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1. Looking for the key to preservation of fossil marine vertebrates in the Pisco Formation of Peru: new insights from a small dolphin skeleton

Author

Olivier Lambert, Giulia Bosio, Claudio Di Celma, Jennifer Pike, Alberto Collareta, Elisa Malinverno, Giovanni Bianucci, Karen Gariboldi, Anna Gioncada, Mario Urbina, Gioncada, A, Gariboldi, K, Collareta, A, Di Celma, C, Bosio, G, Malinverno, E, Lambert, O, Pike, J, Urbina, M, and Bianucci, G

Subjects

Fossilization, 010506 paleontology, Taphonomy, Stratigraphy, Dolomite, Geochemistry, Phosphatization, engineering.material, 010502 geochemistry & geophysics, Neogene, 01 natural sciences, chemistry.chemical_compound, Geochemistry and Petrology, Concretion, Marine vertebrate, Pisco Formation, Marine vertebrates, Early diagenesis, 0105 earth and related environmental sciences, Paleontology, Geology, Diagenesis, Marine vertebrates, Taphonomy, Pisco Formation, Fossilization, Phosphatization, Early diagenesis, chemistry, engineering, Carbonate

Abstract

The upper Neogene Pisco Formation of Peru is known worldwide as one of the most significant Cenozoic\ud marine vertebrate Konservatt-Lagerstätten, even featuring cetacean specimens that retain remains of soft tissues or\ud stomach contents. Previous works showed that biomediated precipitation of dolomite concretions around large-sized\ud decaying carcasses was one of the most relevant processes responsible for exceptional fossil preservation. In turn, little is\ud known about the modes of fossilization of well-preserved small-sized vertebrates, which are rather common in the Pisco\ud Formation, but mostly do not exhibit dolomite concretions. We report on a cetacean specimen, identified as belonging\ud to the extinct short-snouted, small dolphin species Brachydelphis mazeasi (Pontoporiidae), preserved within a late\ud Miocene sandy deposit at the site of Pampa Corre Viento. This specimen consists of a moderately disarticulated partial\ud skeleton exhibiting well-mineralized bones; it is not enclosed within a dolomite concretion, being however delimited\ud by an evident dark boundary in the host sediment. Scanning electron microscopy and microanalytical investigations\ud identify Mn-oxides and apatite as early diagenetic minerals around the skeleton. We argue that a rapid burial of the\ud specimen was pivotal for the preservation of the bones, and allowed the early establishment of anoxic processes for\ud degradation of organic matter. Coupled with availability of P in porewater, the reducing conditions and the lowered\ud pH allowed precipitation of Ca-phosphate while increasing Mn solubility close to the pontoporiid carcass. Mn-oxides\ud precipitated at the redox boundary, the latter defining the outer edge of the volume of sediment affected by altered\ud chemical conditions due to the decaying processes. The permeability of the sediment and the small size of the carcass\ud were possible factors unfavorable to extensive sulfate reduction, thus preventing the formation of a dolomite concretion\ud and allowing bone phosphatization. This record emphasizes the role of conditions favorable to bone mineralization in\ud absence of an isolating carbonate concretion, in cases of high quality preservation of small-sized vertebrates observed\ud in the Pisco Formation. The observation of patterns in the distribution of diagenetic minerals in the sediment enclosing\ud vertebrate remains without, or with limited carbonate concretions provides insights into early taphonomic processes.

Published

2018