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1. Using stable isotopes to inform water resource management in forested and agricultural ecosystems

Author

Scandellari, Francesca, Attou, Taha, Barbeta, Adrià, Bernhard, Fabian, D'Amato, Concetta, Dimitrova-Petrova, Katya, Donaldson, Amanda, Durodola, Oludare, Ferraris, Stefano, Floriancic, Marius G, Fontenla-Razzetto, Gabriela, Gerchow, Malkin, Han, Qiong, Khalil, Isis, Kirchner, James W, Kühnhammer, Kathrin, Liu, Qin, Llorens, Pilar, Magh, Ruth-Kristina, Marshall, John, Meusburger, Katrin, Oliveira, Aline Meyer, Muñoz-Villers, Lyssette, Pires, Sabrina Santos, Todini-Zicavo, Diego, van Meerveld, Ilja, Voigt, Claudia, Wirsig, Luise, Beyer, Matthias, Geris, Josie, Hopp, Luisa, Penna, Daniele, and Sprenger, Matthias

Subjects
Hydrology, Environmental Sciences, Earth Sciences, Clean Water and Sanitation, Agriculture, Ecosystem, Forests, Water Resources, Isotopes, Groundwater, Conservation of Water Resources, Stakeholders, Stable isotopes of water, Forest management, Agricultural management, Water resources management, Climate change
Abstract

Present and future climatic trends are expected to markedly alter water fluxes and stores in the hydrologic cycle. In addition, water demand continues to grow due to increased human use and a growing population. Sustainably managing water resources requires a thorough understanding of water storage and flow in natural, agricultural, and urban ecosystems. Measurements of stable isotopes of water (hydrogen and oxygen) in the water cycle (atmosphere, soils, plants, surface water, and groundwater) can provide information on the transport pathways, sourcing, dynamics, ages, and storage pools of water that is difficult to obtain with other techniques. However, the potential of these techniques for practical questions has not been fully exploited yet. Here, we outline the benefits and limitations of potential applications of stable isotope methods useful to water managers, farmers, and other stakeholders. We also describe several case studies demonstrating how stable isotopes of water can support water management decision-making. Finally, we propose a workflow that guides users through a sequence of decisions required to apply stable isotope methods to examples of water management issues. We call for ongoing dialogue and a stronger connection between water management stakeholders and water stable isotope practitioners to identify the most pressing issues and develop best-practice guidelines to apply these techniques.

Published
2024

8. The Demographics of Water: A Review of Water Ages in the Critical Zone

Author

Sprenger, Matthias, Stumpp, Christine, Weiler, Markus, Aeschbach, Werner, Allen, Scott T, Benettin, Paolo, Dubbert, Maren, Hartmann, Andreas, Hrachowitz, Markus, Kirchner, James W, McDonnell, Jeffrey J, Orlowski, Natalie, Penna, Daniele, Pfahl, Stephan, Rinderer, Michael, Rodriguez, Nicolas, Schmidt, Maximilian, and Werner, Christiane

Subjects
travel times, water ages, tracer hydrology, stable isotopes, critical Zone, terrestrial water cycle, Physical Sciences, Earth Sciences, Engineering, Meteorology & Atmospheric Sciences
Abstract

The time that water takes to travel through the terrestrial hydrological cycle and the critical zone is of great interest in Earth system sciences with broad implications for water quality and quantity. Most water age studies to date have focused on individual compartments (or subdisciplines) of the hydrological cycle such as the unsaturated or saturated zone, vegetation, atmosphere, or rivers. However, recent studies have shown that processes at the interfaces between the hydrological compartments (e.g., soil-atmosphere or soil-groundwater) govern the age distribution of the water fluxes between these compartments and thus can greatly affect water travel times. The broad variation from complete to nearly absent mixing of water at these interfaces affects the water ages in the compartments. This is especially the case for the highly heterogeneous critical zone between the top of the vegetation and the bottom of the groundwater storage. Here, we review a wide variety of studies about water ages in the critical zone and provide (1) an overview of new prospects and challenges in the use of hydrological tracers to study water ages, (2) a discussion of the limiting assumptions linked to our lack of process understanding and methodological transfer of water age estimations to individual disciplines or compartments, and (3) a vision for how to improve future interdisciplinary efforts to better understand the feedbacks between the atmosphere, vegetation, soil, groundwater, and surface water that control water ages in the critical zone.

Published
2019

10. Soil and stem xylem water isotope data from two pan-European sampling campaigns.

Author

Lehmann, Marco M., Geris, Josie, Meerveld, Ilja van, Penna, Daniele, Rothfuss, Youri, Verdone, Matteo, Ala-Aho, Pertti, Arvai, Matyas, Babre, Alise, Balandier, Philippe, Bernhard, Fabian, Butorac, Lukrecija, Carrière, Simon Damien, Ceperley, Natalie C., Chen, Zuosinan, Correa, Alicia, Diao, Haoyu, Dubbert, David, Dubbert, Maren, and Ercoli, Fabio

Subjects
QUALITY control, EUROPEAN beech, FOREST dynamics, STABLE isotopes, MIXED forests
Abstract

Stable isotope ratios of hydrogen (δ2H) and oxygen (δ18O) are crucial for studying ecohydrological dynamics in forests. However, most studies are confined to single sites, resulting in a lack of large-scale isotope data for understanding tree water uptake. Here, we provide a first systematic isotope dataset of soil and stem xylem water collected during two pan-European sampling campaigns at 40 beech (Fagus sylvatica), spruce (Picea abies), or mixed beech-spruce forest sites in spring and summer 2023 (Lehmann et al., 2024). The dataset is complemented by additional site-, soil-, and tree-specific metadata. The samples and metadata were collected by different researchers across Europe following a standardized protocol. Soil samples were taken at up to 5 depths (ranging from 0 to 90 cm) and stem xylem samples from three beech and/or spruce trees per site. All samples were sent to a single laboratory, where all analytical work was conducted. Water was extracted using cryogenic vacuum distillation and analyzed with an isotope laser spectrometer. Additionally, a subset of the samples was analyzed with an isotope ratio mass spectrometer. Data quality checks revealed a high mean total extraction efficiency, mean absolute water amount (> 1 mL), as well as high analytical accuracy and precision. The water isotopic signature of soil and stem xylem water varied as a function of the geographic origin and changed from spring to summer across all sites. While δ2H and δ18O values were strongly correlated, the soil water data plotted closer to the Global Meteoric Water Line (GMWL) than the stem xylem water. Specifically, the δ2H values of the stem xylem were more enriched than those of the soil water, leading to a systematic deviation from the GMWL. Isotopic enrichment of the stem xylem water was larger for spruce than for beech trees at mixed forest sites. This dataset is particularly useful for large-scale studies on plant water use, ecohydrological model testing, and isotope mapping across Europe. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Snowmelt and subsurface heterogeneity control tree water sources in a subalpine forest.

Author

Brighenti, Stefano, Obojes, Nikolaus, Bertoldi, Giacomo, Zuecco, Giulia, Censini, Matteo, Cassiani, Giorgio, Penna, Daniele, and Comiti, Francesco

Subjects
PLANT-water relationships, GEOPHYSICAL observations, CONIFEROUS forests, SOIL depth, WATER supply
Abstract

In high mountain areas, snowmelt water is a key—yet fading—hydrological resource, but its importance for soil recharge and tree root water uptake is understudied. In these environments, heterogeneous terrains enhance a highly variable availability of soil and groundwater resources that can be accessed by plants. We conducted a tracer‐based study on a subalpine forest in the Italian Alps. We investigated the isotopic composition (2H and 18O) of snowmelt, precipitation, spring water, soil water—at different locations and depths—and xylem water of twigs taken from alpine larch, Swiss stone pine and alpenrose plants during bi‐weekly field campaigns (growing seasons of 2020 and 2021). Mixing models based on δ18O revealed a large contribution of snowmelt to soil and xylem water, particularly during early summer. We investigated the contribution of water from different soil depths to xylem water, using the sap flow records to date back the end‐member signatures. We found a flexible use of shallow and deeper soil water by the investigated plants, with groundwater more likely used by larger trees and during the late summer. Results based on isotopic data were combined with geophysical observations of the subsurface structure to develop a conceptual model about the different exploitation of water by plants depending on their location (shallow soil on a slope vs. a saturated area). Our study highlights the relevance of snowmelt in high‐elevation terrestrial ecosystems, where heterogeneous substrates shape the water availability at different depths and, in turn, water uptake by plants. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Tree influence on water dynamics in sloped forest soils: insights from stemflow and throughflow experiments and time-lapse ground-penetrating radar monitoring

Author

Fernandes, Gersende, primary, Burguet Marimon, Maria, additional, Paz Salazar, Maria, additional, Marras, Elisa, additional, Murgia, Ilenia, additional, Kaffas, Konstantinos, additional, Giadrossich, Filippo, additional, D. Stewart, Ryan, additional, R. Abou Najm, Majdi, additional, Comegna, Alessandro, additional, Lassabatère, Laurent, additional, Penna, Daniele, additional, Massari, Christian, additional, and Di Prima, Simone, additional

Published
2024
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15. Toward a common methodological framework for the sampling, extraction, and isotopic analysis of water in the Critical Zone to study vegetation water use

Author

Ceperley, Natalie, primary, Gimeno, Teresa E., additional, Jacobs, Suzanne R., additional, Beyer, Matthias, additional, Dubbert, Maren, additional, Fischer, Benjamin, additional, Geris, Josie, additional, Holko, Ladislav, additional, Kübert, Angelika, additional, Le Gall, Samuel, additional, Lehmann, Marco M., additional, Llorens, Pilar, additional, Millar, Cody, additional, Penna, Daniele, additional, Prieto, Iván, additional, Radolinski, Jesse, additional, Scandellari, Francesca, additional, Stockinger, Michael, additional, Stumpp, Christine, additional, Tetzlaff, Dörthe, additional, van Meerveld, Ilja, additional, Werner, Christiane, additional, Yildiz, Oktay, additional, Zuecco, Giulia, additional, Barbeta, Adrià, additional, Orlowski, Natalie, additional, and Rothfuss, Youri, additional

Published
2024
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16. Toward a common methodological framework for the sampling, extraction, and isotopic analysis of water in the Critical Zone to study vegetation water use

Author

Ceperley, Natalie, Gimeno, Teresa E., Jacobs, Suzanne R., Beyer, Matthias, Dubbert, Maren, Fischer, Benjamin M. C., Geris, Josie, Holko, Ladislav, Kübert, Angelika, Le Gall, Samuel, Lehmann, Marco M., Llorens, Pilar, Millar, Cody, Penna, Daniele, Prieto, Iván, Radolinski, Jesse, Scandellari, Francesca, Stockinger, Michael, Stumpp, Christine, Tetzlaff, Dörthe, van Meerveld, Ilja, Werner, Christiane, Yildiz, Oktay, Zuecco, Giulia, Barbeta, Adrià, Orlowski, Natalie, Rothfuss, Youri, Ceperley, Natalie, Gimeno, Teresa E., Jacobs, Suzanne R., Beyer, Matthias, Dubbert, Maren, Fischer, Benjamin M. C., Geris, Josie, Holko, Ladislav, Kübert, Angelika, Le Gall, Samuel, Lehmann, Marco M., Llorens, Pilar, Millar, Cody, Penna, Daniele, Prieto, Iván, Radolinski, Jesse, Scandellari, Francesca, Stockinger, Michael, Stumpp, Christine, Tetzlaff, Dörthe, van Meerveld, Ilja, Werner, Christiane, Yildiz, Oktay, Zuecco, Giulia, Barbeta, Adrià, Orlowski, Natalie, and Rothfuss, Youri

Published
2024
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17. Toward a common methodological framework for the sampling, extraction, and isotopic analysis of water in the Critical Zone to study vegetation water use

Author

0000-0002-2260-8426, 0000-0002-1707-9291, 0000-0003-2223-6973, 0000-0002-1618-6036, 0000-0002-2352-8516, 0000-0003-2530-6084, 0000-0003-0159-0543, 0000-0002-4589-7478, 0000-0003-3985-9261, 0000-0003-2962-3351, 0000-0003-4591-5303, 0000-0002-2171-581X, 0000-0001-6915-0697, 0000-0001-5549-1132, 0000-0003-4341-4046, 0000-0002-2242-2656, 0000-0002-7715-8100, 0000-0001-9041-2735, 0000-0002-7183-8674, 0000-0002-7547-3270, 0000-0002-7676-9057, 0000-0002-8058-4506, 0000-0002-2125-0717, 0000-0002-8357-1719, 0000-0003-4368-4580, 0000-0002-8874-5036, Ceperley, Natalie, Gimeno, Teresa E., Jacobs, Suzanne R., Beyer, Matthias, Dubbert, Maren, Fischer, Benjamin, Geris, Josie, Holko, Ladislav, Kübert, Angelika, Le Gall, Samuel, Lehmann, Marco M., Llorens, Pilar, Millar, Cody, Penna, Daniele, Prieto, Iván, Radolinski, Jesse, Scandellari, Francesca, Stockinger, Michael, Stumpp, Christine, Tetzlaff, Dörthe, van Meerveld, Ilja, Werner, Christiane, Yildiz, Oktay, Zuecco, Giulia, Barbeta, Adrià, Orlowski, Natalie, Rothfuss, Youri, 0000-0002-2260-8426, 0000-0002-1707-9291, 0000-0003-2223-6973, 0000-0002-1618-6036, 0000-0002-2352-8516, 0000-0003-2530-6084, 0000-0003-0159-0543, 0000-0002-4589-7478, 0000-0003-3985-9261, 0000-0003-2962-3351, 0000-0003-4591-5303, 0000-0002-2171-581X, 0000-0001-6915-0697, 0000-0001-5549-1132, 0000-0003-4341-4046, 0000-0002-2242-2656, 0000-0002-7715-8100, 0000-0001-9041-2735, 0000-0002-7183-8674, 0000-0002-7547-3270, 0000-0002-7676-9057, 0000-0002-8058-4506, 0000-0002-2125-0717, 0000-0002-8357-1719, 0000-0003-4368-4580, 0000-0002-8874-5036, Ceperley, Natalie, Gimeno, Teresa E., Jacobs, Suzanne R., Beyer, Matthias, Dubbert, Maren, Fischer, Benjamin, Geris, Josie, Holko, Ladislav, Kübert, Angelika, Le Gall, Samuel, Lehmann, Marco M., Llorens, Pilar, Millar, Cody, Penna, Daniele, Prieto, Iván, Radolinski, Jesse, Scandellari, Francesca, Stockinger, Michael, Stumpp, Christine, Tetzlaff, Dörthe, van Meerveld, Ilja, Werner, Christiane, Yildiz, Oktay, Zuecco, Giulia, Barbeta, Adrià, Orlowski, Natalie, and Rothfuss, Youri

Abstract

The analysis of the stable isotopic composition of hydrogen and oxygen in water samples from soils and plants can help to identify sources of vegetation water uptake. This approach requires that the heterogeneous nature of plant and soil matrices is carefully accounted for during experimental design, sample collection, water extraction and analyses. The comparability and shortcomings of the different methods for extracting water and analyzing isotopic composition have been discussed in specialized literature. Yet, despite insightful comparisons of extraction methods and benchmarking methodologies of laboratories worldwide, the community still lacks a roadmap to guide sample collection, extraction, and isotopic analyses, and many practical issues for potential users remain unresolved: for example, which (soil or plant) water pool(s) does the extracted water represent? These constitute a hurdle for the implementation of the approach by newcomers. Here, we summarize discussions led in the framework of the COST Action WATSON (“WATer isotopeS in the critical zONe: from groundwater recharge to plant transpiration”—CA19120). We provide guidelines for (1) sampling soil and plant material for isotopic analysis, (2) methods for laboratory or in situ water extraction, and (3) measurements of isotopic composition. We highlight the importance of considering the process chain as a whole, from experimental design to isotopic analysis to minimize biased estimates of the relative contribution of different water sources to plant water uptake. We conclude by acknowledging some of the limitations of this methodology and advice on the collection of key environmental parameters prior to sample collection for isotopic analyses. This article is categorized under: Science of Water > Hydrological Processes Science of Water > Water and Environmental Change Science of Water > Water Extremes.

Published
2024

18. The influence of hillslope topography on beech water use: a comparative study in two different climates.

Author

Fabiani, Ginevra, Klaus, Julian, and Penna, Daniele

Subjects
WATER use, TOPOGRAPHY, BEECH, EUROPEAN beech, MARINE west coast climate
Abstract

Understanding the interrelation between topography and vegetation across different environments is important to assess how hydrological and climatic conditions affect tree physiological activity. This becomes especially important given the expected reduction in water availability and the increase in water demand driven by climate change. These extremes could enhance the thermal and hydrologic gradients along slopes. Here, we aimed to test if and how different climatic and hydrological conditions affect the physiological response of beech trees (Fagus sylvatica L.) to environmental variables along two different topographic sequences. For this purpose, we set up a comparative study on a gentle hillslope in the Weierbach catchment in Luxembourg (oceanic climate) and on a steep hillslope in the Lecciona catchment in Italy (Mediterranean climate). We combined sap velocity measurements with isotopic measurements of soil, precipitation, stream water, groundwater, and xylem over 2019 and 2020 for the Luxembourgish site and over 2021 for the Italian site. We found that, in the Weierbach catchment, trees' responses to environmental variables (i.e. vapour pressure deficit and relative extractable water in the soil) were similar among hillslope positions and between the two monitored years, resulting from homogeneous growing conditions along the topographic sequence. We also did not find any statistical difference in the isotopic composition of xylem water between positions, suggesting that beech trees relied on similar water sources across the landscape. In the Lecciona catchment, we observed lower sap velocities and shorter growing season in trees growing in the upper portions of the hillslope, likely related to water redistribution and different soil moisture along the hillslope catena. Xylem isotopic composition was significantly lighter at the footslope location throughout the growing season than in the upslope locations, suggesting location-specific water use. These results emphasize how differing hydrometeorological processes occurring at the hillslope scale can lead to contrasting tree responses. [ABSTRACT FROM AUTHOR]

Published
2024
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24. A recipe for why and how to set up and sustain an experimental catchment.

Author

Penna, Daniele

Subjects
SCIENTIFIC community, REMOTE sensing, MACHINE learning, BIG data, RESEARCH personnel, WATERSHEDS
Abstract

Experimental catchments are fundamental elements in hydrological sciences as they provide key data for putting forward and testing hypotheses, developing theories, constraining models, and making predictions. Significant progress in catchment hydrology stemmed from field measurements but increasing costs and risks associated with field work and the availability of big data based on remote sensing, machine learning, and a plethora of models, as well as observations deriving from previous and current sites, raises questions on whether running an experimental catchment still provides individual and community benefits as in the past. In this commentary, I highlight the advantages of keeping experimental catchments alive and propose a personal 10‐step "recipe" to set up a new experimental catchment and manage and sustain it in the long term. These suggestions can be useful both to young and less young researchers who are open to facing the challenge of measuring processes in the field and are willing to offer the scientific community new experimental evidence for advancing our current knowledge in catchment hydrology. [ABSTRACT FROM AUTHOR]

Published
2024
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25. Event-based soil erosion and sediment yield modelling for calculating long-term reservoir sedimentation in the Alps.

Author

Kaffas, Konstantinos, Pisaturo, Giuseppe Roberto, Premstaller, Georg, Hrissanthou, Vlassios, Penna, Daniele, and Righetti, Maurizio

Subjects
RESERVOIR sedimentation, SOIL erosion, UNIVERSAL soil loss equation, SEDIMENTS
Abstract

Among the most characteristic offsite effects of soil erosion, reservoir sedimentation is one of the longlasting problems pertaining to storage capacity and dam operations. In this work, sedimentation rates of the Fortezza reservoir in South Tyrol (Italian Alps) are analysed for nine erosive events over 14 months. Sediment rates are calculated through a modified Universal Soil Loss Equation (USLE) combined with a Sediment Delivery Ratio (SDR) module at 2.5 m resolution. The topographic factor is adjusted to the Alpine terrain, and an additional factor is included to consider the nonerodible parts of the basin. The results are validated against a 14-month sediment yield obtained by high-resolution (0.2 m) reservoir bathymetric analyses. The calculated sediment yield has an absolute deviation of 4.8% from the measured one. The results indicate that these methods can be successfully applied for the estimation of reservoir sedimentation rates in the Alps. [ABSTRACT FROM AUTHOR]

Published
2024
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27. List of contributors

Author

Ait-Mouheb, Nassim, primary, Albergel, Clément, additional, Allam, Antoine, additional, Aouissi, Jalel, additional, Baghdadi, Nicolas, additional, Bocquillon, Claude, additional, Boulet, Gilles, additional, Brocca, Luca, additional, Calvet, Jean-Christophe, additional, Camarero, J. Julio, additional, Camici, Stefania, additional, Ciabatta, Luca, additional, Domínguez-Castro, Fernando, additional, El Kenawy, Ahmed, additional, Fakir, Younes, additional, Gaget, Elie, additional, Galewski, Thomas, additional, Gascoin, Simon, additional, Geijzendorffer, Ilse, additional, Guelmami, Anis, additional, Hartani, Tarik, additional, Heras, Mariano Moreno de las, additional, Jarlan, Lionel, additional, Kuper, Marcel, additional, Lana-Renault, Noemí, additional, Le Page, Michel, additional, Leroux, Delphine, additional, López-Moreno, Nacho, additional, Lorenzo-Lacruz, Jorge, additional, Marra, Anna Cinzia, additional, Massari, Christian, additional, Mateo-Sagasta, Javier, additional, Mayaux, Pierre-Louis, additional, Molle, Bruno, additional, Molle, François, additional, Morán-Tejeda, Enrique, additional, Moussa, Roger, additional, Munier, Simon, additional, Najem, Wajdi, additional, Nieto, Hector, additional, Notarnicola, Claudia, additional, Olioso, Albert, additional, Panegrossi, Giulia, additional, Penna, Daniele, additional, Perennou, Christian, additional, Pimentel, Rafael, additional, Polo, María J., additional, Sanchis-Ibor, Carles, additional, Tramblay, Yves, additional, Vicente-Serrano, Sergio M., additional, and Zribi, Mehrez, additional

Published
2020
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32. Quantifying irrigation uptake in olive trees: a proof-of-concept approach combining isotope tracing and Hydrus-1D

Author

Nasta, Paolo, primary, Todini-Zicavo, Diego, additional, Zuecco, Giulia, additional, Marchina, Chiara, additional, Penna, Daniele, additional, McDonnell, Jeffrey J., additional, Amin, Anam, additional, Allocca, Carolina, additional, Marzaioli, Fabio, additional, Stellato, Luisa, additional, Borga, Marco, additional, and Romano, Nunzio, additional

Published
2023
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35. On the relation between antecedent basin conditions and runoff coefficient for European floods

Author

Massari, Christian (author), Pellet, Victor (author), Tramblay, Yves (author), Crow, Wade T. (author), Gründemann, Gaby J. (author), Hascoetf, Tristian (author), Penna, Daniele (author), Modanesi, Sara (author), Brocca, Luca (author), Massari, Christian (author), Pellet, Victor (author), Tramblay, Yves (author), Crow, Wade T. (author), Gründemann, Gaby J. (author), Hascoetf, Tristian (author), Penna, Daniele (author), Modanesi, Sara (author), and Brocca, Luca (author)

Abstract

The event runoff coefficient (i.e. the ratio between event runoff and precipitation that originated the runoff) is a key factor for understanding basin response to precipitation events. Runoff coefficient depends on precipitation intensity and duration but also on specific basin geohydrology attributes (including soil type, geology, land cover, topography) and last but not least, antecedent (or pre-storm) conditions (i.e., the amount of water stored in the different hydrological compartments, like the river, groundwater, soil and snowpack). The relation between runoff coefficient and basin pre-storm conditions is critical for flood forecasting, yet, the understanding of where, when and how much basin pre-storm conditions control runoff coefficients is still an open question. Here, we tested the control of basin pre-storm conditions on runoff coefficient for 60620 flood events across 284 basins in Europe. To do so, we derived basin pre-storm conditions from different proxies, namely: antecedent precipitation; surface and root zone soil moisture from hydrological models, reanalyses and land surface models also ingesting satellite observations; pre-storm river discharge, and pre-storm total water storage anomalies. We evaluated the coupling strength between runoff coefficient and pre-storm conditions proxies in relation to five classes of European basins, defined based on land use and soil type (as indexed by the Soil Conservation Service curve number CN), topography, hydrology and long-term climate and tested their ability to explain stormflow volume variability. We found that precipitation explains relatively well the stormflow volumes for both small and large events but not very well the peak discharge, especially for large floods. The runoff coefficient of events shows different distributions for the five different classes and correlates well with deep soil storages (such as root-zone soil moisture and pre-storm total water storage anomalies), pre-storm river di, Water Resources

Published
2023
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36. 18-fluorodeoxyglucose positron emission tomography (FDG-PET) in patients with non-tuberculous mycobacterial infectionsA case series on the use of Nuclear Medicine in NTM-PD

Author

Stroffolini, G, Gaviraghi, A, Penna, D, Piccioni, P, Venuti, F, Botto, C, Trezzi, M, Betti, M, Sestini, S, Erba, P, Lupia, T, Di Perri, G, Aliberti, S, Calcagno, A, Stroffolini, Giacomo, Gaviraghi, Alberto, Penna, Daniele, Piccioni, Pavilio, Venuti, Francesco, Botto, Carlotta, Trezzi, Michele, Betti, Margherita, Sestini, Stelvio, Erba, Paola Anna, Lupia, Tommaso, Di Perri, Giovanni, Aliberti, Stefano, Calcagno, Andrea, Stroffolini, G, Gaviraghi, A, Penna, D, Piccioni, P, Venuti, F, Botto, C, Trezzi, M, Betti, M, Sestini, S, Erba, P, Lupia, T, Di Perri, G, Aliberti, S, Calcagno, A, Stroffolini, Giacomo, Gaviraghi, Alberto, Penna, Daniele, Piccioni, Pavilio, Venuti, Francesco, Botto, Carlotta, Trezzi, Michele, Betti, Margherita, Sestini, Stelvio, Erba, Paola Anna, Lupia, Tommaso, Di Perri, Giovanni, Aliberti, Stefano, and Calcagno, Andrea

Published
2023

40. Contrasting water use strategies of beech trees along two hillslopes with different slope and climate.

Author

Fabiani, Ginevra, Klaus, Julian, and Penna, Daniele

Abstract

Understanding the interaction between topography and vegetation across different environments is important to assess how hydrological and climatic conditions affect tree physiological activity. This becomes especially important given the expected reduction in water availability and increase in water demand driven by climate change. These extremes could enhance the thermal and hydrologic gradients along slopes. Here, we aimed at testing if and how different climatic and hydrological conditions affect the physiological response to environmental variables of beech trees (Fagus sylvatica L.) along two different topographic sequences. For this purpose, we set up a comparative study on a gentle hillslope in the Weierbach catchment in Luxembourg (oceanic climate) and a steep hillslope in the Lecciona catchment in Italy (Mediterranean climate). We combined sap velocity measurements with isotopic measurements of soil, precipitation, stream water, groundwater, and xylem over 2019 and 2020 in the Luxembourgish site and 2021 in the Italian site. We found that in the Weierbach catchment, trees' response to environmental variables (i.e., vapour pressure deficit and relative extractable water in the soil) was similar among hillslope positions and between the two monitored years resulting from homogeneous growing conditions along the topographic sequence. We also did not find any statistical difference in the isotopic composition of xylem water among positions suggesting that beech trees relied on similar water sources across the landscape. In the Lecciona catchment, we observed lower sap velocities and shorter growing season in trees growing in the upper portions of the hillslope, likely related to water redistribution and different soil moisture along the hillslope catena. Xylem isotopic composition was significantly lighter at the footslope location throughout the growing season than in the upslope locations, suggesting location-specific water use. These results emphasize how differing hydrometeorological processes occurring at the hillslope scale can lead to contrasting tree performances. [ABSTRACT FROM AUTHOR]

Published
2023
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44. Geology controls hydrological regime and spatio-temporal origin of surface and subsurface water in two adjacent mountain catchments in Central Italy

Author

Manca di Villahermosa, Francesca, primary, Dionigi, Marco, additional, Donnini, Marco, additional, Fronzi, Davide, additional, Tazioli, Alberto, additional, Spoloar, Andrea, additional, Turetta, Clara, additional, Cappelletti, Davide, additional, Petroselli, Chiara, additional, Bruschi, Federica, additional, Selvaggi, Roberta, additional, Penna, Daniele, additional, and Massari, Christian, additional

Published
2023
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50. Quantifying irrigation uptake in olive trees: a proof-of-concept approach combining isotope tracing and Hydrus-1D

Author

Nasta, Paolo, Todini-Zicavo, Diego, Zuecco, Giulia, Marchina, Chiara, Penna, Daniele, McDonnell, Jeffrey J., Amin, Anam, Allocca, Carolina, Marzaioli, Fabio, Stellato, Luisa, Borga, Marco, and Romano, Nunzio

Abstract

An isotope-enabled module of Hydrus-1D was applied to a potted olive tree to trace water parcels originating from 26 irrigation events in a glasshouse experiment. The soil hydraulic parameters were optimised via inverse modelling by minimising the discrepancies between observed and simulated soil water content and soil water isotope (δ18O) values at three soil depths. The model’s performance was validated with observed sap flow z-scores and xylem water δ18O. We quantified the source and transit time of irrigation water by analysing the mass breakthrough curves derived from a virtual tracer injection experiment. On average, 26 % of irrigation water was removed by plant transpiration with a mean transit time of 94 hours. Our proof of concept work suggests that transit time may represent a functional indicator for the uptake of irrigation water in agricultural ecosystems.

Published
2023
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