Your search keyword '"Abis, Beniamino"' showing total 8 results

1. SAR, SARin, RDSAR and FF-SAR Altimetry Processing on Demand for Cryosat-2, Sentinel-3 & Sentinel-6 at ESA's Altimetry Virtual Lab.

Author

Benveniste, Jérôme, Dinardo, Salvatore, Fenoglio-Marc, Luciana, Buchhaupt, Christopher, Scagliola, Michele, Passaro, Marcello, Nielsen, Karina, Restano, Marco, Ambrózio, Américo, Sabatino, Giovanni, Orrù, Carla, and Abis, Beniamino

Subjects

RADAR altimetry, SARIN, ALTIMETRY, INDUSTRIAL research

Abstract

This paper presents the RDSAR, SAR/SARin & FF-SAR altimetry processors available in the ESA Altimetry Virtual Lab (AVL) hosted on the EarthConsole® platform. An overview on processors and features as well as preliminary analyses using AVL output data are reported to demonstrate the quality of the ESA Altimetry Virtual Lab altimetry services. Soon additional processors from ESA research contracts will be added to the AVL portfolio to continue providing innovative solutions to the radar altimetry community. [ABSTRACT FROM AUTHOR]

Published

2024

2. Tipping points in the biosphere

Author

Armstrong McKay, David I., Sakschewski, Boris, Roman-Cuesta, Rosa M., Dakos, Vasilis, Flores, Bernardo M., Hessen, Dag O., Hirota, Marina, Kéfi, Sonia, Obura, David, Reyer, Christopher P.O., Staver, A.C., Thom, Dominik, Abis, Beniamino, do Amaral, Cibele, Andersen, Tom, Bathiany, S., Beaugrand, Gregory, Blenckner, Thorsten, Brovkin, Victor, Berdugo, Miguel, Delgado-Baquerizo, Manuel, Dexter, Kyle G., Drüke, Markus, Duke, Norman C., Friess, Daniel A., Silveira, Jorge Alfredo Herrera, Bill-Weilandt, Alina, Guirado, Emilio, Holmgren, M., Kosten, Sarian, Lovelock, Catherine E., Mayor, Angeles G., Mayor, Daniel J., McField, Melanie, Meerhoff, Mariana, Muñiz-Castillo, Aarón Israel, Niiranen, Susa, Paton, Steven, Pearce-Kelly, Paul, Pueyo Estaún, Yolanda, Rocha, Juan Carlos, Romagnoni, Giovanni, Sanabria-Fernandez, Jose A., Sguotti, Camilla, Spears, Bryan M., Staal, Arie, Stevens, Nicola, Tarling, Geraint A., Wiltshire, Andy J., Armstrong McKay, David I., Sakschewski, Boris, Roman-Cuesta, Rosa M., Dakos, Vasilis, Flores, Bernardo M., Hessen, Dag O., Hirota, Marina, Kéfi, Sonia, Obura, David, Reyer, Christopher P.O., Staver, A.C., Thom, Dominik, Abis, Beniamino, do Amaral, Cibele, Andersen, Tom, Bathiany, S., Beaugrand, Gregory, Blenckner, Thorsten, Brovkin, Victor, Berdugo, Miguel, Delgado-Baquerizo, Manuel, Dexter, Kyle G., Drüke, Markus, Duke, Norman C., Friess, Daniel A., Silveira, Jorge Alfredo Herrera, Bill-Weilandt, Alina, Guirado, Emilio, Holmgren, M., Kosten, Sarian, Lovelock, Catherine E., Mayor, Angeles G., Mayor, Daniel J., McField, Melanie, Meerhoff, Mariana, Muñiz-Castillo, Aarón Israel, Niiranen, Susa, Paton, Steven, Pearce-Kelly, Paul, Pueyo Estaún, Yolanda, Rocha, Juan Carlos, Romagnoni, Giovanni, Sanabria-Fernandez, Jose A., Sguotti, Camilla, Spears, Bryan M., Staal, Arie, Stevens, Nicola, Tarling, Geraint A., and Wiltshire, Andy J.

Abstract

This chapter assesses scientific evidence for tipping points across the biosphere, which comprises Earth’s ecosystems. Human-driven habitat loss, pollution, exploitation and, increasingly, climate change are degrading ecosystems across the planet, some of which can pass tipping points beyond which a ‘regime shift’ to an alternative (and often less diverse or beneficial) ecosystem state occurs.Evidence for tipping points emerges across many biomes. In forests,large parts of the Amazon rain forest could tip to degraded forest or impoverished savanna, while tipping in boreal forests is possible but more uncertain, and whether current temperate forest disturbance could lead to tipping is unclear. In open savannas and drylands,drying could lead to desertification in some areas, while in others encroachment by trees and shrubs could see these biodiverse ecosystems shift to a forested or degraded state. Nutrient pollution and warming can trigger lakes to switch to an algae-dominated low-oxygen state. Coral reefs are already experiencing tipping points, as more frequent warming-driven bleaching events, along with pollution,extreme weather events and diseases, tip them to degraded algae-dominated states. Mangroves and sea grasses are at risk of regional tipping, along with kelp forests, marine food webs and some fisheries,which are known to be able to collapse.Together, these tipping points threaten the livelihoods of millions of people, and some thresholds are likely imminent. Stabilising climate is critical for reducing the likelihood of widespread ecosystem tipping points, but tackling other pressures can also help increase ecological resilience, push back tipping and support human well being.

Published

2023

3. A New Fully-Focused SAR Altimetry Processor in the ESA G-POD SARvatore Family: Validation and Applications on Inland Waters

Author

Nielsen, Karina, Altiparmaki, Ourania, Fenoglio-Marc, Luciana, Passaro, Marcello, Bercher, Nicolas, Scagliola, Michele, Abis, Beniamino, Fornari, Marco, Restano, Marco, and Benveniste, J��r��me

Abstract

Satellite altimetry has successfully been applied to derive water level time series over lakes and rivers for many years. In the last decade major advancement within the field have been achieved. The SAR altimetry era, initiated with the launch of CryoSat-2, has made it possible to measure much smaller targets more accurately. The standard 20 Hz radar altimetry products generally allow to study targets down to a few hundred meters in optimal conditions. However, recent advancement in the low-level data processing, the Fully-Focused SAR (FFSAR) technique, where the footprint in the along-track direction can be as small as a few meters, has made it possible to measure the water level of even smaller targets. FFSAR processed data from CryoSat-2 in SAR mode is made freely available by ESA through a newly integrated service on the Grid Processing on Demand (G-POD) platform, within the SARvatore Family of custom processors, where the user can order data from an area and specify various parameters to be applied in the processing. The FFSAR processor has been developed within the ESA ESTEC Sentinel-6 Project and adapted to CryoSat-2 for verification and validation purposes. Here we demonstrate the value of FFSAR and evaluate the FFSAR product obtained from the ESA G-POD service over different inland water targets. The evaluation and validation is done via in situ water level data, external processed FFSAR data, unfocused SAR data and laser altimetry data from ICESat-2. More specific, we perform an evaluation over the narrow ( < 100 m) American Rivers: Red River, Little River, and Canadian River located in the Mississippi basin. Where we compare the water level based on different retracker e.g. ALES+ and threshold retrackers. We make a joint water level time series by considering data from CryoSat-2 and ICESat-2 over a reach, and validate the results against in situ data. Preliminary results show that we can capture the main part of the water level signal. Over the Elbe River, we compare the FFSAR based river water levels with results based on unfocused SAR processing and in situ gauges. We extend our analysis with a case study conducted over the Lake IJssel which is located in The Netherlands and covers an area of approximately 1100 km2. We examine the performance of the G-POD processor by evaluating the FFSAR lake height estimates using externally processed FFSAR data that have been validated against in situ data.

Published

2021

4. Multiple tree-cover states in the earth system

Author

Abis, Beniamino

Abstract

In this dissertation I examine the existence of multiple stable treecover states of the Earth’s forest ecosystems, with a primary focus on the boreal region. Combining remotely-sensed observations, data analysis, and conceptual models, I identify areas with alternative vegetation states under the same environmental conditions, and I explore their possible dynamics under current and future conditions. In recent years, it has been found that the distributions of remotely sensed tree cover in boreal and tropical ecosystems have three distinct modes, corresponding to treeless, open woodland, and forest states. In light of this pattern, it has been suggested that these modes reflect the presence of alternative tree-cover states. As a response to climate change, these ecosystems could undergo critical regime shifts. For the tropics, it has been shown that a positive feedback between fire and vegetation can act as switch between the three states. For the boreal forest, it has been shown that the observed multimodality is not caused by temperature and precipitation patterns. In the first part of this thesis, by means of generalised additive models, I show that the relationship between tree cover and eight remotely-sensed environmental variables varies within the boreal region. Using a classification, I identify areas which exhibit alternative tree-cover states under similar environmental conditions. These regions show a reduced resilience and can shift between states. In the second part of the thesis, I develop and employ a conceptual model to show that tree-cover multistability in the boreal region can emerge through competition between species with different evolutionary traits. By forcing the model with varying permafrost conditions, I show that the asymmetry in tree-species distribution between North America and Eurasia could be due to permafrost presence. In the third part of the thesis, employing projected environmental conditions from the Representative Concentration Pathway (RCP) 2.6 and 8.5 scenarios, I identify potentially multistable areas during the last decade of the 21st century. By including a simple effect of CO2 on plant growth in the conceptual model, I simulate the dynamics of multistable zones under projected environmental conditions. I show that the two scenarios exhibit opposite trends regarding the extent of multistable areas, and that the resilience of Eurasian species might increase, while North American forests might lose stability. In each part of this thesis, I consider limits and advantages of the tools at hand, implying that only through their combined use we can advance our knowledge of tree-cover multistability and improve the representation of the boreal forest in climate models.

Published

2018

5. Alternative tree‐cover states of the boreal ecosystem: A conceptual model

Author

Abis, Beniamino, primary and Brovkin, Victor, additional

Published

2019

6. Environmental conditions for alternative tree-cover states in high latitudes

Author

Abis, Beniamino and Brovkin, Victor

Subjects

lcsh:Geology, lcsh:QH501-531, lcsh:QH540-549.5, lcsh:QE1-996.5, lcsh:Life, lcsh:Ecology

Abstract

Previous analysis of the vegetation cover from remote sensing revealed the existence of three alternative modes in the frequency distribution of boreal tree cover: a sparsely vegetated treeless state, an open woodland state, and a forest state. Identifying which are the regions subject to multimodality, and assessing which are the main factors underlying their existence, is important to project future change of natural vegetation cover and its effect on climate.We study the link between the tree-cover fraction distribution and eight globally observed environmental factors: mean annual rainfall, mean minimum temperature, growing degree days above 0 °C, permafrost distribution, mean spring soil moisture, wildfire occurrence frequency, soil texture, and mean thawing depth. Through the use of generalised additive models, conditional histograms, and phase-space analysis, we find that environmental conditions exert a strong control over the tree-cover distribution, uniquely determining its state among the three dominant modes in ∼ 95 % of the cases. Additionally, we find that the link between individual environmental variables and tree cover is different within the four boreal regions considered here, namely eastern North Eurasia, western North Eurasia, eastern North America, and western North America. Furthermore, using a classification based on rainfall, minimum temperatures, permafrost distribution, soil moisture, wildfire frequency, and soil texture, we show the location of areas with potentially alternative tree-cover states under the same environmental conditions in the boreal region. These areas, although encompassing a minor fraction of the boreal area ( ∼ 5 %), correspond to possible transition zones with a reduced resilience to disturbances. Hence, they are of interest for a more detailed analysis of land–atmosphere interactions.

Published

2017

7. Environmental conditions for alternative tree-cover states in high latitudes

Author

Abis, Beniamino, primary and Brovkin, Victor, additional

Published

2017

8. Environmental Conditions for Alternative Tree Cover States in High Latitudes.

Author

Abis, Beniamino and Brovkin, Victor

Subjects

GROUND vegetation cover, LATITUDE, PHYTOGEOGRAPHY, CLIMATE change, PERMAFROST ecosystems

Abstract

Previous analysis of the vegetation cover from remote sensing revealed the existence of three alternative modes in the frequency distribution of boreal tree cover: a sparsely vegetated treeless state, an open woodland state, and a forest state. Identifying which are the regions subject to multimodality, and assessing which are the main factors underlying their existence, is important to project future change of natural vegetation cover and its effect on climate. We study the impact on the tree cover fraction distribution (TCF) of eight globally-observed environmental factors: mean annual rainfall (MAR), mean minimum temperature (MTmin), growing degree days above 0°C (GDD0), permafrost distribution (PZI), mean spring soil moisture (MSSM), wildfire occurrence frequency (FF), soil texture (ST), and mean thawing depth (MTD). Through the use of generalised additive models, conditional histograms, and phase-space analysis, we find that environmental conditions exert a strong control over the tree cover distribution, generally uniquely determining its state. Additionally, we find that the relationship between tree cover and environment is different within the four boreal regions here considered, namely Eastern North Eurasia, Western North Eurasia, Eastern North America, and Western North America. Furthermore, using a classification based on MAR, MTmin, MSSM, PZI, FF, and ST, we show the location of areas with potentially alternative tree cover states under the same environmental conditions in the boreal region. These areas, although encompassing a minor fraction of the boreal area (~5%), are of interest for a more detailed analysis of land-atmosphere interactions. [ABSTRACT FROM AUTHOR]

Published

2016