Your search keyword '"Karen Gariboldi"' showing total 2 results

1. Insights into the diagenetic environment of fossil marine vertebrates of the Pisco Formation (late Miocene, Peru) from mineralogical and Sr-isotope data

Author

Giovanni Bianucci, Karen Gariboldi, Riccardo Petrini, Mario Urbina, C. Di Celma, Elena Bonaccorsi, Giulia Bosio, Marco Pasero, Anna Gioncada, Alberto Collareta, Elisa Malinverno, Gioncada, A, Petrini, R, Bosio, G, Gariboldi, K, Collareta, A, Malinverno, E, Bonaccorsi, E, Di Celma, C, Pasero, M, Urbina, M, and Bianucci, G

Subjects

Fossilization, 010506 paleontology, Mollusk, Dolomite, Mineralogy, Late Miocene, GEO/01 - PALEONTOLOGIA E PALEOECOLOGIA, 010502 geochemistry & geophysics, 01 natural sciences, chemistry.chemical_compound, GEO/08 - GEOCHIMICA E VULCANOLOGIA, Pisco Formation, Marine vertebrate, 0105 earth and related environmental sciences, Earth-Surface Processes, Anhydrite, Bone preservation, Sr-isotope, Geology, Miocene, Gypsum, Diagenesis, Calcium carbonate, Sr-isotopes Gypsum Fossilization Miocene Marine vertebrates Mollusks, chemistry, Sedimentary rock

Abstract

The late Miocene Pisco Formation of Peru is an outstanding example of richness and high-quality preservation of fossil marine vertebrates. In order to reconstruct the fossilization path, we present new textural, mineralogical and Sr-isotope data of diagenetic minerals formed in correspondence of fossil specimens such as marine vertebrates and mollusks. These fossil specimens were found at Cerro los Quesos, in the Ica Desert, within the diatomaceous strata of the Pisco Formation. Dolomite, gypsum, anhydrite and Mn minerals are the main phases found, while the calcium carbonate originally forming the mollusk valves is replaced by gypsum. An early formation of dolomite and of Mn minerals, triggered by the modifications of the geochemical environment due to organic matter degradation, is suggested by the textural relationships and is confirmed by the Sr isotopic ratio of dolomite, which agrees with that of seawater at the time of sedimentation. Instead, gypsum Sr isotopic ratios indicate a pre-Miocene seawater-derived brine circulating within the sedimentary sequence as a source for Sr. Oxidation of diagenetic sulfide causing a lowering of the pH of porewater is proposed as an explanation for Ca-carbonate dissolution. The diagenetic chemical environment was, nevertheless, favorable to bone preservation.

Published

2018

2. Mineralogical and geochemical characterization of fossil bones from a Miocene marine Konservat-Lagerstätte

Author

Giovanni Bianucci, Karen Gariboldi, Elisa Malinverno, Alberto Collareta, Marco Pasero, Claudio Di Celma, Anna Gioncada, Elena Bonaccorsi, Giulia Bosio, Mario Urbina, Bosio, G, Gioncada, A, Gariboldi, K, Bonaccorsi, E, Collareta, A, Pasero, M, Di Celma, C, Malinverno, E, Urbina, M, and Bianucci, G

Subjects

Fossilization, 010506 paleontology, East Pisco Basin, Dolomite, Geochemistry, Lagerstätte, 010502 geochemistry & geophysics, 01 natural sciences, Apatite, Sedimentary depositional environment, chemistry.chemical_compound, Pisco Formation, Chilcatay Formation, Bioapatite, 0105 earth and related environmental sciences, Earth-Surface Processes, Geology, Diagenesis, chemistry, visual_art, Mammalian bone, visual_art.visual_art_medium, Carbonate

Abstract

Fossil bones, together with teeth, are the most common remains of vertebrates that could manage to get preserved over geological times, providing information on the diagenetic and fossilization processes that occurred in the depositional paleoenvironment. Fossil bones from the marine vertebrate Konservat-Lagerstatte in the East Pisco Basin and Sacaco area (Peru) show a high variety of different textural and chemical features, suggestive of different processes variably contributing to the fossilization path. At the macroscopic scale, bone samples can be grouped into six different categories on the basis of the color (red to gray to white) and hardness (which relates to the mineralization degree); a variety of case studies can be found between these categories. Microscopically, the original microstructure of the bone tissue, both compact and cancellous, is well preserved in all the studied samples, with differences in cavity fillings, distribution of microcracks, and presence of Fe oxides in the diverse bone types. The bone composition and mineralogy correspond to fluorapatite. Differences in color, mineralization degree and geochemistry can be interpreted in terms of different fossilization paths, from burial at the seafloor to exposure in the present-day desert environment. The fossilization paths are strongly conditioned by the factors controlling the interplay of the mechanisms of apatite dissolution-recrystallization and dolomite precipitation (formation of carbonate concretions) as well as the fixation of iron in finely disseminated sulfides in the very early stages of fossilization.

Published

2021