CONICET | Buscador de Institutos y Recursos Humanos

The first magnetostratigraphic scales for the Jurassic through Early Cretaceousfrom the Southern Hemisphere have been constructed over the last decadesfrom marine sections in the Neuquén Basin. Paleomagnetic sites were tied toammonite zones in order to achieve well-refined ages of studied sections. Diverse field tests for the paleomagnetic stability proved the primary origin of isolated magnetizations. In the case of Upper Jurassic?Lower Cretaceous studies, magnetostratigraphic and biostratigraphic data were combined with cyclostratigraphy. Finally, polarities were tied to Andean ammonite zones and from their correlation with the standard zones, calibrated to the GTS2016 (Geomagnetic Polarity Time Scale 2016). For the Early Jurassic, a composite magnetostratigraphic scale was derived out of five sections spanning the Hettangian?Toarcian. The magnetostratigraphic scale portrays 16 reverse (Jr1?Jr16) and 16 normal (Jn1?Jn16) polarity zones that encompass at least 19 ammonite zones. A major difference between both scales rises in the Hettangianinvolving the Jr1?Jr3 polarity zones. For the Middle Jurassic, the resultantmagnetostratigraphy obtained in the Lajas Formation outlines a dominantly reverse polarity pattern. According to the correlation with the GTS2016, the studied section is assigned to the Lower-uppermost Middle Bathonian (Chrons M41 through M39). For the Late Jurassic?Early Cretaceous, the magnetostratigraphic scale obtained in the Vaca Muerta Formation comprises Subchrons M22r.2r through M15r, spanning the V. andesensis (Lower Tithonian)?S. damesi Zones (Upper Berriasian). The use of diverse chronostratigraphic tools such as biostratigraphy, magnetostratigraphy and cyclostratigraphy, enabled to determine with unprecedented precision the position of the Jurassic?Cretaceous boundary, as well as to assess durations of ammonite zones