Your search keyword '"Pavón-Carrasco, F. J."' showing total 3 results

1. La datación arqueomagnética. Fundamentos, éxitos y limitaciones.

Author

Carrancho, Á., Gómez-Paccard, M., and Pavón-Carrasco, F. J.

Subjects

REGIONAL development, PALEOMAGNETISM, VOLCANIC ash, tuff, etc., GEOMAGNETISM, COMBUSTION, GEOPHYSICISTS

Abstract

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Published

2022

2. Rapid Intensity Decrease During the Second Half of the First Millennium BCE in Central Asia and Global Implications.

Author

Bonilla‐Alba, R., Gómez‐Paccard, M., Pavón‐Carrasco, F. J., Río, J. del, Beamud, E., Martínez‐Ferreras, V., Gurt‐Esparraguera, J. M., Ariño‐Gil, E., Palencia‐Ortas, A., Martín‐Hernández, F., Chauvin, A., and Osete, M. L.

Subjects

PALEOMAGNETISM, GEOMAGNETISM, THERMOREMANENT magnetization, MAGNETIC properties of rocks, IRON Age

Abstract

Recent paleomagnetic studies have shown that important short‐lived intensity fluctuations occurred during the first millennium BCE. However, the knowledge of the spatial and temporal extension of these features is still limited by the scarce availability of robust data. In this study we focus on the study of the intensity decrease that took place in Central Asia during the second half of the 1st millennium BCE after the high intensities that characterized the Levantine Iron Age Anomaly. Since previous archeointensities available for this period and region were obtained without accomplishing modern standards of quality, we present here new archeointensities that are derived from classical Thellier and Thellier experiments, including partial thermoremanent magnetization (pTRM) checks, thermoremanent magnetization (TRM) anisotropy and cooling rate corrections at the specimen level. The new 51 archeointensities, together with previous archeointensities, have been used to present a new local paleosecular variation curve for Central Asia. The results confirm the existence of an important geomagnetic field intensity decrease in South Uzbekistan from the 4th century BCE to the end of the 1st century BCE associated with rates of changes up to −15 μT/century. A critical analysis of the archeointensity global database indicates that this feature was present at continental scale, from Western Europe to Central Asia. However, this trend is not identified in other regions such as Japan or Mexico. Finally, the comparison with the dipole moment derived from recent global geomagnetic field reconstructions suggests a strong influence of non‐dipolar sources upon this continental intensity feature. Plain Language Summary: The Earth's magnetic field (also called the geomagnetic field) is continuously changing over time and space. Since the 19th century, the behavior of the geomagnetic field is known through direct observations performed in geomagnetic observatories and satellites. However, the only way to recover past geomagnetic field in ancient times is through paleomagnetic and archeomagnetic studies. In particular, archeomagnetism is the study of heated archeological materials, which include ferromagnetic particles acting as a compass and recording the geomagnetic field direction and strength at a certain time. When the archeological material cools down the ferromagnetic particles save the direction and intensity, like a photograph of the ancient geomagnetic field. Nowadays, there are very few archeomagnetic studies dealing with archeological materials from Central Asia. In this work, we present the variation of the geomagnetic field intensity between 600 BCE–600 CE in Uzbekistan deduced from a complete archeomagnetic investigation of 70 pottery fragments. The results confirm a rapid variation of geomagnetic field strength between 400 BCE and 100 BCE–1CE. To determine the spatial expression of this feature, we compared the obtained trend for Central Asia with the geomagnetic field intensity evolution in other regions of the world. Key Points: We present 51 new thermoremanent magnetization‐anisotropy corrected archeointensities for South UzbekistanAn important decrease in intensity is observed between 400 BCE and 100 BCE–1 CE, probably associated with non‐dipolar sourcesSimilar intensity V‐shaped trends are observed at continental scale [ABSTRACT FROM AUTHOR]

Published

2021

3. Updated Iberian Archeomagnetic Catalogue: New Full Vector Paleosecular Variation Curve for the Last Three Millennia.

Author

Molina‐Cardín, A., Campuzano, S. A., Osete, M. L., Rivero‐Montero, M., Pavón‐Carrasco, F. J., Palencia‐Ortas, A., Martín‐Hernández, F., Gómez‐Paccard, M., Chauvin, A., Guerrero‐Suárez, S., Pérez‐Fuentes, J. C., McIntosh, G., Catanzariti, G., Sastre Blanco, J. C., Larrazabal, J., Fernández Martínez, V. M., Álvarez Sanchís, J. R., Rodríguez‐Hernández, J., Martín Viso, I., and Garcia i Rubert, D.

Subjects

PALEOMAGNETISM, STATISTICAL bootstrapping, GEOMAGNETISM, IRON Age

Abstract

In this work, we present 16 directional and 27 intensity high‐quality values from Iberia. Moreover, we have updated the Iberian archeomagnetic catalogue published more than 10 years ago with a considerable increase in the database. This has led to a notable improvement of both temporal and spatial data distribution. A full vector paleosecular variation curve from 1000 BC to 1900 AD has been developed using high‐quality data within a radius of 900 km from Madrid. A hierarchical bootstrap method has been followed for the computation of the curves. The most remarkable feature of the new curves is a notable intensity maximum of about 80 μT around 600 BC, which has not been previously reported for the Iberian Peninsula. We have also analyzed the evolution of the paleofield in Europe for the last three thousand years and conclude that the high maximum intensity values observed around 600 BC in the Iberian Peninsula could respond to the same feature as the Levantine Iron Age Anomaly, after travelling westward through Europe. Plain language summary: Knowledge of the Earth's magnetic field plays an important role on the understanding of its dynamics. By measuring certain rocks or archeological objects from around the world, we can determine the field's shape and intensity in former times. Knowing its evolution is essential to understand how this field is generated, how it has varied through time and how it may behave in the future. In this work, we present new measurements of the magnetic field from the Iberian Peninsula that provide useful constraints on the magnetic field for archeological times that currently lack information. We have updated the compilation of Iberian data for the last 3,000 years and calculated a new reference curve for the magnetic field for this region. We have found that the magnetic field was particularly intense in the Iberian Peninsula about 2,600 years ago. By comparing this result with data from Europe and the Middle East, we observe that this high intensity has been moving from east to west through southern Europe. This feature is probably related with the rapid intensity change (the geomagnetic spike) recently discovered in the Levantine region. Key Points: We have obtained 16 archeomagnetic directions and 27 high‐quality archeointensity dataA new full vector paleosecular variation curve for the last three millennia in Iberia is presentedThe new curve shows a high‐intensity maximum around 600 BC that might be related to the Levantine Iron Age Anomaly moving through Europe [ABSTRACT FROM AUTHOR]

Published

2018