Your search keyword '"Bargués-Tobella, A."' showing total 10 results

1. Excessive livestock grazing overrides the positive effects of trees on infiltration capacity and modifies preferential flow in dry miombo woodlands

Author

Ulrik Ilstedt, C. A. Masao, L. Lulandala, Gert Nyberg, and Aida Bargués-Tobella

Subjects

Ecology, Livestock grazing, animal diseases, Forest Science, Soil Science, Woodland, Development, Preferential flow, Environmental Sciences related to Agriculture and Land-use, Agronomy, parasitic diseases, Environmental Chemistry, Environmental science, General Environmental Science

Abstract

The increase in livestock grazing in African drylands such as miombo woodlands threatens land productivity and ecosystem functioning. Trees have positive effects on soil hydraulic properties, but few studies have looked at grazing intensity and hydrological functioning in different land uses. Therefore, we conducted a biophysical survey in Morogoro Rural District, Tanzania, where we identified four main land uses and land cover types, that is, Forest reserve, open-access forest, cropland under fallow, and active cropland. We assessed grazing intensity, measured infiltration capacity, and conducted dye tracer experiments to assess the degree of preferential flow in 64 plots. We also tested the effect of grazing exclusion on infiltration capacity in 12-year-old fenced plots. Our results show that irrespective of land use or cover type, soil bulk density increased by 10% from low to high grazing intensity, whereas infiltration capacity and soil organic carbon decreased by 55% and 28%, respectively. We found a positive relationship between infiltration capacity and tree basal area in plots with lowest grazing intensities. However, at higher grazing, the infiltration capacity remained low independently of the basal area. Preferential flow in deeper soils was six-times higher in areas with no grazing, indicating higher deep soil and groundwater recharge potential at low grazing intensities. We conclude that the negative impacts on soil hydrological functioning of excessive livestock grazing override the positive effect of trees, but restricting grazing can reverse the impact.

Published

2022

2. Assessing soil and land health across two landscapes in eastern Rwanda to inform restoration activities

Author

Tor-Gunnar Vågen, Elisée Bahati Ntawuhiganayo, Athanase Mukuralinda, Aida Bargués-Tobella, Susan Chomba, Leigh A. Winowiecki, Alex Billy Mugayi, and Providence Mujawamariya

Subjects

QE1-996.5, Topsoil, geography, geography.geographical_feature_category, Soil Science, Geology, Plant community, Forestry, Soil carbon, Woodland, Vegetation, Shrubland, Environmental sciences, Land degradation, Erosion, Environmental science, GE1-350

Abstract

Land degradation negatively impacts water, food, and nutrition security and is leading to increased competition for resources. While landscape restoration has the potential to restore ecosystem function, understanding the drivers of degradation is critical for prioritizing and tracking interventions. We sampled 300–1000 m2 plots using the Land Degradation Surveillance Framework across Nyagatare and Kayonza districts in Rwanda to assess key soil and land health indicators, including soil organic carbon (SOC), erosion prevalence, vegetation structure and infiltration capacity, and their interactions. SOC content decreased with increasing sand content across both sites and sampling depths and was lowest in croplands and grasslands compared to shrublands and woodlands. Stable carbon isotope values (δ13C) ranged from −15.35 ‰ to −21.34 ‰, indicating a wide range of historic and current plant communities with both C3 and C4 photosynthetic pathways. Field-saturated hydraulic conductivity (Kfs) was modeled, with a median of 76 mm h−1 in Kayonza and 62 mm h−1 in Nyagatare, respectively. Topsoil OC had a positive effect on Kfs, whereas pH, sand, and erosion had negative effects. Soil erosion was highest in plots classified as woodland and shrubland. Maps of soil erosion and SOC at 30 m resolution were produced with high accuracy and showed strong variability across the study landscapes. These data demonstrate the importance of assessing multiple biophysical properties in order to assess land degradation, including the spatial patterns of soil and land health indicators across the landscape. By understanding the dynamics of land degradation and interactions between biophysical indicators, we can better prioritize interventions that result in multiple benefits as well as assess the impacts of restoration options.

Published

2021

3. Positive Effects of Scattered Trees on Soil Water Dynamics in a Pasture Landscape in the Tropics

Author

Anders Malmer, Aida Bargués-Tobella, Laura Benegas, Ulrik Ilstedt, and Niles J. Hasselquist

Subjects

ecosystem, Hydrology, land management, Soil Science, isosource mixing model, General Medicine, Oceanography, Hydrology, Water Resources, Groundwater recharge, groundwater recharge, Environmental technology. Sanitary engineering, Water resources, Water balance, Dry season, Soil water, Environmental science, niche partitioning, Water content, TD1-1066, Groundwater, tree-grass coexistence, Transpiration

Abstract

As a result of canopy interception and transpiration, trees are often assumed to have negative effects on the local hydrological budget resulting in reduced soil and groundwater resources. However, it has also been shown that trees can have positive effects through reducing surface run-off and improving soil infiltrability and groundwater recharge, especially in many tropical ecosystems characterized by high rain intensity and degradation-prone soils. In this study, we used isotopic measurements of soil water to better understand the main processes by which trees influence local soil water dynamics within a tropical pasture with scattered tree cover in the Copan River catchment, Honduras. We also determined the stable isotope signature of xylem water in grasses and trees to assess potential competition for water sources during the wet and dry seasons. During the wet season, when soil water availability was not limiting, both grasses and trees primarily utilized soil water near the soil surface (i.e., 0–10 cm). In contrast, during the dry season, we observed niche partitioning for water resources where grasses primarily utilized soil moisture at deeper soil depth (i.e., 90–100 cm) while trees relied heavily on groundwater. Moreover, isotopic data of soil water suggest that trees reduce evaporative water losses from the soil surface, as indicated by the lack of correlation between soil water content and lc-excess (line condition excess) values of surface soil water under trees, and enhance preferential flow as suggested by less negative lc-excess values under trees compared to open areas during the dry season. Taken together, our findings provide further support that trees can have positive effects on the local water balance with implication for landscape management, promoting the inclusion of scattered trees to provide water ecosystem services in silvopastoral systems, adding to other ecosystem services like biodiversity or carbon sequestration.

Published

2021

4. Assessing biogeochemical and human-induced drivers of soil organic carbon to inform restoration activities in Rwanda

Author

Leigh A. Winowiecki, Elisée Bahati Ntawuhiganayo, Susan Chomba, Tor-Gunnar Vågen, Providence Mujawamaria, Aida Bargués-Tobella, Alex Billy Mugayi, and Athanase Mukuralinda

Subjects

Soil health, Hydrology, Topsoil, geography, Infiltration (hydrology), geography.geographical_feature_category, Land restoration, Land degradation, Environmental science, Soil carbon, Subsoil, Shrubland

Abstract

Land restoration is of critical importance in Rwanda, where land degradation negatively impacts crop productivity, water, food and nutrition security. We implemented the Land Degradation Surveillance Framework in Kayonza and Nyagatare districts in eastern Rwanda to assess baseline status of key soil and land health indicators, including soil organic carbon (SOC) and soil erosion prevalence. We collected 300 topsoil (0–20 cm) and 281 subsoil (20–50 cm) samples from two 100 km2 sites. We coupled the soil health indicators with vegetation structure, tree density and tree diversity assessments. Mean topsoil organic carbon was low overall, 20.9 g kg−1 in Kayonza and 17.3 g kg−1 in Nyagatare. Stable carbon isotope values (d13CV-PDB ) ranged from −15.35 to −21.34 ‰ indicating a wide range of plant communities with both C3 and C4 photosynthetic pathways. Soil carbon content decreased with increasing sand content across both sites and at both sampling depths and was lowest in croplands compared to shrubland, woodland and grasslands. Field-saturated hydraulic conductivity (Kfs) was estimated based on infiltration measurements, with a median of 76 mm h−1 in Kayonza and 62 mm h−1 in Nyagatare, respectively. Topsoil OC had a positive effect on Kfs, whereas pH, sand and compaction had negative effects. Soil erosion was highest in plots classified as woodland and shrubland. Maps of soil erosion and SOC at 30-m resolution were produced with high accuracy and showed high variability across the region. These data and analysis demonstrate the importance of systematically monitoring multiple indicators at multiple spatial scales to assess drivers of degradation and their impact on soil organic carbon dynamics.

Published

2020

5. Temporal variations in transpiration of Vitellaria paradoxa in West African agroforestry parklands

Author

Jules Bayala, Aida Bargués-Tobella, Josias Sanou, H. R. Bazié, Gérard Zombre, and Ulrik Ilstedt

Subjects

0106 biological sciences, Wet season, Vapour Pressure Deficit, Forestry, 04 agricultural and veterinary sciences, Seasonality, medicine.disease, 01 natural sciences, Canopy conductance, Agronomy, Botany, Soil water, Dry season, 040103 agronomy & agriculture, medicine, 0401 agriculture, forestry, and fisheries, Environmental science, Agronomy and Crop Science, Water use, 010606 plant biology & botany, Transpiration

Abstract

Lack of data on water use of key species of drylands constitutes an obstacle to understanding their role in hydrological processes in this environment. To elucidate seasonal variation in water consumption by Vitellaria paradoxa, the dominant species of parklands of the semi-arid areas of West Africa, we’ve measured its transpiration using heat ratio method (HRM) and seven potential explanatory variables. Sap flux was found to be significantly different among years with 0.64, 0.59 and 0.67 L h−1 dm−2 in 2008, 2009 and 2010, respectively. Sap flux was significantly higher in the dry (0.73 L h−1 dm−2) than in the wet season (0.53 L h−1 dm−2). Nighttime sap flux during dry season (0.48 L h−1 dm−2) was significantly higher than that of the wet season (0.20 L h−1 dm−2) and it contributes on average to 26% of daily sap flow with a maximum reaching 49%. The mean transpiration rate per tree was 151 L day−1 and all measured variables except rainfall and soil water content were significantly correlated with sap flux. These correlations were stronger (higher R value) during the rainy than in the dry season. Vapor Pressure Deficit (VPD) explained the highest proportion of sap flux variation and their curve was of parabolic type (R2 = 0.54) indicating that V. paradoxa can probably down-regulate its canopy conductance beyond a certain threshold of VPD, which is about 3 kPa in the present study. Future studies should investigate such hypothesis as well as the impacts of the variation of V. paradoxa transpiration due to climatic variables on hydrological cycles.

Published

2017

6. Soil control over the distribution of Mediterranean oak forests in the Montsec mountains (northeastern Spain)

Author

Rafael Rodríguez-Ochoa, A. Bargués Tobella, M. Antúnez, and José Ramón Olarieta

Subjects

0106 biological sciences, Mediterranean climate, Total organic carbon, biology, Ecology, Phosphorus, Soil Science, chemistry.chemical_element, Forestry, 04 agricultural and veterinary sciences, Evergreen, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Altitude, Rock fragment, chemistry, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Quercus faginea

Abstract

Models of plant species distribution and response to global change rely mostly on climatic variables alone, whereas soil variables are usually not taken into account. Evergreen and marcescent oaks are therefore considered to share environmental niches in the Mediterranean region despite their functional differences. We studied the distribution of forests dominated by either Quercus ilex (QI plots) or Q. faginea/Q. subpyrenaica (QF plots) in 46 plots at an altitude between 570 m and 980 m on a north-facing slope in northeastern Spain. We used binomial logistic regression and classification tree analysis to explain the distribution of the two types of forest. Soils of the sample plots were mostly Lithic Xerorthents developed from limestone. Surface mineral horizons of QI forests had higher organic carbon (C), nitrogen (N), and NaOH-extractable phosphorus concentrations, while organic layers had smaller values of the C/N and C/P ratios. Soils of QF forests accumulated higher amounts of C despite the lower concentration in their surface mineral horizons. The distribution of QF and QI forests was significantly explained by the variability in soil available water-holding capacity and rock fragment content, QF forests appearing on soils with over 22 mm of available water-holding capacity and

Published

2017

7. Soil property changes over a 120-yr chronosequence from forest to agriculture in western Kenya

Author

J. Kinyangi, Ulrik Ilstedt, Gert Nyberg, and A. Bargués Tobella

Subjects

lcsh:GE1-350, education.field_of_study, δ13C, lcsh:T, Agroforestry, Chronosequence, Population, lcsh:Geography. Anthropology. Recreation, Soil carbon, Infiltration (HVAC), lcsh:Technology, Bulk density, lcsh:TD1-1066, lcsh:G, Agronomy, Agricultural land, Soil retrogression and degradation, Environmental science, lcsh:Environmental technology. Sanitary engineering, education, lcsh:Environmental sciences

Abstract

Much of the native forest in the highlands of western Kenya has been converted to agricultural land in order to feed the growing population, and more land is being cleared. In tropical Africa, this land use change results in progressive soil degradation, as the period of cultivation increases. Both rates and variation in infiltration, soil carbon concentration and other soil parameters are influenced by management within agricultural systems, but they have rarely been well documented in East Africa. We constructed a chronosequence for an area of western Kenya, using two native forest sites and six fields that had been converted to agriculture for up to 119 yr. We assessed changes in infiltrability (the steady-state infiltration rate), bulk density, proportion of macro- and microaggregates in soil, soil C and N concentrations, as well as the isotopic signature of soil C (δ13C), along the 119-yr chronosequence of conversion from natural forest to agriculture. Infiltration, soil C and N decreased within 40 yr after conversion, while bulk density increased. Median infiltration rates fell to about 15% of the initial values in the forest, and C and N concentrations dropped to around 60%, whilst the bulk density increased by 50%. Despite high spatial variability, these parameters have correlated well with time since conversion and with each other.

Published

2018

8. Trees, forests and water: Cool insights for a hot world

Author

Yulia Sugandi, Meine van Noordwijk, Dominick V. Spracklen, Bruno Verbist, Daniel Murdiyarso, Bart Muys, Adriaan J. Teuling, David Sands, David L. A. Gaveau, Victoria Gutierrez, Aida Bargués Tobella, Douglas Sheil, David Ellison, Jan Pokorny, Bruno Locatelli, Caroline A Sullivan, Solomon Gebreyohannis Gebrehiwot, Cindy E. Morris, Jane Maslow Cohen, Irena F. Creed, Elaine Springgay, Ulrik Ilstedt, Department of Forest Ecology and Management, Swedish University of Agricultural Sciences (SLU), Ellison Consulting, Unité de Pathologie Végétale (PV), Institut National de la Recherche Agronomique (INRA), Department Plant Sciences and Plant Pathology [Bozeman], Montana State University (MSU), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad), Center for International Forestry Research (CIFOR), Consultative Group on International Agricultural Research [CGIAR] (CGIAR), Norwegian University of Life Sciences (NMBU), University of Texas at Austin [Austin], Bogor Agricultural University - IPB (INDONESIA), WeForest, World Agroforestry Center [CGIAR, Kenya] (ICRAF), Wageningen University and Research [Wageningen] (WUR), University of Western Ontario (UWO), ENKI, o.p.s., University of Leeds, Department of Earth Sciences [Uppsala], Uppsala University, Addis Ababa University (AAU), Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Food and Agriculture Organization of the United Nations [Rome, Italie] (FAO), Southern Cross University (SCU), CGIAR Research Program on Forests, Trees and Agroforestry (CRP-FTA), Australian Research Council fund LP130100498, ENKI and the Belgian Development Cooperation through VLIR-UOS, Station de Pathologie Végétale (AVI-PATHO), Department of Ecology and Natural Resource Management, Texas law, University of North Texas (UNT), Department of Geophysics and Meteorology, ICRAF World Agroforestry Center, Plant Production Systems, Wageningen University and Research Center (WUR), Department of Biology, Western University, School of Earth and Environment, Hydrology and Quantitative Water Management Group, Ethiopian Institute of Water Resources, Department of Earth Sciences [ Uppsala], Division of Forest, Nature and Landscape, Department of Earth and Environmental Sciences [Leuven] (EES), Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven)-Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Food and Agricultural Organization (FAO), Department of Community Development and Communication Sciences, School of Environment, Science and Engineering, Southern Cross University, and Ellison, David

Subjects

010504 meteorology & atmospheric sciences, Mitigation, Climate, Geography, Planning and Development, Ressource énergétique, Planification régionale, adaptation aux changements climatiques, forêt tropicale, adaptation, 010501 environmental sciences, 01 natural sciences, Klimatforskning, forest, forêt, 11. Sustainability, K01 - Foresterie - Considérations générales, couverture du sol, Gouvernance, Milieux et Changements globaux, reforestation, Global and Planetary Change, Utilisation des terres, water, energy, climate, carbon, mitigation, sustainability, Energy, Ecology, Corporate governance, Environmental resource management, impact climatique, PE&RC, Call to action, séquestration du carbone, Plant Production Systems, Sustainability, réduction des émissions, P01 - Conservation de la nature et ressources foncières, Ressource en eau, P33 - Chimie et physique du sol, cycle du carbone, Climate Research, P40 - Météorologie et climatologie, cycle de l'eau, [SDE.MCG]Environmental Sciences/Global Changes, Land cover, Management, Monitoring, Policy and Law, Carbon cycle, carbon cycle, Couverture végétale, Forest, Adaptation, P10 - Ressources en eau et leur gestion, Arbre forestier, Reforestation, 0105 earth and related environmental sciences, Changement climatique, Land use, business.industry, Water, Water cool, Cycle hydrologique, politique agrienvironnementale, 15. Life on land, Carbon, Water resources, 13. Climate action, Plantaardige Productiesystemen, Politique foncière, Environmental science, Politique forestière, business

Abstract

© 2017 The Author(s) Forest-driven water and energy cycles are poorly integrated into regional, national, continental and global decision-making on climate change adaptation, mitigation, land use and water management. This constrains humanity's ability to protect our planet's climate and life-sustaining functions. The substantial body of research we review reveals that forest, water and energy interactions provide the foundations for carbon storage, for cooling terrestrial surfaces and for distributing water resources. Forests and trees must be recognized as prime regulators within the water, energy and carbon cycles. If these functions are ignored, planners will be unable to assess, adapt to or mitigate the impacts of changing land cover and climate. Our call to action targets a reversal of paradigms, from a carbon-centric model to one that treats the hydrologic and climate-cooling effects of trees and forests as the first order of priority. For reasons of sustainability, carbon storage must remain a secondary, though valuable, by-product. The effects of tree cover on climate at local, regional and continental scales offer benefits that demand wider recognition. The forest- and tree-centered research insights we review and analyze provide a knowledge-base for improving plans, policies and actions. Our understanding of how trees and forests influence water, energy and carbon cycles has important implications, both for the structure of planning, management and governance institutions, as well as for how trees and forests might be used to improve sustainability, adaptation and mitigation efforts. publisher: Elsevier articletitle: Trees, forests and water: Cool insights for a hot world journaltitle: Global Environmental Change articlelink: http://dx.doi.org/10.1016/j.gloenvcha.2017.01.002 content_type: article copyright: © 2017 The Author(s). Published by Elsevier Ltd. ispartof: Global Environmental Change vol:43 pages:51-61 status: published

Published

2017

9. Strategies trees use to overcome seasonal water limitation in an agroforestry system in semiarid West Africa

Author

Hjalmar Laudon, Ulrik Ilstedt, A. Bargués Tobella, Gert Nyberg, H. R. Bazié, Jules Bayala, and Niles J. Hasselquist

Subjects

Wet season, 010504 meteorology & atmospheric sciences, Ecology, Agroforestry, business.industry, 04 agricultural and veterinary sciences, Aquatic Science, 01 natural sciences, Water balance, Agriculture, Abundance (ecology), Dry season, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Soil horizon, Environmental science, business, Water content, Ecology, Evolution, Behavior and Systematics, Groundwater, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Agroforestry parklands, in which annual crops are grown under scattered mature trees, constitute the most prevalent farming system in semiarid West Africa, covering vast areas of land. The most dominant tree species in these systems is Vitellaria paradoxa, an indigenous tree to West Africa. Despite the importance of this tree in the region, no study to our knowledge has examined its sources and patterns of water uptake. In this study, we used oxygen stable isotopes at natural abundance levels to investigate water sources used by V. paradoxa both in the dry and wet season in an agroforestry parkland in Burkina Faso. We found that during the wet season soil moisture was highest near the soil surface (

Published

2017

10. Patterns of water infiltration and soil degradation over a 120-yr chronosequence from forest to agriculture in western Kenya

Author

J. Kinyangi, Gert Nyberg, Ulrik Ilstedt, and A. Bargués Tobella

Subjects

Agronomy, Soil biodiversity, Agriculture, business.industry, Agroforestry, Soil retrogression and degradation, Chronosequence, Environmental science, Soil carbon, business

Abstract

Soil degradation is commonly reported in the tropics where forest is converted to agriculture. Much of the native forest in the highlands of western Kenya has been converted to agricultural land in order to feed the growing population, and more land is being cleared. In tropical Africa, this land use change results in progressive soil degradation, as the period of cultivation increases. Sites that were converted to agriculture at different times can be evaluated as a chronosequence; this can aid in our understanding of the processes at work, particularly those in the soil. Both levels and variation of infiltration, soil carbon and other parameters are influenced by management within agricultural systems, but they have rarely been well documented in East Africa. We constructed a chronosequence for an area of western Kenya, using two native forest sites and six fields that had been converted to agriculture for varying lengths of time. We assessed changes in infiltrability (the steady-state infiltration rate), soil C and N, bulk density, δ13C, and the proportion of macro- and microaggregates in soil along a 119 yr chronosequence of conversion from natural forest to agriculture. Infiltration, soil C and N, decreased rapidly after conversion, while bulk density increased. Median infiltration rates fell to about 15 % of the initial values in the forest and C and N values dropped to around 60 %, whilst the bulk density increased by 50 %. Despite high spatial variability in infiltrability, these parameters correlated well with time since conversion and with each other. Our results indicate that landscape planners should include wooded elements in the landscape in sufficient quantity to ensure water infiltration at rates that prevent runoff and erosion. This should be the case for restoring degraded landscapes, as well as for the development of new agricultural areas.

Published

2011