanic rocks of the Mitu Group are not a significant source for radiogenic Sr-87; however, molasse-type sedimentary rocks and volcaniclastic rocks cannot be ruled out as a possible source of radiogenic Sr-87. The marked enrichment in Sr-87 of carbonates toward the lower part of the Pucara Group is accompanied by only a slight decrease in delta(18)O values and essentially no change in delta(13)C values, whereas replacement dolomite and sparry carbonates at the MVT deposits display a coherent trend of progressive Sr-87-enrichment, and O-18- and C-13-depletion. The depletion in O-18 in carbonates from the MVT deposits are likely related to a temperature increase, possibly coupled with a O-18-enrichment of the ore-forming fluids. Progressively lower delta(13)C values throughout the paragenetic sequence at the MVT deposits are interpreted as a gradually more important contribution from organically derived carbon. Quantitative calculations show that a single fluid-rock interaction model satisfactorily reproduces the marked Sr-87-enrichment and the slight decrease in delta(18)O values in carbonate rocks from the lower part of the Pucara Group. By contrast, the isotopic covariation trends of the MVT deposits are better reproduced by a model combining fluid mixing and fluid-rock interaction. The modelled ore-bearing fluids have a range of compositions between a hot, saline, radiogenic brine that had interacted with lithologies underlying the Pucara sequence and cooler, dilute brines possibly representing local fluids within the Pucara sequence. The composition of the local fluids varies according to the nature of the lithologies present in the neighborhood of the different MVT deposits. The proportion of the radiogenic fluid in the modelled fluid mixtures interacting with the carbonate host rocks at the MVT deposits decreases as one moves up in the stratigraphic sequence of the Pucara Group.

Carbon and oxygen isotope study of hydrothermal carbonates in the zinc-lead deposits of the San Vicente district, central Peru: A quantitative modeling on mixing processes and CO2 degassing

Carbon and oxygen isotope studies of the host and gangue carbonates of Mississippi Valley-type zinc-lead deposits in the San Vicente District hosted in the Upper Triassic to Lower Jurassic dolostones of the Pucara basin (central Peru) were used to constrain models of the ore formation. A mixing model between an incoming hot saline slightly acidic radiogenic (Pb, Sr) fluid and the native formation water explains the overall isotopic variation (delta(13)C = - 11.5 to + 2.5 parts per thousand relative to PDB and delta(18)O = + 18.0 to + 24.3 parts per thousand relative to SMOW) of the carbonate generations. The dolomites formed during the main ore stage show a narrower range (delta(13)C = - 0.1 to + 1.7 parts per thousand and delta(18)O = + 18.7 to + 23.4 parts per thousand) which is explained by exchange between the mineralizing fluids and the host carbonates combined with changes in temperature and pressure. This model of fluid-rock interaction explains the pervasive alteration of the host dolomite I and precipitation of sphalerite I. The open-space filling hydrothermal white sparry dolomite and the coexisting sphalerite II formed by prolonged fluid-host dolomite interaction and limited CO2 degassing. Late void-filling dolomite III (or calcite) and the associated sphalerite III formed as the consequence of CO2 degassing and concomitant pH increase of a slightly acidic ore fluid. Widespread brecciation is associated to CO2 outgassing. Consequently, pressure variability plays a major role in the ore precipitation during the late hydrothermal events in San Vicente. The presence of native sulfur associated with extremely carbon-light calcites replacing evaporitic sulfates (e.g., delta(13)C = - 11.5 parts per thousand), altered native organic matter and heavier hydrothermal bitumen (from - 27.0 to - 23.0 parts per thousand delta(13)C) points to thermochemical reduction of sulfate and/or thiosulfate. The delta(13)C- and delta(18)O-values of the altered host dolostone and hydrothermal carbonates, and the carbon isotope composition of the associated organic matter show a strong regional homogeneity. These results coupled with the strong mineralogical and petrographic similarities of the different MVT occurrences perhaps reflects the fact that the mineralizing processes were similar in the whole San Vicente belt, suggesting the existence of a common regional mineralizing hydrothermal system with interconnected plumbing.

An evaluation of the inorganic and organic geochemistry of the San Vicente Mississippi Valley-type zinc-lead district, central Peru: Implications for ore fluid composition, mixing processes, and sulfate reduction

Mississippi Tialley-type zinc-lead deposits and ore occurrences in the San Vicente belt are hosted in dolostones of the eastern Upper Triassic to Lower Jurassic Pucara basin, central Peru. Combined inorganic and organic geochemical data from 22 sites, including the main San Vicente deposit, minor ore occurrences, and barren localities, provide better understanding of fluid pathways and composition, ore precipitation mechanisms, Eh-pH changes during mineralization, and relationships between organic matter and ore formation. Ore-stage dark replacement dolomite and white sparry dolomite are Fe and rare earth element (REE) depleted, and Mn enriched, compared to the host dolomite. In the main deposit, they display significant negative Ce and probably Eu anomalies. Mixing of an incoming hot, slightly oxidizing, acidic brine (H2CO3 being the dominant dissolved carbon species), probably poor in REE and Fe, with local intraformational, alkaline, reducing waters explains the overall carbon and oxygen isotope variation and the distributions of REE and other trace elements in the different hydrothermal carbonate generations. The incoming ore fluid flowed through major aquifers, probably basal basin detrital units, with limited interaction with the carbonate host rocks. The hydrothermal carbonates show a strong regional chemical homogeneity, indicating access of the ore fluids by interconnected channelways near the ore occurrences. Negative Ce anomalies in the main deposit, that are absent at the district scale, indicate local ore-fluid chemical differences. Oxidation of both migrated and indigenous hydrocarbons by the incoming fluid provided the local reducing conditions necessary for sulfate reduction to H2S, pyrobitumen precipitation, and reduction of Eu3+ to Eu2+. Fe-Mn covariations, combined with the REE contents of the hydrothermal carbonates, are consistent with the mineralizing system shifting from reducing/rock-dominated to oxidizing/fluid-dominated conditions following ore deposition. Sulfate and sulfide sulfur isotopes support sulfide origin from evaporite-derived sulfate by thermochemical organic reduction; further evidence includes the presence of C-13-depleted calcite cements (similar to-12 parts per thousand delta(13)C) as sulfate pseudomorphs, elemental sulfur, altered organic matter in the host dolomite, and isotopically heavier, late, solid bitumen. Significant alteration of the indigenous and extrinsic hydrocarbons, with absent bacterial membrane biomarkers (hopanes) is observed. The light delta(34)S of sulfides from small mines and occurrences compared to the main deposit reflect a local contribution of isotopically light sulfur, evidence of local differences in the ore-fluid chemistry.

Mineral zoning and geochemistry of epithermal polymetallic Zn-Pb-Ag-Cu-Bi mineralization at Cerro de Pasco, Peru

The large Cerro de Pasco Cordilleran base metal deposit in central Peru is located on the eastern margin of a middle Miocene diatreme-dome complex and comprises two mineralization stages. The first stage consists of a large pyrite-quartz body replacing Lower Mesozoic Pucara carbonate rocks and, to a lesser extent, diatreme breccia. This body is composed of pyrite with pyrrhotite inclusions, quartz, and black and red chalcedony (containing hypogene hematite). At the contact with the pyrite-quartz body, the diatreme breccia is altered to pyrite-quartz-sericite-pyrite. This body was, in part, replaced by pipelike pyrrhotite bodies zoned outward to carbonate-replacement Zn-Pb ores hearing Fe-rich sphalerite (up to 24 mol % Fes). The second mineralization stage is partly superimposed on the first and consists of zoned east-west-trending Cu-Ag-(Au-Zn-Pb) enargite-pyrite veins hosted in the diatreme breccia in the western part of the deposit and well-zoned Zn-Pb-(Bi-Ag-Cu) carbonate-replacement orebodies; in both cases, sphalerite is Fe poor and the inner parts of the orebodies show typically advanced argillic alteration assemblages, including aluminum phosphate Sulfate (APS) minerals. The zoned enargite-pyrite veins display mineral zoning, from a core of enargite-pyrite +/- alunite with traces of Au, through an intermediate zone of tennantite, chalcopyrite, and Bi minerals to a poorly developed Outer zone hearing sphalerite-galena +/- kaolinite. The carbonate-hosted replacement ores are controlled along N 35 degrees E, N 90 degrees E, N 120 degrees E, and N 170 degrees E faults. They form well-zoned upward-flaring pipelike orebodies with a core of famatinite-pyrite and alunite, an intermediate zone with tetrahedrite-pyrite, chalcopyrite, matildite, cuprobismutite, emplectite, and other Bi minerals accompanied by APS minerals, kaolinite, and dickite, and an outer zone composed of Fe-poor sphalerite (in the range of 0.05-3.5 mol % Fes) and galena. The outermost zone consists of hematite, magnetite, and Fe-Mn-Zn-Ca-Mg carbonates. Most of the second-stage carbonate-replacement orebodies plunge between 25 degrees and 60 degrees to the west, suggesting that the hydrothermal fluids ascended from deeper levels and that no lateral feeding from the veins to the carbonate-replacement orebodies took place. In the Venencocha and Santa Rosa areas, located 2.5 km northwest of the Cerro de Pasco open pit and in the southern part of the deposit, respectively, advanced argillic altered dacitic domes and oxidized veins with advanced argillic alteration halos occur. The latter veins are possibly the oxidized equivalent of the second-stage enargite-pyrite veins located in the western part of the deposit. The alteration assemblage quartz-muscovite-pyrite associated with the pyrite-quartz body suggests that the first stage precipitated at slightly, acidic fin. The sulfide mineral assemblages define an evolutionary path close to the pyrite-pyrrhotite boundary and are characteristic of low-sulfidation states; they suggest that the oxidizing slightly acidic hydrothermal fluid was buffered by phyllite, shale, and carbonate host rock. However, the presence in the pyrite-quartz body of hematite within quartz suggests that, locally, the fluids were less buffered by the host rock. The mineral assemblages of the second mineralization stage are characteristic of high- to intermediate-sulfidation states. High-sulfidation states and oxidizing conditions were achieved and maintained in the cores of the second-stage orebodies, even in those replacing carbonate rocks. The observation that, in places, second-stage mineral assemblages are found in the inner and outer zones is explained in terms of the hydrothermal fluid advancing and waning. Microthermometric data from fluid inclusions in quartz indicate that the different ores of the first mineralization stage formed at similar temperatures and moderate salinities (200 degrees-275 degrees C and 0.2-6.8 wt % NaCl equiv in the pyrite-quartz body; 192 degrees-250 degrees C and 1.1-4.3 wt % NaCl equiv in the pyrrhotite bodies; and 183 degrees-212 degrees C and 3.2-4.0 wt % NaCl equiv in the Zn-Pb ores). These values are similar to those obtained for fluid inclusions in quartz and sphalerite from the second-stage ores (187 degrees-293 degrees C and 0.2-5.2 wt % NaCl equiv in the enargite-pyrite veins: 178 degrees-265 degrees C and 0.2-7.5 wt % NaCl equiv in quartz of carbonate-replacement orebodies; 168 degrees-999 degrees C and 3-11.8 wt % NaCl equiv in sphalerite of carbonate-replacement orebodies; and 245 degrees-261 degrees C and 3.2-7.7 wt % NaCl equiv in quartz from Venencocha). Oxygen and hydrogen isotope compositions oil kaolinite from carbonate-replacement orebodies (delta(18)O = 5.3-11.5%o, delta D = -82 to -114%o) and on alunite from the Venencocha and Santa Rosa areas (delta(18)O = 1.9-6.9%o, delta D = -56 to -73%o). Oxygen isotope compositions of quartz from the first and second stages have 6180 values from 9.1 to 1.7.8 per mil. Calculated fluids in equilibrium with kaolinite have delta(18)O values of 2.0 to 8.2 and delta D values of -69 to -97 per mil; values in equilibrium with alunite are -1.4 to -6.4 and -62 to -79 per mil. Sulfur isotope compositions of sulfides from both stages have a narrow range of delta(34)S values, between -3.7 and +4.2 per mil; values for sulfates from the second stage are between 4.2 and 31.2 per mil. These results define two mixing trends for the ore-forming fluids. The first trend reflects mixing between a moderately saline (similar to 10 wt % NaCl equiv) magmatic end member that had degassed (as indicated by the low delta D values) and meteoric water. The second mixing indicates condensation of magmatic vapor with HCl and SO(2) into meteoric water, which formed alunite. The hydrothermal system at Cerro de Pasco was emplaced at a shallow depth (similar to 500 m) in the epithermal and upper part of a porphyry environment. The similar temperatures and salinities obtained for the first stage and second stages, together with the stable isotope data, indicate that both stages are linked and represent successive stages of epithermal polymetallic mineralization in the upper part of a porphyry system.

Apparent stable-isotope heterogeneities in gangue carbonates of the Mississippi Valley-type Zn-Pb deposits of San-Vicente, Central Peru

The aim of the present communication is to emphasize that some variations of the measured delta(13)C and delta(18)O values are apparent, and due to analytical interferences caused by the presence of sulfur and organosulfur compounds in the analyzed carbonates. This is particularly relevant for isotopic studies on carbonate-hosted mineral deposits, where the nearly ubiquitous association of the host carbonates with organic matter and sulfides can certainly affect the metallogenetic interpretations. In this work two methods were used to overcome the disturbing effects of sulfides and organic matter: (1) sample pretreatment following the method proposed by Charef and Sheppard (1984), combining the oxidation of organic matter with sodium hypochlorite and trapping of the sulfur species with silver phosphate; and (2) laser-based microprobe extraction. Apparent isotopic variations in sparry dolomite from a single hand sample of zebra ore from the MVT Zn-Pb deposit, San Vicente, central Peru, are as large as 6 parts per thousand delta(13)C and 4 parts per thousand delta(18)O. These variations are reduced to several tenths of a per mil when the samples are pretreated. A careful examination of the effects of treatment with NaOCl and/or Ag3PO4 in relation to the concentration of sulfide inclusions indicates that the main disturbing effects for delta(13)C values are the presence of sulfur species and organic matter, whereas the delta(18)O values are mainly affected by the presence of sulfides. Fine- and medium-grained replacement carbonates from MVT and other sediment-hosted base metal deposits are potentially the most affected during isotope analysis, due to the common presence of organic matter and sulfides. Using in situ laser microprobe techniques, it is possible to determine isotopic variations at a sub-millimeter scale. Our results show that laser extraction analysis allows a more precise sampling of the carbonate minerals, and minimizes contamination of the sample with sulfides and to some extent with intergrown organic matter. However, there is an isotopic shift associated with the laser extraction technique, of the order of 0.5-1 parts per thousand for delta(13)C and delta(18)O values.

De la stratification sociale à la mobilité : une analyse du positionnement professionnel perçu

Avant-propos : De nombreuses études ont été réalisées sur les inégalités factuelles des structures sociales, comprenant aussi bien l'aspect statique de la stratification sociale que l'aspect dynamique de la mobilité sociale (voir par exemple Levy et Suter, 2002, Lemel, 1991, Erikson et Goldthorpe, 1992, Esping-Andersen, 1993). Par contre, les recherches portant sur la perception, par les acteurs, des inégalités des structures sociales sont en comparaison peu nombreuses en ce qui concerne les représentations de la stratification sociale (Levy et al., 1997, Lorenzi-Cioldi et Joye, 1988, Coxon, Davies et Jones, 1986, Zwicky, 1989) et presque inexistantes dans le cas des représentations de la mobilité sociale (Attias-Donfut et Wolff, 2001). La présente recherche se propose d'étudier simultanément la perception de la stratification sociale et de la mobilité sociale intragénérationnelle par les acteurs en intégrant le caractère multidimensionnel du système d'inégalités. Elle défend la thèse fondamentale d'une double origine des inégalités perçues, qui participeraient à la fois d'aspects macrosociaux et mésosociaux de la stratification sociale, les premiers portant sur la structure sociale dans son ensemble, les seconds sur une partie seulement de celle-ci (voir par exemple Kelley et Evans, 1995, Levy, 2002). Dans une perspective systémique, on se trouverait, à côté de la structure macrosociale, en présence de sous-systèmes mésosociaux, de portée restreinte. La perception de la stratification sociale dépendrait alors du cadre de référence adopté par les acteurs, selon qu'il porte sur le système dans son ensemble ou sur un sous-système. Un des objectifs de cette recherche sera d'établir que la pertinence des cadres de référence macrosocial et mésosocial est étroitement liée à la lecture statique ou dynamique de la stratification sociale. Dans le cas statique, celui du positionnement, les représentations sociales s'articuleraient autour des inégalités macrosociales, tenant compte du système dans son ensemble, tandis que dans le cas dynamique, celui de la mobilité ou de l'évolution du positionnement, les inégalités mésosociales, propres aux sous-systèmes, l'emporteraient. D'une part, la perception du positionnement social dépendrait de l'insertion de l'acteur dans la structure sociale, comprise dans son ensemble, et reproduirait les inégalités factuelles macrosociales, telles qu'elles apparaissent par exemple au travers des catégories socioprofessionnelles. D'autre part, la perception du parcours de mobilité ? conservation, amélioration ou dégradation de la position perçue ? resterait indépendante des changements macrosociaux de l'insertion, mais relèverait avant tout de déterminants propres à l'environnement social immédiat de l'acteur. L'environnement de l'acteur, en tant qu'il s'inscrit dans une partie restreinte de la structure sociale, permettrait de saisir les inégalités mésosociales. L'expérience, par les acteurs, de ces deux aspects de la structure sociale conduirait à la mise en place de deux types d'inégalités perçues irréductibles les unes aux autres dans la mesure où le système macrosocial et les sous-systèmes mésosociaux présentent une certaine autonomie. Cette autonomie peut être vue d'une part en rapport avec l'importance propre des organisations de nature mésosociale - en particulier les entreprises - dans les sociétés contemporaines (Sainsaulieu et Segrestin, 1986, Perrow, 1991), d'autre part en relation avec l'hétérogénéité que ces dernières induisent en termes de segmentation du marché de l'emploi (Baron et Bielby, 1980). Dans une large mesure, les organisations intermédiaires se distinguent ainsi de la structure sociale prise dans son ensemble: plutôt que de reproduire les inégalités macrosociales, elles constitueraient des systèmes d'inégalités indépendants, notamment quant à la régulation des parcours professionnels (Bertaux, 1977). Ainsi, la perception de la structure sociale ne se réduirait pas aux seuls facteurs macrosociaux, mais dépendrait, en l'absence d'un modèle d'organisation mésosocial unique, de la diversité des structures intermédiaires. On peut d'ailleurs supposer que la prise en compte des organisations mésosociales est susceptible de pallier la faiblesse des explications classiques en termes macrosociologiques, relevées par les tenants des thèses avançant le déclin du pouvoir structurant de la stratification sociale ou du travail (voir Levy, 2002 et, sur les thèses citées, par exemple Beck, 1983, Matthes, 1983, Berger et Hradil, 1990, Clark et Lipset, 1991). En effet, dans la mesure où l'acteur serait plus souvent confronté aux structures de son environnement social immédiat plutôt qu'à la structure sociale dans son ensemble, la perception pourrait dépendre en premier lieu de facteurs mésosociaux, susceptibles de supplanter ou, à tout le moins, d'atténuer l'effet des facteurs macrosociaux. Une telle approche permet de conserver une lecture structurelle de la perception du positionnement en enrichissant la relation classique entre structure macrosociale et acteur d'une composante mésosociologique, évitant ainsi le recours à une explication culturelle ad hoc Dès lors, la principale question de recherche s'adresse au lien entre structure sociale factuelle et structure sociale perçue. Dans la perspective statique du positionnement, l'effet des structures mésosociales serait tel qu'il se superposerait à la détermination macrosociale de la perception, sans pour autant subvertir la hiérarchie des positions induites par les catégories socioprofessionnelles. Dans la perspective dynamique, en revanche, les changements liés à l'insertion mésosociale peuvent l'emporter sur l'immobilité ou la mobilité définies en termes macrosociologiques. D'une part, en supposant que les plans mésosocial et macrosocial agissent de manière plus ou moins autonome sur la perception, l'amélioration, la conservation ou la dégradation de la position ne coïncide pas nécessairement selon ces deux plans. D'autre part, l'ampleur de la mobilité perçue due à l'écart entre le positionnement mésosocial passé et actuel peut dépasser celle qui est liée à la mobilité macrosociale, surtout si cette dernière est de faible distance. Le passage de la perspective statique à la perspective dynamique peut dès lors être vu comme un moyen de faire apparaître le rôle fondamental joué par les structures mésosociales au sein de la stratification sociale. L'orientation de la recherche consistera d'abord à mettre en évidence, par-delà les différences macrosociales des représentations des positions professionnelles, les variations de la perception au sein des catégories socioprofessionnelles. Ces étapes montreront, à différents égards, que les représentations se singularisent en relation avec l'insertion mésosociale de l'acteur. On verra également que la perception de la mobilité échappe à une détermination macrosociale, mais qu'elle présente une cohérence mésosociale certaine. Ces résultats, insistant sur la prise en compte des structures mésosociales, nous amèneront enfin à un examen systématique des déterminants de la perception du positionnement et du parcours de mobilité, mettant en oeuvre une variété de facteurs explicatifs dépassant un cadre d'analyse purement structurel. La recherche débute par une discussion de la place qui revient à une étude des représentations du parcours professionnel dans le champ des travaux sur la stratification et la mobilité sociale, en particulier sa justification théorique et empirique, et la formulation des hypothèses de recherche (chapitre 1). Elle se poursuit par la présentation de l'échantillonnage et des variables utilisées (chapitre 2). Le traitement des hypothèses de recherche fait l'objet de trois chapitres distincts. Chaque hypothèse s'accompagne, en plus des développements liés à son examen, d'une introduction et d'une conclusion spécifiques. Le premier (chapitre 3) porte sur la perception de la stratification sociale des positions professionnelles, le second (chapitre 4) sur la perception du parcours de mobilité et le troisième (chapitre 5) sur les déterminants sociologiques de la perception des inégalités liées au positionnement et à la mobilité professionnels. Enfin, au traitement des hypothèses fait suite la conclusion de la recherche (chapitre 6).