Your search keyword '"Prieto, Juan F."' showing total 10 results

1. Modeling the two- and three-dimensional displacement field in Lorca, Spain, subsidence and the global implications

Author

Fernandez, Jose, Prieto, Juan F., Escayo, Joaquin, Camacho, Antonio G., Luzón, Francisco, Tiampo, Kristy F., Palano, Mimmo, Abajo, Tamara, Pérez, Enrique, Velasco, Jesus, Herrero, Tomas, Bru, Guadalupe, Molina, Iñigo, López, Juan, Rodríguez Velasco, Gema, Gómez, Israel, Mallorquí, Jordi J., Fernandez, Jose, Prieto, Juan F., Escayo, Joaquin, Camacho, Antonio G., Luzón, Francisco, Tiampo, Kristy F., Palano, Mimmo, Abajo, Tamara, Pérez, Enrique, Velasco, Jesus, Herrero, Tomas, Bru, Guadalupe, Molina, Iñigo, López, Juan, Rodríguez Velasco, Gema, Gómez, Israel, and Mallorquí, Jordi J.

Abstract

Land subsidence associated with overexploitation of aquifers is a hazard that commonly affects large areas worldwide. The Lorca area, located in southeast Spain, has undergone one of the highest subsidence rates in Europe as a direct consequence of long-term aquifer exploitation. Previous studies carried out on the region assumed that the ground deformation retrieved from satellite radar interferometry corresponds only to vertical displacement. Here we report, for the first time, the two- and three-dimensional displacement field over the study area using synthetic aperture radar (SAR) data from Sentinel-1A images and Global Navigation Satellite System (GNSS) observations. By modeling this displacement, we provide new insights on the spatial and temporal evolution of the subsidence processes and on the main governing mechanisms. Additionally, we also demonstrate the importance of knowing both the vertical and horizontal components of the displacement to properly characterize similar hazards. Based on these results, we propose some general guidelines for the sustainable management and monitoring of land subsidence related to anthropogenic activities, Ministerio de Economía y Competitividad (MINECO), Fac. de Ciencias Matemáticas, TRUE, pub

Published

2023

2. InSAR deformation monitoring and Defsour® deformation interpretation

Author

Hu, Zhongbo, Fernandez, Jose, Camacho, Antonio G., Escayo, Joaquin, Du, Sen, Prieto, Juan F., Rodríguez, Susana, Davoise, D., Torné, Montserrat, Balaguera, A., Seivane, Helena, Schimmel, Martin, Hu, Zhongbo, Fernandez, Jose, Camacho, Antonio G., Escayo, Joaquin, Du, Sen, Prieto, Juan F., Rodríguez, Susana, Davoise, D., Torné, Montserrat, Balaguera, A., Seivane, Helena, and Schimmel, Martin

Abstract

The natural hazards, like volcanic landslides and seismic activity, or induced by human activity (e.g. water extraction, mining,...), can have important effects in infrastructures and environment, producing great economic losses and threatening human lives. The occurrence of these phenomena are mostly related to areas that are susceptible to subsidence. Subsidence can result in permanent land loss, damage to infrastructure and buildings, and damage to the environment. Therefore, improving our understanding of the processes associated with hazards is crucial for developing systems that monitor, evaluate and predict hazards, and that aid decision makers during a crisis. Many of these hazards manifest themselves previously through deformations of the land and infrastructures. Synthetic Aperture Radar Interferometry (DInSAR) has been proved its unprecedented ability to detect millimetric displacements on the Earth surface over time scales of decades. An advanced interpretation tool Defsour, developed by the group in IGEO-CSIC, can model InSAR time series deformation data to constrain the location and geometry of the deformation sources as well as its temporal evolution. 3-D arbitrary sources for pressure and fractures/dislocations (strike-slip, dip-slip, and tensile) are adjusted. The Defsour software can automatically determine the number, nature, position, and 3D geometry of the causative source structures. In this presentation, the basic principles and case studies of the applications related to the deformation monitoring (InSAR) and deformation intepretation tool (Defsour) will be discussed and presented.

Published

2023

3. Shallow magmatic intrusion evolution below La Palma before and during the 2021 eruption

Author

Fernández, José, Escayo, Joaquin, Camacho, Antonio G., Palano, Mimmo, Prieto, Juan F., Hu, Zhongbo, Samsonov, Sergey V., Tiampo, Kristy F., Ancochea Soto, Eumenio, Fernández, José, Escayo, Joaquin, Camacho, Antonio G., Palano, Mimmo, Prieto, Juan F., Hu, Zhongbo, Samsonov, Sergey V., Tiampo, Kristy F., and Ancochea Soto, Eumenio

Abstract

La Palma, Canary Islands, underwent volcanic unrest which culminated in its largest historical eruption. We study this unrest along 2021 using Interferometric Synthetic Aperture Radar (InSAR) and a new improved interpretation methodology, comparing achieved results with the crustal structure. We reproduce the final phase of La Palma volcanic unrest, highligthing a shallow magma accumulation which begins about 3.5 months before the eruption in a crustal volume charactherized by low density and fractured rocks. Our modeling, together with our improved pictures of the crustal structure, allows us to explain the location and characteristics of the eruption and to detect failed eruption paths. These can be used to explain post-eruptive phenomena and hazards to the local population, such as detected gases anomalies in La Bombilla and Puerto Naos. Our results have implications for understanding volcanic activity in the Canaries and volcano monitoring elsewhere, helping to support decision-making and providing significant insights into urban and infrastructure planning in volcanic areas., Agencia Estatal de Investigación, Depto. de Mineralogía y Petrología, Fac. de Ciencias Geológicas, TRUE, pub

Published

2022

4. Detection of volcanic unrest onset in La Palma, Canary Islands, evolution and implications

Author

José Fernández, José, Escayo, Joaquin, Hu, Zhongbo, Camacho, A.G., Samsonov, Sergey V., Prieto, Juan F., Tiampo, Kristy F., Palano, Mimmo, Mallorquí, Jordi J., Ancochea Soto, Eumenio, José Fernández, José, Escayo, Joaquin, Hu, Zhongbo, Camacho, A.G., Samsonov, Sergey V., Prieto, Juan F., Tiampo, Kristy F., Palano, Mimmo, Mallorquí, Jordi J., and Ancochea Soto, Eumenio

Abstract

La Palma island is one of the highest potential risks in the volcanic archipelago of the Canaries and therefore it is important to carry out an in-depth study to define its state of unrest. This has been accomplished through the use of satellite radar observations and an original state-of-the-art interpretation technique. Here we show the detection of the onset of volcanic unrest on La Palma island, most likely decades before a potential eruption. We study its current evolution seeing the spatial and temporal changing nature of activity at this potentially dangerous volcano at unprecedented spatial resolutions and long time scales, providing insights into the dynamic nature of the associated volcanic hazard. The geodetic techniques employed here allow tracking of the fluid migration induced by magma injection at depth and identifying the existence of dislocation sources below Cumbre Vieja volcano which could be associated with a future flank failure. Therefore they should continue being monitored using these and other techniques. The results have implications for the monitoring of steep-sided volcanoes at oceanic islands., Ministerio de Ciencia e Innovación (MICINN), Ministerio de Economía y Competitividad (MINECO), Consejo Superior de Investigaciones Científicas (CSIC), Depto. de Mineralogía y Petrología, Fac. de Ciencias Geológicas, TRUE, pub

Published

2021

5. Upgraded GROWTH 3.0 software for structural gravity inversion and application to El Hierro (Canary Islands)

Author

Camacho, A.G., Prieto, Juan F., Aparicio, Alfredo, Ancochea Soto, Eumenio, Fernández, José, Camacho, A.G., Prieto, Juan F., Aparicio, Alfredo, Ancochea Soto, Eumenio, and Fernández, José

Abstract

GROWTH 3.0 is a software package to determine the subsurface 3D density distribution that adjust discrete gravity anomaly values determined from gravity observations. The software uses very general assumptions and quite automatically determines the 3D density structures described by the aggregation of thousands of small rectangular prisms. A previous version of the software was published in 2011. However, methodological developments and computational technical evolution made it necessary to upgrade the software to include new advances and recent improvements in the inversion methodology (automatic determination of density contrasts, background medium with downward density increase, etc.), and a change in the computer operating system (from Windows XP, which was compatible with the 2011 version, to Windows 10 Pro for the current version). Here we describe the new upgraded version of the software package (which can be downloaded free), its use and application, using the study of El Hierro (Canary Islands) as a test case from which to obtain a 3D density model of its crustal structure. We also give a brief geological and volcanological interpretation., Ministerio de Ciencia e Innovación (MICINN), Consejo Superior de Investigaciones Científicas (CSIC), Depto. de Mineralogía y Petrología, Fac. de Ciencias Geológicas, TRUE, pub

Published

2021

6. Detection of volcanic unrest onset in La Palma, Canary Islands, evolution and implications

Author

Universitat Politècnica de Catalunya. Departament de Teoria del Senyal i Comunicacions, Universitat Politècnica de Catalunya. RSLAB - Grup de Recerca en Teledetecció, Escayo Menéndez, Joaquín, Hu, Zhongbo, Mallorquí Franquet, Jordi Joan, Fernández, José, Camacho, Antonio G, Samsonov, Sergey V., Prieto, Juan F., Tiampo, Kristy F., Palanno, Mimmo, Ancochea, Eumenio, Universitat Politècnica de Catalunya. Departament de Teoria del Senyal i Comunicacions, Universitat Politècnica de Catalunya. RSLAB - Grup de Recerca en Teledetecció, Escayo Menéndez, Joaquín, Hu, Zhongbo, Mallorquí Franquet, Jordi Joan, Fernández, José, Camacho, Antonio G, Samsonov, Sergey V., Prieto, Juan F., Tiampo, Kristy F., Palanno, Mimmo, and Ancochea, Eumenio

Abstract

La Palma island is one of the highest potential risks in the volcanic archipelago of the Canaries and therefore it is important to carry out an in-depth study to define its state of unrest. This has been accomplished through the use of satellite radar observations and an original state-of-the-art interpretation technique. Here we show the detection of the onset of volcanic unrest on La Palma island, most likely decades before a potential eruption. We study its current evolution seeing the spatial and temporal changing nature of activity at this potentially dangerous volcano at unprecedented spatial resolutions and long time scales, providing insights into the dynamic nature of the associated volcanic hazard. The geodetic techniques employed here allow tracking of the fluid migration induced by magma injection at depth and identifying the existence of dislocation sources below Cumbre Vieja volcano which could be associated with a future flank failure. Therefore they should continue being monitored using these and other techniques. The results have implications for the monitoring of steep-sided volcanoes at oceanic islands., This research was mainly funded by the Spanish Ministerio de Ciencia, Innovación y Universidades research project DEEP-MAPS, Grant Agree-ment Number RTI2018-093874-B-I00. It was also partially supported by the CSIC project 201530E019, and the project GEOSIR, Grant Agreement AYA2010-17448 from the Spanish Ministerio de Ciencia e Innovación and the MINECO research project CGL2017-86241-R. This work represents a contribution to CSIC Thematic Interdisciplinary Platform PTI TELEDETECT., Peer Reviewed, Postprint (published version)

Published

2021

7. Geodetic Study of the 2006–2010 Ground Deformation in La Palma (Canary Islands): Observational Results

Author

Escayo, Joaquin, Fernández, José, Prieto, Juan F., Camacho, Antonio G., Palano, Mimmo, Aparicio, Alfredo, Rodríguez Velasco, Gema, Ancochea Soto, Eumenio, Escayo, Joaquin, Fernández, José, Prieto, Juan F., Camacho, Antonio G., Palano, Mimmo, Aparicio, Alfredo, Rodríguez Velasco, Gema, and Ancochea Soto, Eumenio

Abstract

La Palma is one of the youngest of the Canary Islands, and historically the most active. The recent activity and unrest in the archipelago, the moderate seismicity observed in 2017 and 2018 and the possibility of catastrophic landslides related to the Cumbre Vieja volcano have made it strongly advisable to ensure a realistic knowledge of the background surface deformation on the island. This will then allow any anomalous deformation related to potential volcanic unrest on the island to be detected by monitoring the surface deformation. We describe here the observation results obtained during the 2006–2010 period using geodetic techniques such as Global Navigation Satellite System (GNSS), Advanced Differential Synthetic Aperture Radar Interferometry (A-DInSAR) and microgravimetry. These results show that, although there are no significant associated variations in gravity, there is a clear surface deformation that is spatially and temporally variable. Our results are discussed from the point of view of the unrest and its implications for the definition of an operational geodetic monitoring system for the island, Ministerio de Ciencia e Innovación (MICINN), Consejo Superior de Investigaciones Científicas (CSIC), Depto. de Mineralogía y Petrología, Fac. de Ciencias Geológicas, TRUE, pub

Published

2020

8. Deep volcanic morphology below Lanzarote, Canaries, from gravity inversion: New results for Timanfaya and implications

Author

Camacho, Antonio G., Prieto, Juan F., Ancochea Soto, Eumenio, José Fernández, José, Camacho, Antonio G., Prieto, Juan F., Ancochea Soto, Eumenio, and José Fernández, José

Abstract

The deep roots of oceanic island volcanoes are poorly known and geophysical models can help to constrain processes such as magma storage and transport before and during eruptions. Lanzarote, Canary Islands, is a volcanic island in post-erosional phase where, in the 18th century, one of the most important historical eruptions, considering duration and volume, of the Canary Islands took place in the Timanfaya area. To improve the knowledge on the structure of Lanzarote and in Timanfaya area, we carry out a gravity determination of the subsurface anomalous 3D density structure, using an improved quasi-automatic inversion methodology. The obtained model presents a 3D morphology of anomalous density bodies. We describe the improvements of the inversion methodology, the adjusted model and interpretative conclusions corresponding to the structure and the long-term cumulative magmatic plumbing system of the island. Three high-density sources are described as resulting in the inference of three main volcanic complexes: a large central complex (San Bartolomé) and two smaller complexes, one in the NE and a third smaller one located in the SW close to the Timanfaya area. The outcrops of Miocene lava flows from the center of the Island can be attributed to the top of the central intrusive model. We infer the local plumbing system for Timanfaya volcano area by means of strongly tilted successive branches of magma departing from the SW intrusive body. The structural results show no evidence of any magma chamber below Timanfaya as proposed by previous works. We also present a comparison of the gravity results and geological observations, showing different cases of correlation in the Island. They go from a good match between the gravity anomaly and the position of the central volcanic structure, to no anomaly associated to the fissural Quaternary volcanic activity., MINECO, CSIC, Depto. de Mineralogía y Petrología, Fac. de Ciencias Geológicas, TRUE, pub

Published

2019

9. Detailed multidisciplinary monitoring reveals pre- and co-eruptive signals at Nyamulagira volcano (North Kivu, Democratic Republic of Congo)

Author

Natural Sciences and Engineering Research Council of Canada, National Science Foundation (US), National Geographic Society, Smets, Benoît, d’Oreye, Nicolas, Kervyn, François, Kervyn, Matthieu, Albino, Fabien, Arellano, Santiago R., Bagalwa, Montfort, Balagizi, Charles, Carn, Simon A., Darrah, Thomas H., Fernández, José, Galle, Bo, González, Pablo J., Head, Elisabet, Karume, Katcho, Kavotha, Déogratias, Lukaya, François, Mashagiro, Niche, Mavonga, Georges, Norman, Patrik, Osodundu, Etoy, Pallero, José L. G., Prieto, Juan F., Samsonov, Sergey, Syauswa, Muhindo, Tedesco, Dario, Tiampo, Kristy, Wauthier, Christelle, Yalire, Mathieu M., Natural Sciences and Engineering Research Council of Canada, National Science Foundation (US), National Geographic Society, Smets, Benoît, d’Oreye, Nicolas, Kervyn, François, Kervyn, Matthieu, Albino, Fabien, Arellano, Santiago R., Bagalwa, Montfort, Balagizi, Charles, Carn, Simon A., Darrah, Thomas H., Fernández, José, Galle, Bo, González, Pablo J., Head, Elisabet, Karume, Katcho, Kavotha, Déogratias, Lukaya, François, Mashagiro, Niche, Mavonga, Georges, Norman, Patrik, Osodundu, Etoy, Pallero, José L. G., Prieto, Juan F., Samsonov, Sergey, Syauswa, Muhindo, Tedesco, Dario, Tiampo, Kristy, Wauthier, Christelle, and Yalire, Mathieu M.

Abstract

This paper presents a thorough description of Nyamulagira’s January 2010 volcanic eruption (North Kivu, Democratic Republic of Congo), based on a combination of field observation and ground-based and space-borne data. It is the first eruption in the Virunga Volcanic Province that has been described by a combination of several modern monitoring techniques. The 2010 eruption lasted 26 days and emitted ∼45.5 × 106 m3 of lava. Field observations divided the event into four eruptive stages delimited by major changes in effusive activity. These stages are consistent with those described by Pouclet (1976) for historical eruptions of Nyamulagira. Co-eruptive signals from ground deformation, seismicity, SO2 emission and thermal flux correlate with the eruptive stages. Unambiguous pre-eruptive ground deformation was observed 3 weeks before the lava outburst, coinciding with a small but clear increase in the short period seismicity and SO2 emission. The 3 weeks of precursors contrasts with the only precursory signal previously recognized in the Virunga Volcanic Province, the short-term increase of tremor and long period seismicity, which, for example, were only detected less than 2 h prior to the 2010 eruption. The present paper is the most detailed picture of a typical flank eruption of this volcano. It provides valuable tools for re-examining former—mostly qualitative—descriptions of historical Nyamulagira eruptions that occurred during the colonial period.

Published

2014

10. GNSS, Space Weather and TEC Special Features.

Author

Kos, Serdjo, Fernández, José, Kos, Serdjo, and Prieto, Juan F.

Subjects

Energy industries & utilities, History of engineering & technology, Technology: general issues, CID, COSMIC, Continuously Operating Reference Station (CORS), CubeSat observation, Differential Global Positioning System (DGPS), EIA, EPN, European Geostationary Navigation Overlay Service (EGNOS), Fractal Hausdorff dimension, GNSS, GNSS meteorology, GNSS time series analysis, GNSS-IR, GPS, GPS TEC, GPS/GNSS, Global Navigation Satellite Systems (GNSS), Global Positioning System (GPS), Ni-based superalloys, PCC, Precise Point Positioning (PPP), ROTI, Saastamoinen model of zenith tropospheric delay, Savitzky-Golay, South Atlantic Anomaly, TEC, antenna, attention mechanism, attribute-augmented, calibration, daytime, deep learning, detrending, diurnal evolution, dual-frequency carrier phase combination, dual-frequency pseudorange, equatorial and low-latitude ionosphere, fractal reconstruction, gravity wave, ground-truth data, international space station, ionogram, ionosphere, ionospheric corrections, ionospheric irregularity, ionospheric model, landslide displacement prediction, lightning, lithosphere-atmosphere-ionosphere coupling, mean fusion, microstructure, morphology, multi-GNSS, multi-frequency, multipath error, multisatellite combination, n/a, navigation positioning system, nighttime, phase delay, polynomial, positioning accuracy, radiation belts, radiation measurement, radio occultation observation, reliability method, scintillation, seasonal variation, seismic swarm, seismo-ionospheric coupling, signal-to-noise ratio, snow depth, soil moisture content, spatiotemporal analysis, statistical position equilibrium, surface meteorological data, tomography, total electron content, tropospheric error, volcanic activity, water vapor

Abstract

Summary: In the domain of electronic navigation, satellite navigation (GNSS) is one of the most important complex modern systems. GNSS is a key aspect of infrastructure which supports the development and improvement of power grid systems, banking operations, global transportation systems, and global communication systems. Today, GNSS requires the use of several positioning networks and sensors, such as radio networks and MEMS. The Earth's atmosphere, particularly the ionosphere and troposphere, can be seen as a huge laboratory where multiple processes and phenomena directly affecting the propagation of EM waves occur. Like all complex systems, GNSS technology has also gone through certain evolutionary stages. Factors affecting the future evolution of GNSS technology include the appearance of new signals and frequencies, complementary technologies in use, etc., but in the domain of GNSS technologies, it is essential to study the impact of space weather on GNSS systems. A key part of research related to GNSS technologies is the vertical TEC distribution and anomalies related to earthquakes and volcanic eruptions on Earth. There are many challenges that need to be addressed because they affect reliability, accuracy, and all other essential parameters of GNSS systems. It addresses some of these issues by publishing manuscripts which study GNSS risk assessment, different effects of space weather disturbances on the operation of GNSS systems, environmental impacts on the operation of GNSS systems, GNSS positioning error budgets, TEC special features in volcano eruptions, and similar topics.