Your search keyword '"Ramon Mercedes-Martín"' showing total 20 results

1. Effects of salinity, organic acids and alkalinity on the growth of calcite spherulites: Implications for evaporitic lacustrine sedimentation

Author

Ramon Mercedes‐Martín, Ashit Rao, Mike Rogerson, and Mónica Sánchez‐Román

Subjects

alginic acid, alkaline, calcite, evaporation, salinity, shrub, Geology, QE1-996.5

Abstract

Abstract Lacustrine non‐skeletal carbonates exhibit a diversity of petrographies due to interactions between physico‐chemical and biologically influenced mechanisms. Despite the suggestion that evaporative concentration was involved in the formation of spherulite and shrubby‐bearing carbonate successions in the Pre‐Salt Cretaceous alkaline lakes of the South Atlantic, no consensus exists about the water chemistries promoting these exotic mineral textures. In this work, an experimental approach was developed to evaluate how changes in salinity (NaCl) and biopolymer concentrations (alginic acid) impact calcite growth dynamics from saline and alkaline synthetic solutions. Hydrochemical and petrographical data from selected modern saline/alkaline environments were compared with experimental datasets to further estimate how the underlying (bio)chemical conditions and lake locations probably converge to allow the formation of calcite spherulite grains in evaporitic settings. Spherulitic calcite from Recent saline lakes and experiments arise from waters with moderate to high [Calcium]/[Alkalinity] ratios ([Ca]/[Alk]) rather than in calcium‐depleted and alkaline‐rich environments which tend to produce single‐crystal calcites during abiotic water mixing or lake evaporation. This observation is consistent with the assembly of polycrystalline textures being a kinetically controlled feature, forced by remarkably high rates of nucleation. Also, the data analysed do not support a causative relationship between evaporite‐driven salinity fluctuations and the preferential formation of spherulites, shrubs or their intermediate textures. Ubiquitous in saline lakes, organic substances can lower the kinetic thresholds for spherulitic calcite aggregation while microbial photosynthesis can also raise pH, altogether enhancing calcite supersaturation and promoting spherulite formation in waters with moderate‐high [Ca]/[Alk] ratios and high salinities. Localised observations of abiotic spherulites in Recent soda lakes can occur in restricted mixing zones where [Ca]/[Alk] ratios are enhanced. This work highlights the roles of concentration regimes associated with biopolymers and microbial metabolism against the background salinity fluctuations in determining the morphological and textural transitions in lacustrine carbonate minerals.

Published

2022

2. What are the different styles of calcite precipitation within a hyperalkaline leachate? A sedimentological Anthropocene case study

Author

Laura Bastianini, Mike Rogerson, Ramon Mercedes‐Martín, Timothy J. Prior, and William M. Mayes

Subjects

anthropogenic carbonates, biotic, calcite precipitation, travertines, Geology, QE1-996.5

Abstract

Abstract This study aims to compare the fabrics of anthropogenic carbonates downstream of lime and steel disposal sites with models of carbonate precipitation from natural systems to elucidate potential drivers, precipitation mechanisms, morphological similarities, predictability in 3D facies distributions and depositional models of these systems. For this purpose, a combination of sedimentological, mineralogical and geochemical approaches is conducted including the analysis of microfacies (petrographic microscope and electron microscopy), X‐ray diffraction and hydrochemistry. The data show that both anthropogenic and natural systems exhibit clear proximal, middle and distal zones of carbonate precipitation. The main macroscopic differences are the dominance of swamp environments in the proximal zone and the prevalence of tufa‐like barrage‐and‐pool sequences in the middle and distal zones. Microfabrics in anthropogenic sites are comparable to travertines but lack the sub‐surface facies and at extreme pH exhibit sparry crusts without clear equivalents in travertines. This sedimentology of anthropogenic carbonates shows that calcite mineral formation is complex and not homogeneous or purely driven by thermodynamic processes. Considering the sedimentology of these human‐induced systems will help us understand precipitation mechanisms which will aid both efforts to utilise anthropogenic alkaline wastes for carbon capture and manage their environmental impacts.

Published

2022

3. What Causes Carbonates to Form 'Shrubby' Morphologies? An Anthropocene Limestone Case Study

Author

Laura Bastianini, Mike Rogerson, Ramon Mercedes-Martín, Timothy J. Prior, Edgley A. Cesar, and William M. Mayes

Subjects

Pre-Salt reservoirs, alkaline steel slag, Consett, shrubby carbonate, microbial, hydrochemistry, Science

Abstract

The South Atlantic Aptian “Pre-Salt” shrubby carbonate successions offshore Brazil and Angola are of major interest due to their potential hydrocarbon accumulations. Although the general sedimentology of these deposits is widely recognized to be within saline, alkaline lakes in rift volcanic settings, the specific genesis of shrubby carbonate morphologies remains unclear. This study reports the first petrographically comparable shrubby carbonates amongst other carbonate microfacies from an Anthropocene limestone formed under hyperalkaline (pH 9–12) and hypersaline (conductivity 425–3200 μS) conditions at ambient temperature (12.5–13°C) (Consett, United Kingdom). This discovery allows us to capitalize on exceptional long-term hydrochemical monitoring efforts from the site, demonstrating that shrubby carbonates occur uniquely within the waters richest in calcium (∼240 mg/L) and with highest pH (∼12) and consequently with very high levels of supersaturation. However, the physical distribution of shrubs is more comparable with estimated local kinetic precipitation rate than it is to thermodynamic saturation, indicating that the fundamental control on shrub formation arises from crystal surface processes. The shrubby carbonate we report grows in the presence of significant diatomaceous and cyanobacterial biofilms, despite the highly alkaline conditions. These biofilms are lost from the deposited material early due to the high solubility of organic and silica within hyperalkaline settings, and this loss contributes to very high intercrystalline porosity. Despite the presence of these microbes, few if any of the fabrics we report would be considered as “boundstones” despite it being clear that most fabrics are being deposited in the presence of abundant extra-cellular polymeric substances. We are aware of no previous petrographic work on anthropogenic carbonates of this type, and recommend further investigation to capitalize on what can be learned from these “accidental laboratories.”

Published

2019

4. The geomorphological distribution of subaqueous tufa columns in a hypersaline lake: Mono Lake, U.S.A

Author

Claire E. Keevil, Mike Rogerson, Daniel R. Parsons, Ramon Mercedes-Martín, Alexander T. Brasier, John. J.G. Reijmer, Anna Matthews, and Earth Sciences

Subjects

F800, Geology, F600

Abstract

Understanding the flow of carbon through hyperalkaline lakes is a key means of understanding their biogeochemistry, sedimentology, and their paleoenvironmental and paleoclimatic records. Furthermore, understanding how mineral precipitation is regulated in these lakes can provide insights into how their sequestration of carbon can be managed. We report geophysical surveys of Mono Lake, California, USA, which show unanticipated geomorphological control on the recent/contemporary formation of lacustrine carbonate formations (“tufa”). Acquired shallow-penetration seismic data show a fault zone below the lake floor, but despite the regional evidence for geothermal waters rising up these fractures, we find no evidence for tufa precipitation at the surface exposure of this structure, either in the seismic data or in the swath bathymetry. However, we do find sub-lacustrine tufa columns in these data elsewhere, which is the first time these have been reported directly. We find and report on a strong link between column location and meteoric Ca supply to the lake, with the latter sourced either through surface runoff or groundwater. For example, a region close to a creek inlet has more frequent and larger tufa bodies, which grow at a wider depth range than another region far from an inlet but close to the fault. This demonstrates the importance of meteoric water ingress in regulating carbonate mineral formation in these basins, and raises the possibility that management of water within the catchment could be a means to enhance carbon capture in natural and artificial hyperalkaline lakes.

Published

2022

5. What are the different styles of calcite precipitation within a hyperalkaline leachate? A sedimentological Anthropocene case study

Author

Mike Rogerson, Laura Bastianini, Ramon Mercedes-Martín, William M. Mayes, and Timothy J. Prior

Subjects

biotic, Stratigraphy, Geochemistry, F700, travertines, F800, Environmental Science (miscellaneous), engineering.material, F600, Oceanography, Natural (archaeology), Sedimentary depositional environment, chemistry.chemical_compound, calcite precipitation, Precipitation, Sedimentology, Lime, Calcite, anthropogenic carbonates, QE1-996.5, Paleontology, Geology, chemistry, Facies, engineering, Carbonate

Abstract

This study aims to compare the fabrics of anthropogenic carbonates downstream of lime and steel disposal sites with models of carbonate precipitation from natural systems to elucidate potential drivers, precipitation mechanisms, morphological similarities, predictability in 3D facies distributions and depositional models of these systems. For this purpose, a combination of sedimentological, mineralogical and geochemical approaches is conducted including the analysis of microfacies (petrographic microscope and electron microscopy), X‐ray diffraction and hydrochemistry. The data show that both anthropogenic and natural systems exhibit clear proximal, middle and distal zones of carbonate precipitation. The main macroscopic differences are the dominance of swamp environments in the proximal zone and the prevalence of tufa‐like barrage‐and‐pool sequences in the middle and distal zones. Microfabrics in anthropogenic sites are comparable to travertines but lack the sub‐surface facies and at extreme pH exhibit sparry crusts without clear equivalents in travertines. This sedimentology of anthropogenic carbonates shows that calcite mineral formation is complex and not homogeneous or purely driven by thermodynamic processes. Considering the sedimentology of these human‐induced systems will help us understand precipitation mechanisms which will aid both efforts to utilise anthropogenic alkaline wastes for carbon capture and manage their environmental impacts.

Published

2022

6. Effects of salinity, organic acids and alkalinity on the growth of calcite spherulites

Author

Mike Rogerson, Ashit Rao, Ramon Mercedes-Martín, Mónica Sánchez-Román, Geology and Geochemistry, MESA+ Institute, and Physics of Complex Fluids

Subjects

UT-Gold-D, Stratigraphy, Alkalinity, Evaporation, F800, F600, Environmental Science (miscellaneous), Oceanography, evaporation, salinity, chemistry.chemical_compound, shrub, Alginic acid, Calcite, alginic acid, QE1-996.5, Chemistry, Paleontology, Geology, Sedimentation, Salinity, spherulite, Spherulite, Environmental chemistry, alkaline, calcite

Abstract

Lacustrine non‐skeletal carbonates exhibit a diversity of petrographies due to interactions between physico‐chemical and biologically influenced mechanisms. Despite the suggestion that evaporative concentration was involved in the formation of spherulite and shrubby‐bearing carbonate successions in the Pre‐Salt Cretaceous alkaline lakes of the South Atlantic, no consensus exists about the water chemistries promoting these exotic mineral textures. In this work, an experimental approach was developed to evaluate how changes in salinity (NaCl) and biopolymer concentrations (alginic acid) impact calcite growth dynamics from saline and alkaline synthetic solutions. Hydrochemical and petrographical data from selected modern saline/alkaline environments were compared with experimental datasets to further estimate how the underlying (bio)chemical conditions and lake locations probably converge to allow the formation of calcite spherulite grains in evaporitic settings. Spherulitic calcite from Recent saline lakes and experiments arise from waters with moderate to high [Calcium]/[Alkalinity] ratios ([Ca]/[Alk]) rather than in calcium‐depleted and alkaline‐rich environments which tend to produce single‐crystal calcites during abiotic water mixing or lake evaporation. This observation is consistent with the assembly of polycrystalline textures being a kinetically controlled feature, forced by remarkably high rates of nucleation. Also, the data analysed do not support a causative relationship between evaporite‐driven salinity fluctuations and the preferential formation of spherulites, shrubs or their intermediate textures. Ubiquitous in saline lakes, organic substances can lower the kinetic thresholds for spherulitic calcite aggregation while microbial photosynthesis can also raise pH, altogether enhancing calcite supersaturation and promoting spherulite formation in waters with moderate‐high [Ca]/[Alk] ratios and high salinities. Localised observations of abiotic spherulites in Recent soda lakes can occur in restricted mixing zones where [Ca]/[Alk] ratios are enhanced. This work highlights the roles of concentration regimes associated with biopolymers and microbial metabolism against the background salinity fluctuations in determining the morphological and textural transitions in lacustrine carbonate minerals.

Published

2022

7. Geochemical approach for decoding the paleoenvironmental and depositional evolution of a coastal lacustrine Konservat-Lagerstätte (Early Cretaceous, south-Central Pyrenees)

Author

Alejandro Gil-Delgado, David Cruset, Oriol Oms, Edgar Botero, Jordi Ibáñez-Insa, Xavier Delclòs, Albert Sellés, Àngel Galobart, and Ramon Mercedes-Martín

Subjects

Stratigraphy, Multiproxy geochemistry, Fossil lagerstätte, Geology, Lacustrine carbonates, Stable isotopes

Abstract

Altres ajuts: acords transformatius de la UAB Altres ajuts: Departament de Cultura of the Generalitat de Catalunya and the CERCA Program - ARQ001SOL-173-2022 The lithographic limestone of La Pedrera de Meià (LPM) in south-Central Pyrenees (NE Spain) is considered one of the best preserved lacustrine-coastal successions of the Early Cretaceous in Europe, hosting a taxonomically diverse record of Barremian biota. While this Konservat-Lagerstätte has been extensively surveyed for paleontological purposes, little is known about the paleoenvironmental and depositional conditions prevailing during the formation of this fossil lagerstätte deposit. LPM limestone is made up of a homogeneous, dark gray to pale brown, faintly laminated 50 m-thick succession of micrite-rich intervals. To shed light on the environmental conditions of deposition, 303 rock samples were studied using a multiproxy approach based on different techniques including petrography, SEM-EDX, XRD, ICP-MS, XRF, Rare Earth Element distributions and C and O stable isotope geochemistry. The combination of sedimentological and geochemical data reveals a vertical shift of facies from littoral to profundal environments and then returning to littoral conditions. Profundal facies are made up of filament-rich mudstones originated from in situ precipitation of micrite either through biotically mediated or physico-chemical processes in undisturbed low energy settings, under anoxic conditions, characterized by the presence of transported terrestrial and lacustrine organisms that are exquisitely well-preserved. Littoral areas are characterized by the presence of in situ charophytes, smooth ostracods, and miliolid foraminifera that accumulated in mud-rich facies indicating low/moderate-energy, shallow-water, and relatively oxygenated conditions. Stable isotopic data and elemental geochemistry suggest a hydrologically closed to semi-closed lacustrine system with a restricted water circulation encouraging dysoxic to anoxic conditions in profundal sediments. Paleoproductivity proxies suggest a good correlation between catchment-derived siliciclastic discharge to the lake and primary productivity peaks. Furthermore, a decline interrigenous input coupled with a reduction of meteoric water entrance to the lake is interpreted based on elemental proxies derived from paleosalinity and paleoredox analysis. Collectively, the strontium/barium (Sr/Ba) ratios, the sparse presence of miliolid foraminifera, and the isotopic signatures indicate an increase in salinity toward the younger intervals of the lake infilling, although their ultimate causes are unclear (i.e., increased evaporation, or a combination of reduced meteoric input and sporadic marine inputs might explain our data). The present work shows the importance of performing detailed multiproxy geochemical-sedimentological studies to better constrain the unique paleoenvironmental and paleohydrological conditions associated with the exceptional preservation of fossil biotas in Konservat-Lagerstätte deposits in analogous depositional settings.

Published

2023

8. Cretaceous coastal lake carbonate geochemistry of La Pedrera de Meià fossil site (southern Pyrenees)

Author

Alejandro Gil-Delgado, Edgar Botero, Jordi Ibàñez-Insa, Ramon Mercedes-Martín, Albert Sellés, Xavier Delclòs, Àngel Galobart, and Oriol Oms

Abstract

La Pedrera de Meià (LPM) fossil site, discovered in the 19th century, is an important Barremian Konservat-Lagerstätte located at the southern slope of the Montsec range (Lleida province, Spain). LPM is comparable in fossil preservation with other European lithographic limestones lagerstätten sites such as Solnhofen (Germany), Cerin (France) or Las Hoyas (Spain). The LPM site stands out by the conservation of soft tissues of different groups of plants and animals such as arthropods, osteichthyes, frogs or feathered dinosaurs. The high biodiversity recorded in fossil pieces there are up to 50 holotypes and paratypes described, including the first flowered plants or social insects in the history of life. Such a unique fossil record is widespread throughout the most significant collections all over Europe.Geologically, the outcrop records the deepest part of a coastal lake after a succession of 50 m of laminated mudstones, with restricted lateral continuity. These mudstones produce slabs from metric to millimetric thickness and appear very monotonous. Overall, no conspicuous vertical textural changes can be recognized in outcropThe main objective of this study is to gain insights on the paleoenvironmental and paleoclimatic conditions concurring to lake formation where the LPM outcrop is located. For this purpose, a detailed stratigraphic study has been performed together with petrographical and geochemical analyses on rock samples collected across a 50m-thick sedimentary log to precisely locate all the samples of a multiproxy study. Our analysis includes X- Ray fluorescence (XRF), throughout all the stratigraphic log. Other analytical measurements have been carried out in a shorter control interval to obtain more accurate data that can be extrapolated to the whole column by using the XRF results. These include X-Ray diffraction (XRD), C and O stable isotopes, loss on ignition of organic matter, pyrite framboid petrography, and laminae counting. Comparison of the complete XRF record with the results of laminae counting suggests that cycles could be orbitally forced. It is concluded that the multiproxy dataset along the shorter interval allows one to characterize the paleoenvironmental evolution of this exceptional site.The present LPM geochemical data is also being used to test whether lithographic limestone localities have distinctive compositional fingerprint. Worldwide lithographic limestone’s localities are thus compared. The goal is to attain a pattern that may enable one to identify the original site of any specimen in a museum which may have no associated information. In other words, our objective is to assess whether a fossil belongs to the LPM and/or even to determine the specific stratigraphic interval from which it was obtained.

Published

2022

9. Faunal composition and paleoenvironmental reconstruction of a Middle-Late Triassic boundary assemblage in the Pyrenean basin (Catalonia, NE Spain)

Author

Joan Cartanyà, Arnau Bolet, Ruben Garcia-Artigas, Marc Riccetto, Josep Fortuny, and Ramon Mercedes-Martín

Subjects

Paleontology, Boundary (topology), Assemblage (archaeology), Structural basin, Geology

Abstract

Altres ajuts: We acknowledge support from the CERCA programme (ICP) from the Generalitat de Catalunya, and the projects "Vertebrats del Permià i el Triàsic de Catalunya i el seu context geologic" (Ref. 2010/70085), "Evolució dels ecosistemes amb faunes de vertebrats del Permià i el Triàsic de Catalunya" (ref. 2014/100606) and "Evolució dels ecosistemes durant la transició Paleozoic-Mesozoic a Catalunya" (ref. CLT009/18/00066) The Ladinian-Carnian transition in the Tethys domain was accompanied by an important environmental change representing a milestone in the climate evolution of the Triassic. However, estimations on paleodiversity composition and paleoenvironmental conditions across this interval are scarce in marine settings due to the lack of fossil-bearing successions. In this work, a refined paleontological and sedimentological study has allowed us to better characterize a well-preserved marine ?Ladinian-Carnian carbonate succession in the South Central Pyrenees (Odèn site, Catalonia, NE Spain). Vertebrate faunas include numerous actinopterygian specimens, forming an assemblage composed of at least four taxa: Peltopleurus cf. P. nuptialis Lombardo, 1999, Saurichthys sp., Colobodus giganteus (Beltan, 1972), and an indeterminate halecomorph. Specimens belonging to the genus Peltopleurus are dominant; the long-snouted Saurichthys, the halecomorph, and the large-bodied Colobodus giganteus are less abundant. Tetrapod remains are scarcely present and are assigned to sauropterygians. Invertebrate faunas include bivalves (Pseudocorbula gregaria [Münster in Goldfuss, 1838]) and brachiopods (Lingula sp.). The fossil assemblage was recovered from organic-rich laminated silty mudstone layers. Sedimentological and textural analyses suggest that fossil biotas were deposited below the fair-weather wave base in shallow subtidal coastal settings. These environments were sporadically sourced by silt/clay. The age of the Odèn site, on the basis of the recovered fauna, is assigned to the ?late Ladinian-middle Carnian (Middle-Late Triassic), which is in agreement with previously published ages based on palynomorph data. The refined integration of paleontological, sedimentological, and biostratigraphic data from the Odèn site and other vertebrate-bearing localities in the Tethys domain can help better constrain the paleoenvironmental conditions and paleogeographical configuration impacting ecosystem diversity during the late Ladinian-Carnian interval.

Published

2022

10. Towards a morphology diagram for terrestrial carbonates: evaluating the impact of carbonate supersaturation and alginic acid in calcite precipitate morphology

Author

Alexander T. Brasier, Martyn Pedley, Timothy J. Prior, Anna Matthews, Ian Billing, John J. G. Reijmer, Ramon Mercedes-Martín, Scott Lepley, Mike Rogerson, and Tracy Love

Subjects

Calcite, Supersaturation, Mineral, 010504 meteorology & atmospheric sciences, Precipitation (chemistry), Mineralogy, F800, F600, 010502 geochemistry & geophysics, 01 natural sciences, F900, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, Carbonate, Sedimentary rock, Single crystal, 0105 earth and related environmental sciences, Phase diagram

Abstract

Ancient and recent terrestrial carbonate-precipitating systems are characterised by a heterogeneous array of deposits volumetrically dominated by calcite. In these environments, calcite precipitates display an extraordinary morphological diversity, from single crystal rhombohedral prisms, to blocky crystalline encrustations, or spherulitic to dendritic aggregates. Despite many decades of thorough descriptive and interpretative work on these fabrics, relating calcite micro-morphology with sedimentary hydrogeochemical conditions remains a challenge. Environmental interpretations have been hampered by the fact that calcite morphogenesis results from the complex interaction between different physico-chemical parameters which often act simultaneously (e.g., carbonate mineral supersaturation, Mg/Ca ratio of the parental fluid, organic and inorganic additives). To try to experimentally address the sedimentological causes of calcite morphogenesis, an experimental approach yielding a first attempt at a calcite growth-form phase diagram is presented here. The initial aim was to account for the carbonate products experimentally nucleated in alkaline, saline lake settings. These are the result of at least two competing calcite precipitation ‘driving forces’ that affect morphogenesis: the calcite supersaturation level of the parental fluid, and the concentration of microbial-derived organic molecules (alginic acid). A key finding of this study is that common naturally-occurring calcite products such as calcite floating rafts, rhombohedral prismatic forms, di-pyramid calcite crystals, spherulitic calcite grains, or vertically stacked spheroidal calcite aggregates, can be related to specific hydrogeochemical contexts, and their physical transitions pinpointed in a phase diagram. By exploring binary or ternary responses to forcing in morphological phase-space, links between calcite growth forms and (palaeo)environmental conditions can be determined. This provides a truly process-oriented means of navigating questions around carbonate precipitate morphogenesis for the future.

Published

2021

11. A microbial role in the construction of Mono Lake carbonate chimneys?

Author

John J. G. Reijmer, Alexander T. Brasier, Martin Saunders, Colin Taylor, Mike Rogerson, Siri Kellner, Timothy J. Prior, Ramon Mercedes-Martín, Paul Guagliardo, Anna Matthews, David Wacey, and Geology and Geochemistry

Subjects

Geologic Sediments, 010504 meteorology & atmospheric sciences, Carbonates, Geochemistry, F800, 010502 geochemistry & geophysics, 01 natural sciences, F900, chemistry.chemical_compound, Microscopy, Electron, Transmission, X-Ray Diffraction, SDG 14 - Life Below Water, Microbial mat, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, General Environmental Science, Calcite, Manganese, Authigenic, Silicate, Lakes, chemistry, 13. Climate action, Benthic zone, General Earth and Planetary Sciences, Carbonate, Carbonate Ion, Microscopy, Electrochemical, Scanning, Environmental Monitoring

Abstract

Lacustrine carbonate chimneys are striking, metre-scale constructions. If these were bioinfluenced constructions, they could be priority targets in the search for early and extraterrestrial microbial life. However, there are questions over whether such chimneys are built on a geobiological framework or are solely abiotic geomorphological features produced by mixing of lake and spring waters. Here, we use correlative microscopy to show that microbes were living around Pleistocene Mono Lake carbonate chimneys during their growth. A plausible interpretation, in line with some recent works by others on other lacustrine carbonates, is that benthic cyanobacteria and their associated extracellular organic material (EOM) formed tubular biofilms around rising sublacustrine spring vent waters, binding calcium ions and trapping and binding detrital silicate sediment. Decay of these biofilms would locally have increased calcium and carbonate ion activity, inducing calcite precipitation on and around the biofilms. Early manganese carbonate mineralisation was directly associated with cell walls, potentially related to microbial activity though the precise mechanism remains to be elucidated. Much of the calcite crystal growth was likely abiotic, and no strong evidence for either authigenic silicate growth or a clay mineral precursor framework was observed. Nevertheless, it seems likely that the biofilms provided initial sites for calcite nucleation and encouraged the primary organised crystal growth. We suggest that the nano-, micro- and macroscale fabrics of these Pleistocene Mono Lake chimneys were affected by the presence of centimetre-thick tubular and vertically stacked calcifying microbial mats. Such carbonate chimneys represent a promising macroscale target in the exploration for ancient or extraterrestrial life.

Published

2018

12. Are spherulitic lacustrine carbonates an expression of large-scale mineral carbonation? A case study from the East Kirkton Limestone, Scotland

Author

H. Martyn Pedley, Hubert B. Vonhof, Ian Billing, Ramon Mercedes-Martín, Rona A. R. McGill, Alexander T. Brasier, Timothy J. Prior, John J. G. Reijmer, Simon M. Fellows, Erin L McClymont, Anna Matthews, Mike Rogerson, and Geology and Geochemistry

Subjects

010504 meteorology & atmospheric sciences, Chalcedony, Outcrop, Carbonate minerals, Geochemistry, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Lake, Palaeozoic, Petrography, chemistry.chemical_compound, Sediment mineralogy, Pre-Salt, SDG 14 - Life Below Water, 0105 earth and related environmental sciences, Calcite, geography, geography.geographical_feature_category, Bedrock, Hydrolysis, PHREEQC, Geology, Magnesium silicate, Europe, chemistry, Facies, engineering, Carbonate, Palaeogeography

Abstract

Lacustrine carbonate deposits with spherulitic facies are poorly understood, but are key to understanding the economically important “Pre-Salt” Mesozoic strata of the South Atlantic. A major barrier to research into these unique and spectacular facies is the lack of good lacustrine spherulite-dominated deposits which are known in outcrop. Stratigraphy and petrography suggest one of the best analogue systems is found in the Carboniferous of Scotland: the East Kirkton Limestone. Here we propose a hydrogeochemical model that explains why the CaCO3, SiO2, Mg-Si-Al mineral suite associated with spherular radial calcite facies forms in alkaline lakes above basaltic bedrock. Demonstrating links between igneous bedrock chemistry, lake and spring water chemistry and mineral precipitation, this model has implications for studies of lacustrine sediments in rift basins of all ages. Using empirical and theoretical approaches, we analyze the relationship between metal mobilization from sub-surface volcaniclastic rocks and the potential for precipitation of carbonate minerals, various Mg-bearing minerals and chalcedony in a lacustrine spherulitic carbonate setting. This suite of minerals is most likely formed by in-gassing of CO2 to a carbon-limited alkaline spring water, consistent with the reaction of alkali igneous rocks in the subsurface with meteoric groundwater. We suggest that an analogous system to that at East Kirkton caused development of the ‘Pre-Salt’ spherulitic carbonate deposits.

Published

2017

13. Permian-Triassic Rifting Stage

Author

José María Tubía, Jacinto Alonso-Azcárate, Ana Márquez-Aliaga, David Gómez-Gras, Javier Luque, Emilio Ramos, Henar Vargas, Sylvie Bourquin, Alfonso Sopeña, Mariano Marzo, Alfredo Arche, Y. Sánchez-Moya, Carlos Galé, Juan Alberto Pérez-Valera, Lidia Rodríguez-Méndez, Belén Galán-Abellán, Alberto Pérez-López, Ramon Mercedes-Martín, Nicola Gretter, Julia Cuevas, Ángela Suárez-Rodríguez, Pablo Plasencia, Fidel Martín-González, Javier Martín-Chivelet, Agustín Martín-Algarra, María José Escudero-Mozo, Fernando Pérez-Valera, Leopoldo Márquez, Blas Lorenzo Valero Garcés, Nemesio Heredia Carballo, Teresa Ubide, Ausonio Ronchi, Marceliano Lago, José F. Barrenechea, Raúl de la Horra, César Viseras, Patricia Cadenas, José Gisbert Aguilar, Ramon Salas, Antonio Goy, José B. Diez, David Sánchez-Fernández, José Arribas, Gabriela Fernández-Viejo, José López-Gómez, Federico Ortí, Violeta Borruel-Abadía, Jorge M. Gaspar-Escribano, Joan Lloret, Instituto de Geociencias [Madrid] (IGEO), Consejo Superior de Investigaciones Científicas [Madrid] (CSIC)-Universidad Complutense de Madrid = Complutense University of Madrid [Madrid] (UCM), Instituto de Nanociencia, Nanotecnologia y Materiales Moleculares, Universidad de Castilla-La Mancha (INAMOL), Universidad de Castilla-La Mancha (UCLM), Géosciences Rennes (GR), Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Rennes (OSUR)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES), Universidad de Oviedo [Oviedo], Cecilio Quesada, José Tomás Oliveira, Universidad Complutense de Madrid = Complutense University of Madrid [Madrid] (UCM)-Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Universidad de Castilla-La Mancha = University of Castilla-La Mancha (UCLM), Université de Rennes (UR)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire des Sciences de l'Univers de Rennes (OSUR), and Université de Rennes (UR)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Rennes 2 (UR2)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Rennes 2 (UR2)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[SDU.STU.TE]Sciences of the Universe [physics]/Earth Sciences/Tectonics, geography, geography.geographical_feature_category, Rift, 010504 meteorology & atmospheric sciences, Permian, Tectonic phase, 010502 geochemistry & geophysics, 01 natural sciences, Supercontinent, Gondwana, Tectonics, Paleontology, Peninsula, [SDU.STU.ST]Sciences of the Universe [physics]/Earth Sciences/Stratigraphy, Mesozoic, Geology, 0105 earth and related environmental sciences

Abstract

International audience; The Permian-Triassic rifting represents the first of the two Mesozoic rifting stages recorded in the Iberian Peninsula. Its first phases of development started during the Early Permian, and were linked to the beginning of the break-up of Pangea, the large, unique and rheologically unstable supercontinent that mainly resulted from the collision of Gondwana and Laurussia. This chapter analyzes this first rifting stage in Iberia in two separate phases, an initial or tectonic phase, and a later mature phase. This analysis focuses on the main Permian-Triassic basins of the Iberian Peninsula: the Pyrenean, Iberian, Catalan, Ebro and Betic basins, as well as the basins located in the present-day Balearic Islands. In order to achieve a better understanding of the analyses of these basins, a multidisciplinary approach has been carried out by 48 researchers, including studies of tectonics, sedimentology, magmatism, mineralogy, geochemistry and paleontology.

Published

2019

14. Growing spherulitic calcite grains in saline, hyperalkaline lakes: experimental evaluation of the effects of Mg-clays and organic acids

Author

Alexander T. Brasier, Ramon Mercedes-Martín, John J. G. Reijmer, Mike Rogerson, Timothy J. Prior, Ian Billing, H. M. Pedley, Simon M. Fellows, Hubert B. Vonhof, Dynamic Earth and Resources, Earth and Climate, Marine Biogeology, and Geology and Geochemistry

Subjects

010504 meteorology & atmospheric sciences, Stratigraphy, F700, Mineralogy, chemistry.chemical_element, F800, F600, 010502 geochemistry & geophysics, 01 natural sciences, chemistry.chemical_compound, SDG 14 - Life Below Water, 0105 earth and related environmental sciences, Alginic acid, Calcite, chemistry.chemical_classification, Supersaturation, Precipitation (chemistry), Magnesium, Geology, Calcium carbonate, chemistry, Chemical engineering, Spherulite, Organic acid

Abstract

The origin of spherical-radial calcite bodies - spherulites - in sublacustrine, hyperalkaline and saline systems is unclear, and therefore their palaeoenvironmental significance as allochems is disputed. Here, we experimentally investigate two hypotheses concerning the origin of spherulites. The first is that spherulites precipitate from solutions super-saturated with respect to magnesium-silicate clays, such as stevensite. The second is that spherulite precipitation happens in the presence of dissolved, organic acid molecules. In both cases, experiments were performed under sterile conditions using large batches of a synthetic and cell-free solution replicating waters found in hyperalkaline, saline lakes (such as Mono Lake, California). Our experimental results show that a highly alkaline and highly saline solution supersaturated with respect to calcite (control solution) will precipitate euhedral to subhedral rhombic and trigonal bladed calcite crystals. The same solution supersaturated with respect to stevensite precipitates sheet-like stevensite crystals rather than a gel, and calcite precipitation is reduced by ~. 50% compared to the control solution, producing a mixture of patchy prismatic subhedral to euhedral, and minor needle-like, calcite crystals. Enhanced magnesium concentration in solution is the likely the cause of decreased volumes of calcite precipitation, as this raised equilibrium ion activity ratio in the solution. On the other hand, when alginic acid was present then the result was widespread development of micron-size calcium carbonate spherulite bodies. With further growth time, but falling supersaturation, these spherules fused into botryoidal-topped crusts made of micron-size fibro-radial calcite crystals. We conclude that the simplest tested mechanism to deposit significant spherical-radial calcite bodies is to begin with a strongly supersaturated solution that contains specific but environmentally-common organic acids. Furthermore, we found that this morphology is not a universal consequence of having organic acids dissolved in the solution, but rather spherulite development requires specific binding behaviour. Finally, we found that the location of calcite precipitation was altered from the air:water interface to the surface of the glassware when organic acids were present, implying that attached calcite precipitates reflect precipitation via metal-organic intermediaries, rather than direct forcing via gas exchange.

Published

2016

15. A depositional model for spherulitic carbonates associated with alkaline, volcanic lakes

Author

Alexander T. Brasier, Hubert B. Vonhof, Martyn Pedley, John J. G. Reijmer, Ramon Mercedes-Martín, Mike Rogerson, Dynamic Earth and Resources, and Geology and Geochemistry

Subjects

Alkaline, 010504 meteorology & atmospheric sciences, Aptian, Outcrop, Stratigraphy, Lacustrine, Geochemistry, F800, F600, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Sedimentary depositional environment, Petrography, Paleontology, chemistry.chemical_compound, Carboniferous, Spherule, Spherulitic, SDG 14 - Life Below Water, 0105 earth and related environmental sciences, Calcite, geography, geography.geographical_feature_category, Geology, Geophysics, Volcano, chemistry, Facies, Volcanic, Pre-salt, Economic Geology

Abstract

The South Atlantic Aptian ‘Pre-salt’ reservoirs are formed by a combination of spherulitic carbonates and Mg-rich clays accumulated in volcanic alkaline lake settings with exotic chemistries. So far, outcrop analogues characterised by metre-thick successions deposited in lacustrine scenarios are elusive so disentangling the genesis of spherulitic carbonates represents a major scientific challenge with business impact. In particular the controls on spatial distribution and the environment of spherulitic facies formation remain poorly constrained, little studied, and hotly debated. To shed light on this conundrum, a spherulitic carbonate-rich, alkaline volcanic lacustrine succession has been analysed at outcrop scale: the Carboniferous East Kirkton Limestone (Scotland). Despite clays being very scarce and limited to layers of amorphous Mg-Si minerals, a diverse array of spherulitic calcitic components were formed, including coated grains, crusts, and build-ups. This setting enables the mechanisms of spherulitic calcite development and the patterns of sediment accumulation to be explored in a geobiological and hydrochemical scenario similar to the ‘Pre-Salt’ subsurface occurrences but divorced from clay influence. The integration of logs, borehole data, outcrop photomosaics and petrographic observations collectively allowed the reconstruction of a depositional model for the East Kirkton lacustrine succession. In this model, calcite spherule nucleation took place at the sediment-water interface in the littoral zone, driven by the co-occurrence of 1) high alkalinity, 2) Ca-Mg rich hydrochemistry, and 3) microbial-derived colloidal exopolymeric substances. These environmental conditions permitted the coeval development of spherulitic cementstone build-ups and spherulitic grainstone-packstone within the wave-agitated zone, and the accumulation of floatstones and laminites of spherulitic grains in deeper lake regions by means of downslope reworking. This model is consistent with the previously documented microbial bloom occurrences and highlights the need to better understand the complex ‘microbe-solution’ interactions before any reliable facies model is envisaged.

Published

2017

16. Diversity and factors controlling widespread occurrence of syn-rift Ladinian microbialites in the western Tethys (Triassic Catalan Basin, NE Spain)

Author

Ramon Salas, Ramon Mercedes-Martín, and Concha Arenas

Subjects

Rift, biology, Stratigraphy, Thrombolite, Geology, Ladinian, Structural basin, biology.organism_classification, Sedimentary depositional environment, chemistry.chemical_compound, Paleontology, chemistry, Upwelling, Carbonate, Transgressive

Abstract

The fault-block carbonate ramps of the Ladinian (Middle Triassic) Catalan Basin hosted a wide variety of microbial deposits which formed during a syn-rift stage. Stratigraphical and sedimentological analyses of these microbialites allow us to reconstruct two depositional models for such microbial deposits. Moreover new insights into the interplay between the intrinsic and extrinsic factors that controlled the widespread development of these microbialites are provided. Stromatolites, ooidal-muddy microbial laminites and thrombolites were analyzed on the basis of their geometry, lamination and textural attributes. These microbialites are distributed over two Transgressive–Regressive sequences and coexisted during the Fassanian (Early Ladinian) regressive stage. Later, stromatolites and ooidal-muddy microbial laminites developed during the Longobardian (Late Ladinian) transgressive stage. Three types of lamina couplets reflect distinct accretion processes linked to water chemistry, sediment supply and hydrodynamic conditions. Thrombolite textures were produced by accretionary, binding and encrusting processes (microbially mediated) and pervasive cementation. The widespread occurrence of microbial deposits is explained as a consequence of a biogeochemical cascade of events (e.g., anoxic/dysoxic seawater conditions, volcanic activity, upwelling of alkaline waters, nutrient concentrations, and microbial blooms), which promoted favorable conditions for microbial growth in the Tethys during the Ladinian. Furthermore, in the Catalan Basin, syn-rift fault induced subsidence and local water energy gradients exerted an essential role in the distribution of the three types of microbialites through space and time. Thrombolites were prone to grow in the hanging wall block of a half-graben (subtidal conditions), whereas stromatolites and ooidal-muddy microbial laminites flourished preferably in a foot wall block setting (intertidal–shallow subtidal conditions). However, the fact that thrombolites exhibit abundant botryoidal and isopachous fibrous marine cements, corrosion and significant microbial evidence allow us to hypothesize about the relationship between thrombolite occurrence and hydrothermal fault-controlled fluid circulation during the Triassic rifting. The two depositional models here proposed constitute a step forward the understanding of the platform-to-basin microbialite heterogeneity during the Ladinian. Furthermore this work sheds new light on the mechanisms that likely promoted microbialite development during a period of major ecological restructuration and complex oceanographic conditions.

Published

2014

17. The hydrochemical evolution of alkaline volcanic lakes: a model to understand the South Atlantic Pre-salt mineral assemblages

Author

Mónica Sánchez-Román, Jordi Tritlla, Carlos Ayora, Ramon Mercedes-Martín, Ayora, Carlos [0000-0003-0238-7723], and Ayora, Carlos

Subjects

010504 meteorology & atmospheric sciences, Lacustrine, Geochemistry, Aquifer, 010502 geochemistry & geophysics, 01 natural sciences, Hydrologically open basin, chemistry.chemical_compound, East African Rift, SDG 14 - Life Below Water, Magnesium-rich clay, 0105 earth and related environmental sciences, Calcite, geography, geography.geographical_feature_category, PHREEQC, Sediment, Silica, Groundwater recharge, Sedimentation, Volcano, chemistry, Pre-salt, General Earth and Planetary Sciences, Baringo, Geology, Groundwater

Abstract

Understand the origin of the exotic strontium-rich calcite/magnesium-rich clay/silica deposits formed during the Early Cretaceous in the South Atlantic Pre-salt lakes is challenging our ability to comprehend the chemical evolution of alkaline volcanic lakes. Here we present a new hydrochemical model based on an open basin concept, thermodynamic equilibrium, and chemical data from Lake Baringo (East African Rift) to shed light on the mechanisms facilitating carbonate-clay-silica precipitation. This model explores the effects that the leakage to adjacent waterbodies, the combination of lake evaporation and lake recharge (with river, hydrothermal and marine waters), and the bathymetric effects of the partial CO2 pressure have in the stationary precipitation of Pre-salt lacustrine mineral assemblages. Sediment thickness calculations suggest that the facies cyclicity in the Pre-salt and elsewhere are likely reflecting temporal fluctuations in the type of waters sourcing the lake, and in the degree of leakage to aquifers over multiple evaporative-freshening cycles. A plausible link between enhanced strontium uptake into Pre-salt calcite allochems and [Ca2+]/[CO3 2−] lake water stoichiometries allows to infer different scenarios for strontium-rich calcite formation with or without magnesium clays. Our conceptual model allows to quantify the role that hydrology (groundwater charge, discharge to aquifers; evaporation) exert on carbonate-clay-silica precipitation providing with a refined framework to understand the basin-scale chemical sedimentation in alkaline lakes. Furthermore, this model represents a robust template upon which critically test the superimposed kinetic factors likely attached to the genesis of specific mineral factories such as those encountered in the South Atlantic Pre-salt alkaline lakes. © 2019 Elsevier B.V., Gernot Arp, Marcelo Rezende, and Mateu Esteban are warmly thanked for stimulating discussions on Pre-salt spherulites-shrubs. Repsol Exploración and Jeferson Luiz Dias are kindly acknowledged for permission to publish the Pre-salt and borehole images respectively. Support from Origins Center project190438131, NWO and Dutch National Science Agenda (NWA) program is greatly appreciated. Albert Nardi (Barcelona Science) is thanked for yielding us permission to use a developing version of GibbsStudio software. Franco Pirajno and two anonymous reviewers are kindly acknowledged for their constructive and detailed comments which improved the final version of this paper. Joan-Albert Sánchez-Cabeza is thanked for his effective editorial work.

Published

2019

18. Facies heterogeneity and depositional models of a Ladinian (Middle Triassic) microbial-dominated carbonate ramp system (Catalan Coastal Ranges, NE Spain)

Author

Ramon Mercedes-Martín, Ramon Salas, and Concha Arenas

Subjects

Evaporite, Stratigraphy, Geology, Context (language use), Ladinian, Oceanography, Sedimentary depositional environment, Paleontology, chemistry.chemical_compound, Geophysics, chemistry, Facies, Carbonate, Economic Geology, Sequence stratigraphy, Sedimentary rock

Abstract

The Ladinian sedimentary successions record a major transgressive pulse of northeastern Iberia during the Middle Triassic. This record is arranged in two transgressive–regressive (T–R) sequences formed by two fault-block microbial and shoal-dominated carbonate ramps. The main factor controlling the creation of accommodation space is the differential rapid syn-rift subsidence, which induces the generation of palaeogeographical barriers that played a key role in the sedimentary architecture and microbial development. The facies architecture of these ramps was reconstructed by means of facies analysis and sequence stratigraphy. T–R sequence 1 corresponds to a fault-block carbonate ramp system dominated by microbialites and oolitic shoals. T–R sequence 2 represents a fault-block carbonate ramp system mainly characterised by lagoons and shoals. The diverse types of microbialites (stromatolites and thrombolites) are widely represented in the inner and middle ramp settings, reaching a width of 45 km and an average thickness of 40 m. T–R sequence 1 contains the most noticeable microbial deposits, stromatolites in the inner ramp (up to 7 m thick) and thrombolites in the middle ramp (up to 40 m thick). T–R sequence 2 is mainly characterised by the occurrence of oolitic stromatolites in the inner ramp and internal shoals and sheltered lagoons in the middle ramp. Microbialites exhibit a fabric-selective ancient porosity which is currently occluded by coarse calcite and quartz cements. The most common types of ancient porosity are interlaminar, vuggy and mouldic (grain dissolution and evaporite replacement). The studied carbonate ramps can be used as an analogue for ancient microbialite reservoirs in rapidly subsiding depositional areas, with a high diversity of microbial deposits formed in restricted to open marine conditions, with a wide array of ancient porosity and a well-known sequence stratigraphic context.

Published

2013

19. Microbial-dominated carbonate platforms during the Ladinian rifting: sequence stratigraphy and evolution of accommodation in a fault-controlled setting (Catalan Coastal Ranges, NE Spain)

Author

Concha Arenas, Ramon Mercedes-Martín, and Ramon Salas

Subjects

Paleontology, Rift, biology, Stromatolite, Keuper, Thrombolite, Geology, Subsidence, Sequence stratigraphy, Ladinian, biology.organism_classification, Unconformity

Abstract

The Upper Muschelkalk sedimentary record constitutes a major transgressive pulse of north‐eastern Iberia during the Ladinian. This record is arranged in two transgressive–regressive (T–R) sequences formed by two stepped microbial‐dominated carbonate ramp systems where accommodation was mainly controlled by extensional faults. This study seeks to gain new insights into how the evolution of syn‐rift subsidence controls the creation of accommodation space, the depositional styles and, especially, the palaeogeographical domains where specific microbialites developed (thrombolites and stromatolites). Thrombolite bodies (at least 40 m thick) display two types of architecture, biostromal and mud‐mounded and stromatolite bodies (at least 7 m thick) consist of tabular and domed, head‐shaped morphologies. Domed and mounded forms are usually developed during stages of increasing accommodation rates, low‐to flat‐nelief forms tend to grow in association with periods of low accommodation rates. A sea‐level fall of at least 50 m occurred at the end of the Early Ladinian leaving the platform subaerially exposed. As a result, a prominent karst with significant erosional incisions and profuse collapse breccia fillings was formed in the inner and middle ramp settings. The resultant subaerial unconformity bounds T–R sequences 1 and 2. Subsidence curves display two stages of rapid/decelerated total subsidence, constituting two discrete rift/post‐rift pulses in the large Triassic rifting period: (i) Buntsandstein – Middle Muschelkalk, and (ii) Late Muschelkalk – Imon Formation (Rhaetian). The second pulse is characterized by a rapid syn‐rift subsidence during the Late Muschelkalk, and a decelerated post‐rift subsidence throughout the deposition of Keuper facies and Imon Formation. The Late Muschelkalk rapid syn‐rift pulse of total subsidence produces gains in accommodation, which controls the development of the stromatolites and thrombolites (biostromes and mud‐mounds).

Published

2013

20. A test of the biogenicity criteria established for microfossils and stromatolites on Quaternary tufa and speleothem materials formed in the 'Twilight Zone' at Caerwys, U.K

Author

Alexander T. Brasier, Mike Rogerson, Ramon Mercedes-Martín, Hubert B. Vonhof, John J. G. Reijmer, Dynamic Earth and Resources, and Geology and Geochemistry

Subjects

Geologic Sediments, Carbonates, Speleothem, F800, F600, Cyanobacteria, Calcium Carbonate, Petrography, chemistry.chemical_compound, Paleontology, SDG 14 - Life Below Water, Calcite, geography, geography.geographical_feature_category, biology, Fossils, Meteoroids, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), United Kingdom, Caves, chemistry, Stromatolite, Space and Planetary Science, Tufa, Carbonate, Carbonate rock, Sedimentary rock, Microscopy, Polarization

Abstract

The ability to distinguish the features of a chemical sedimentary rock that can only be attributed to biology is a challenge relevant to both geobiology and astrobiology. This study aimed to test criteria for recognizing petrographically the biogenicity of microbially influenced fabrics and fossil microbes in complex Quaternary stalactitic carbonate rocks from Caerwys, UK. We found that the presence of carbonaceous microfossils, fabrics produced by the calcification of microbial filaments, and the asymmetrical development of tufa fabrics due to the more rapid growth of microbially influenced laminations could be recognized as biogenic features. Petrographic evidence also indicates that the development of "speleothem-like" laminae was related to episodes of growth interrupted by intervals of nondeposition and erosion. The lack of any biogenic characteristics in these laminae is consistent with their development as a result of variation in the physicochemical parameters that drive calcite precipitation from meteoric waters in such environmental settings.

Published

2015