Search

Your search keyword '"Bouwman, Arno"' showing total 22 results
Start Over Author "Bouwman, Arno" Publication Year Range Last 10 years
22 results on '"Bouwman, Arno"'

2. The potential of global coastal flood risk reduction using various DRR measures.

Author

Mortensen, Eric, Tiggeloven, Timothy, Haer, Toon, van Bemmel, Bas, Le Bars, Dewi, Muis, Sanne, Eilander, Dirk, Sperna Weiland, Frederiek, Bouwman, Arno, Ligtvoet, Willem, and Ward, Philip J.

Subjects
FLOOD risk, FLOOD warning systems, ECONOMIC indicators, VEGETATION management, LEVEES, U.S. dollar
Abstract

Coastal flood risk is a serious global challenge facing current and future generations. Several disaster risk reduction (DRR) measures have been posited as ways to reduce the deleterious impacts of coastal flooding. On a global scale, however, efforts to model the future effects of DRR measures (beyond structural) are limited. In this paper, we use a global-scale flood risk model to estimate the risk of coastal flooding and to assess and compare the efficacy and economic performance of various DRR measures, namely dykes and coastal levees, dry-proofing of urban assets, zoning restrictions in flood-prone areas, and management of foreshore vegetation. To assess the efficacy of each DRR measure, we determine the extent to which it can limit future flood risk as a percentage of regional GDP to the same proportional value as today (a "relative risk constant" objective). To assess their economic performance, we estimate the economic benefits and costs of implementing each measure. If no DRR measures are implemented to mitigate future coastal flood risk, we estimate expected annual damages to exceed USD 1.3 trillion by 2080, directly affecting an estimated 11.5 million people on an annual basis. Low- and high-end scenarios reveal large ranges of impact uncertainty, especially in lower-income regions. On a global scale, we find the efficacy of dykes and coastal levees in achieving the relative risk constant objective to be 98 %, of dry-proofing to be 49 %, of zoning restrictions to be 11 %, and of foreshore vegetation to be 6 %. In terms of direct costs, the overall figure is largest for dry-proofing (USD 151 billion) and dykes and coastal levees (USD 86 billion), much more than those of zoning restrictions (USD 27 million) and foreshore vegetation (USD 366 million). These two more expensive DRR measures also exhibit the largest potential range of direct costs. While zoning restrictions and foreshore vegetation achieve the highest global benefit–cost ratios (BCRs), they also provide the smallest magnitude of overall benefit. We show that there are large regional patterns in both the efficacy and economic performance of modelled DRR measures that display much potential for flood risk reduction, especially in regions of the world that are projected to experience large amounts of population growth. Over 90 % of sub-national regions in the world can achieve their relative risk constant targets if at least one of the investigated DRR measures is employed. While future research could assess the indirect costs and benefits of these four and other DRR measures, as well as their subsequent hybridization, here we demonstrate to global and regional decision makers the case for investing in DRR now to mitigate future coastal flood risk. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

3. The geography of future water challenges : Bending the trend

Author

Ligtvoet, Willem, Bouwman, Arno, Bakkenes, Michel, Beusen, Arthur, van Bemmel, Bas, de Blois, Filip, de Bruin, Sophie, Beije, Ed, Bijlsma, Like, Doelman, Jonathan, Gernaat, David, Janse, Jan, van Puijenbroek, Peter, de Ruitter, Jan, van Rijn, Frank, de Vos, Lotte, Visser, Hans, Sperna Weiland, Frederiek, Eilander, Dirk, Oude Essink, Gualbert, Biemans, Hester, Gulpen, Marijn, Mortensen, Eric, Ward, Philip, Tiggeloven, Timothy, Susnik, Janez, Veerbeek, Wiliam, van Beek, Rens, Wanders, Niko, Bouw, Matthijs, Mo, Ce, Jones, Rennie, Tahseen, Sumaita, Kind, Jarl, Siderius, Christian, ten Brinke, Wilfried, Righart, Annemieke, Ligtvoet, Willem, Bouwman, Arno, Bakkenes, Michel, Beusen, Arthur, van Bemmel, Bas, de Blois, Filip, de Bruin, Sophie, Beije, Ed, Bijlsma, Like, Doelman, Jonathan, Gernaat, David, Janse, Jan, van Puijenbroek, Peter, de Ruitter, Jan, van Rijn, Frank, de Vos, Lotte, Visser, Hans, Sperna Weiland, Frederiek, Eilander, Dirk, Oude Essink, Gualbert, Biemans, Hester, Gulpen, Marijn, Mortensen, Eric, Ward, Philip, Tiggeloven, Timothy, Susnik, Janez, Veerbeek, Wiliam, van Beek, Rens, Wanders, Niko, Bouw, Matthijs, Mo, Ce, Jones, Rennie, Tahseen, Sumaita, Kind, Jarl, Siderius, Christian, ten Brinke, Wilfried, and Righart, Annemieke

Published
2023

4. Modeling compound flood risk and risk reduction using a globally applicable framework: a pilot in the Sofala province of Mozambique

Author

Eilander, Dirk, Couasnon, Anaïs, Sperna Weiland, Frederiek C., Ligtvoet, Willem, Bouwman, Arno, Winsemius, Hessel C., and Ward, Philip J.

Abstract

In low-lying coastal areas floods occur from (combinations of) fluvial, pluvial, and coastal drivers. If these flood drivers are statistically dependent, their joint probability might be misrepresented if dependence is not accounted for. However, few studies have examined flood risk and risk reduction measures while accounting for so-called compound flooding. We present a globally applicable framework for compound flood risk assessments using combined hydrodynamic, impact, and statistical modeling and apply it to a case study in the Sofala province of Mozambique. The framework broadly consists of three steps. First, a large stochastic event set is derived from reanalysis data, taking into account co-occurrence of and dependence between all annual maximum flood drivers. Then, both flood hazard and impact are simulated for different combinations of drivers at non-flood and flood conditions. Finally, the impact of each stochastic event is interpolated from the simulated events to derive a complete flood risk profile. Our case study results show that from all drivers, coastal flooding causes the largest risk in the region despite a more widespread fluvial and pluvial flood hazard. Events with return periods longer than 25 years are more damaging when considering the observed statistical dependence compared to independence, e.g., 12 % for the 100-year return period. However, the total compound flood risk in terms of expected annual damage is only 0.55 % larger. This is explained by the fact that for frequent events, which contribute most to the risk, limited physical interaction between flood drivers is simulated. We also assess the effectiveness of three measures in terms of risk reduction. For our case, zoning based on the 2-year return period flood plain is as effective as levees with a 10-year return period protection level, while dry proofing up to 1 m does not reach the same effectiveness. As the framework is based on global datasets and is largely automated, it can easily be repeated for other regions for first-order assessments of compound flood risk. While the quality of the assessment will depend on the accuracy of the global models and data, it can readily include higher-quality (local) datasets where available to further improve the assessment.

Published
2023

5. The geography of future water challenges:Bending the trend

Author

Ligtvoet, Willem, Bouwman, Arno, Bakkenes, Michel, Beusen, Arthur, van Bemmel, Bas, de Blois, Filip, de Bruin, Sophie, Beije, Ed, Bijlsma, Like, Doelman, Jonathan, Gernaat, David, Janse, Jan, van Puijenbroek, Peter, de Ruitter, Jan, van Rijn, Frank, de Vos, Lotte, Visser, Hans, Sperna Weiland, Frederiek, Eilander, Dirk, Oude Essink, Gualbert, Biemans, Hester, Gulpen, Marijn, Mortensen, Eric, Ward, Philip, Tiggeloven, Timothy, Susnik, Janez, Veerbeek, Wiliam, van Beek, Rens, Wanders, Niko, Bouw, Matthijs, Mo, Ce, Jones, Rennie, Tahseen, Sumaita, Kind, Jarl, Siderius, Christian, ten Brinke, Wilfried, and Righart, Annemieke

Published
2023

9. The potential of global coastal flood risk reduction using various DRR measures.

Author

Mortensen, Eric, Tiggeloven, Timothy, Haer, Toon, van Bemmel, Bas, Le Bars, Dewi, Muis, Sanne, Eilander, Dirk, Weiland, Frederiek Sperna, Bouwman, Arno, Ligtvoet, Willem, and Ward, Philip J.

Subjects
FLOOD risk, FLOOD warning systems, ECONOMIC indicators, VEGETATION management, LEVEES, COST effectiveness
Abstract

Coastal flood risk is a serious global challenge facing current and future generations. Several disaster risk reduction (DRR) measures have been posited as ways to reduce the deleterious impacts of coastal flooding. On the global scale, however, efforts to model the effects of DRR measures (beyond structural) in the future are limited. In this paper, we use a global-scale flood risk model to estimate the risk of coastal flooding, and to assess and compare the effectiveness and economic performance of various DRR measures, namely: dykes and coastal levees, dry-proofing of urban assets, zoning restrictions in flood-prone areas, and management of foreshore vegetation. To assess the effectiveness of each DRR measure, we determine the extent to which they can limit future flood risk as a percentage of regional GDP to the same value as today (the so-called relative-risk constant objective). To assess their economic performance, we estimate the economic benefits and costs. If no DRR measures are taken in the future, we estimate expected annual damages to exceed $2 trillion USD by 2080, directly affecting an estimated 15 million people. Over 90% of sub-national regions in the world can achieve their relative-risk constant targets if at least one of the investigated DRR measures is employed. At the global scale, we find the effectiveness of dykes and coastal levees in achieving the relative-risk constant objective to be 98%, dry-proofing to be 49%, zoning restrictions to be 11%, and foreshore vegetation to be 6%. In terms of direct costs, the overall figure is largest for dry-proofing ($151 billion) and dykes and coastal levees ($86 billion), much more than those of zoning restrictions ($27 million) and foreshore vegetation ($366 million). While zoning restrictions and foreshore vegetation achieve the highest global benefit-cost ratios, they also provide the least benefits overall. We show that there are large regional patterns in both the effectiveness and economic performance of modelled DRR measures. Future research could assess the indirect costs and benefits of these four and other DRR measures as well as their subsequent hybridisation. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

10. NBS in Vulnerable Geographies: Applicability of NBS in socio-economic unequal urban/peri-urban contexts with water-related challenges

Author

Hooimeijer, F.L., Kuzniecow Bacchin, T., Recubenis Sanchis, I., Meneses Di Gioia Ferreira, L., do Nascimento, L.F., Bijlsma, Like, van Rijn, Frank, Bouwman, Arno, and Veerbeek, William

Abstract

To achieve inclusive and sustainable urban development, the introduction of water related Nature Based Solutions (NBS) have proven to be eff ective in specific urban contexts. Different sources point out their contribution to various SDG’s in Europe, Australia and the United States, all of which are regions with high GDP levels with strong institutional contexts. However, in regions that are underdeveloped, have weak institutional contexts, high social and economic inequality and are situated in more vulnerable or extreme landscapes, the so called ‘vulnerable geographies’, the experience with Nature Based Solutions is less extensive (PBL, 2018). This report presents the results of a literature review that aims at providing a first (broad) exploration of NBS in contexts outside the regions mentioned above.

Published
2021

11. Modeling compound flood risk and risk reduction using a globallyapplicable framework: A case study in the Sofala region.

Author

Eilander, Dirk, Couasnon, Anai's, Sperna Weiland, Frederiek C., Ligtvoet, Willem, Bouwman, Arno, Winsemius, Hessel C., and Ward, Philip J.

Subjects
FLOOD risk, LEVEES
Abstract

In low-lying coastal areas floods occur from (combinations of) fluvial, pluvial, and coastal drivers. If these flood drivers are statistically dependent, their joint likelihood might be misrepresented if dependence is not accounted for. However, few studies have examined flood risk and risk reduction measures while accounting for so-called compound flooding. We present a globally-applicable framework for compound flood risk assessments using combined hydrodynamic, impact and statistical modeling and apply it to a case study in the Sofala province of Mozambique. The framework broadly consists of three steps. First, a large stochastic event set is derived from reanalysis data, taking into account co-occurrence of, and dependence between all annual maxima flood drivers. Then, both flood hazard and impact are simulated for different combinations of drivers at non-flood and flood conditions. Finally, the impact of each stochastic event is interpolated from the simulated events to derive a complete flood risk profile. Our case study results show that from all drivers, coastal flooding causes the largest risk in the region despite a more widespread fluvial and pluvial flood hazard. Events with return periods larger than 25 year are more damaging when considering the observed statistical dependence compared to independence, e.g.: 12% for the 100-year return period. However, the total compound flood risk in terms of expected annual damage is only 0.55% larger. This is explained by the fact that for frequent events, which contribute most to the risk, limited physical interaction between flood drivers is simulated. We also assess the effectiveness of three measures in terms of risk reduction. For our case, zoning based on the 2-year return period flood plain is as effective as levees with a 10-year return period protection level, while dry proofing up to 1 m does not reach the same effectiveness. As the framework is based on global datasets and is largely automated, it can easily be repeated for many other regions for first order assessments of compound flood risk. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

12. NBS in Vulnerable Geographies: Applicability of NBS in socio-economic unequal urban/peri-urban contexts with water-related challenges

Author

Hooimeijer, F.L. (author), Kuzniecow Bacchin, T. (author), Recubenis Sanchis, I. (author), Meneses Di Gioia Ferreira, L. (author), do Nascimento, L.F. (author), Bijlsma, Like (author), van Rijn, Frank (author), Bouwman, Arno (author), Veerbeek, William (author), Hooimeijer, F.L. (author), Kuzniecow Bacchin, T. (author), Recubenis Sanchis, I. (author), Meneses Di Gioia Ferreira, L. (author), do Nascimento, L.F. (author), Bijlsma, Like (author), van Rijn, Frank (author), Bouwman, Arno (author), and Veerbeek, William (author)

Abstract

To achieve inclusive and sustainable urban development, the introduction of water related Nature Based Solutions (NBS) have proven to be eff ective in specific urban contexts. Different sources point out their contribution to various SDG’s in Europe, Australia and the United States, all of which are regions with high GDP levels with strong institutional contexts. However, in regions that are underdeveloped, have weak institutional contexts, high social and economic inequality and are situated in more vulnerable or extreme landscapes, the so called ‘vulnerable geographies’, the experience with Nature Based Solutions is less extensive (PBL, 2018). This report presents the results of a literature review that aims at providing a first (broad) exploration of NBS in contexts outside the regions mentioned above., Environmental Technology and Design, Urban Design

Published
2021

13. Global-scale benefit–cost analysis of coastal flood adaptation to different flood risk drivers using structural measures

Author

Tiggeloven, Timothy, primary, de Moel, Hans, additional, Winsemius, Hessel C., additional, Eilander, Dirk, additional, Erkens, Gilles, additional, Gebremedhin, Eskedar, additional, Diaz Loaiza, Andres, additional, Kuzma, Samantha, additional, Luo, Tianyi, additional, Iceland, Charles, additional, Bouwman, Arno, additional, van Huijstee, Jolien, additional, Ligtvoet, Willem, additional, and Ward, Philip J., additional

Published
2020
Full Text
View/download PDF

14. Localising global urban development; simulating local exposure to natural hazards in the global 2UP model

Author

Koomen, Eric, van Huystee, Jolien, van Bemmel, Bas, Bouwman, Arno, Ligtvoet, Willem, Andree, Bo Pieter Johannes, Caruso, G, Gerber, P, Jones, K, Klein, O, Perchoux, C, Spatial Economics, and Tinbergen Institute

Abstract

Future population growth is expected to concentrate in urban agglomerations that are already exposed to numerous natural hazards. It is difficult, however, to assess this increase in risk as natural hazards are often concentrated in space and population growth scenarios tend to be defined at much coarser scales. By combining recently released high-resolution spatial data on land use, population density and natural hazards with a novel, computationally effective simulation approach we analyse global increases in local exposure to two important natural hazards: flood risk and landslides. We develop global spatially explicitp rojections of population change and urban expansion using a land-use and population allocation model. The model is developed in the Geo Data and Model Server (GeoDMS) modelling framework, that also underlies Land Use Scanner and several other operational models of land-use change developed for individual countries, larger river catchment areas and the territory of the European Union. The model disaggregates scenario-based national-level population estimates to a high resolution spatial grid (30 arc seconds). It simulates local population development and urban growth on a global scale. The main steps include: 1) compiling current global population and urban land use data layers; 2) developing projections of future population and urban area growth; 3) defining suitable locations for future development following a logistic regression analysis explaining urban patterns around the globe; 4) allocating future urban area development and population change; 5) assessing exposure to natural hazards. We conclude that on global scale urban development is likely to strongly increase exposure to both floods and landslides. In almost all world regions urban growth during the coming decades is larger in hazard-prone areas than in non-exposed areas. This is especially prevalent for countries in Sub-Saharan Africa and South Asia. In developed countries growth rates are much lower and show far less variation between exposed and non-exposed areas. In our presentation we will discuss the functioning of the model, its calibration and validation and the most interesting outcomes. We will briefly reflect on its usefulness for policymakers, suggesting that the model is best applied in fast developing regions where model-based risk assessments were hitherto impossible because of a lack of data.

Published
2019

15. IAMC Wiki Model Documentation IMAGE

Author

Stehfest, Elke, van Vuuren, Detlef P., Kram, Tom, Bouwman, A.F., Alkemade, J.R.M., Bakkenes, Michel, Bouwman, Arno, den Elzen, Michel, Janse, Jan, Lucas, Paul L., van Minnen, Jelle, Prins, Anne Gerdien, Biemans, H., Muller, Chris, Stehfest, Elke, van Vuuren, Detlef P., Kram, Tom, Bouwman, A.F., Alkemade, J.R.M., Bakkenes, Michel, Bouwman, Arno, den Elzen, Michel, Janse, Jan, Lucas, Paul L., van Minnen, Jelle, Prins, Anne Gerdien, Biemans, H., and Muller, Chris

Published
2020

16. Global scale benefit-cost analysis of coastal flood adaptation to different flood risk drivers

Author

Tiggeloven, Timothy, primary, de Moel, Hans, additional, Winsemius, Hessel C., additional, Eilander, Dirk, additional, Erkens, Gilles, additional, Gebremedhin, Eskedar, additional, Diaz Loaiza, Andres, additional, Kuzma, Samantha, additional, Luo, Tianyi, additional, Iceland, Charles, additional, Bouwman, Arno, additional, van Huijstee, Jolien, additional, Ligtvoet, Willem, additional, and Ward, Philip J., additional

Published
2019
Full Text
View/download PDF

17. Supplementary material to "Global scale benefit-cost analysis of coastal flood adaptation to different flood risk drivers"

Author

Tiggeloven, Timothy, primary, de Moel, Hans, additional, Winsemius, Hessel C., additional, Eilander, Dirk, additional, Erkens, Gilles, additional, Gebremedhin, Eskedar, additional, Diaz Loaiza, Andres, additional, Kuzma, Samantha, additional, Luo, Tianyi, additional, Iceland, Charles, additional, Bouwman, Arno, additional, van Huijstee, Jolien, additional, Ligtvoet, Willem, additional, and Ward, Philip J., additional

Published
2019
Full Text
View/download PDF

18. Global drivers of future river flood risk

Author

Winsemius, Hessel C., Aerts, Jeroen C. J. H., van Beek, Ludovicus P. H., Bierkens, Marc F. P., Bouwman, Arno, Jongman, Brenden, Kwadijk, Jaap C. J., Ligtvoet, Willem, Lucas, Paul L., van Vuuren, Detlef P., Ward, Philip J., Hydrologie, Environmental Sciences, Landscape functioning, Geocomputation and Hydrology, Hydrologie, Environmental Sciences, Landscape functioning, Geocomputation and Hydrology, Water Management, Water and Climate Risk, and Amsterdam Global Change Institute

Subjects
010504 meteorology & atmospheric sciences, Flood myth, business.industry, River flood, Natural resource economics, 0208 environmental biotechnology, Environmental resource management, Climate change, Socioeconomic development, 02 engineering and technology, Environmental Science (miscellaneous), 01 natural sciences, Gross domestic product, 020801 environmental engineering, Geography, Taverne, SDG 13 - Climate Action, Climate model, Environmental impact assessment, business, Risk assessment, Social Sciences (miscellaneous), 0105 earth and related environmental sciences
Abstract

Global river flood risk is expected to increase substantially over coming decades due to both climate change and socioeconomic development. Model-based projections suggest that southeast Asia and Africa are at particular risk, highlighting the need to invest in adaptation measures. Understanding global future river flood risk is a prerequisite for the quantification of climate change impacts and planning effective adaptation strategies1. Existing global flood risk projections fail to integrate the combined dynamics of expected socio-economic development and climate change. We present the first global future river flood risk projections that separate the impacts of climate change and socio-economic development. The projections are based on an ensemble of climate model outputs2, socio-economic scenarios3, and a state-of-the-art hydrologic river flood model combined with socio-economic impact models4,5. Globally, absolute damage may increase by up to a factor of 20 by the end of the century without action. Countries in Southeast Asia face a severe increase in flood risk. Although climate change contributes significantly to the increase in risk in Southeast Asia6, we show that it is dwarfed by the effect of socio-economic growth, even after normalization for gross domestic product (GDP) growth. African countries face a strong increase in risk mainly due to socio-economic change. However, when normalized to GDP, climate change becomes by far the strongest driver. Both high- and low-income countries may benefit greatly from investing in adaptation measures, for which our analysis provides a basis.

Published
2015
Full Text
View/download PDF

19. Global scale benefit-cost analysis of coastal flood adaptation to different flood risk drivers.

Author

Tiggeloven, Timothy, de Moel, Hans, Winsemius, Hessel C., Eilander, Dirk, Erkens, Gilles, Gebremedhin, Eskedar, Loaiza, Andres Diaz, Kuzma, Samantha, Tianyi Luo, Iceland, Charles, Bouwman, Arno, van Huijstee, Jolien, Ligtvoet, Willem, and Ward, Philip J.

Subjects
COST effectiveness, FLOOD risk, PHYSIOLOGICAL adaptation, FLOODS, TWENTY-first century
Abstract

Coastal flood hazard and exposure are expected to increase over the course of the 21st century, leading to increased coastal flood risk. In order to limit the increase in future risk, or even reduce coastal flood risk, adaptation is necessary. Here, we present a framework to evaluate the future benefits and costs of structural protection measures at the global scale, which accounts for the influence of different flood risk drivers (namely: sea-level rise, subsidence, and socioeconomic change). Globally, we find that the estimated expected annual damage (EAD) increases by a factor of 150 between 2010 and 2080, if we assume that no adaptation takes place. We find that 15 countries account for approximately 90% of this increase. We then explore four different adaptation objectives and find that they all show high potential to cost-effectively reduce (future) coastal flood risk at the global scale. Attributing the total costs for optimal protection standards, we find that sea-level rise contributes the most to the total costs of adaptation. However, the other drivers also play an important role. The results of this study can be used to highlight potential savings through adaptation at the global scale. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

20. Global drivers of future river flood risk

Author

Winsemius, Hessel C., Aerts, Jeroen C. J. H., van Beek, Ludovicus P. H., Bierkens, Marc F. P., Bouwman, Arno, Jongman, Brenden, Kwadijk, Jaap C. J., Ligtvoet, Willem, Lucas, Paul L., van Vuuren, Detlef P., Ward, Philip J., Winsemius, Hessel C., Aerts, Jeroen C. J. H., van Beek, Ludovicus P. H., Bierkens, Marc F. P., Bouwman, Arno, Jongman, Brenden, Kwadijk, Jaap C. J., Ligtvoet, Willem, Lucas, Paul L., van Vuuren, Detlef P., and Ward, Philip J.

Abstract

Understanding global future river flood risk is a prerequisite for the quantification of climate change impacts and planning effective adaptation strategies1. Existing global flood risk projections fail to integrate the combined dynamics of expected socio-economic development and climate change. We present the first global future river flood risk projections that separate the impacts of climate change and socio-economic development. The projections are based on an ensemble of climate model outputs2, socio-economic scenarios3, and a state-of-the-art hydrologic river flood model combined with socio-economic impact models4, 5. Globally, absolute damage may increase by up to a factor of 20 by the end of the century without action. Countries in Southeast Asia face a severe increase in flood risk. Although climate change contributes significantly to the increase in risk in Southeast Asia6, we show that it is dwarfed by the effect of socio-economic growth, even after normalization for gross domestic product (GDP) growth. African countries face a strong increase in risk mainly due to socio-economic change. However, when normalized to GDP, climate change becomes by far the strongest driver. Both high- and low-income countries may benefit greatly from investing in adaptation measures, for which our analysis provides a basis.

Published
2016

21. Global drivers of future river flood risk

Author

Hydrologie, Environmental Sciences, Landscape functioning, Geocomputation and Hydrology, Winsemius, Hessel C., Aerts, Jeroen C. J. H., van Beek, Ludovicus P. H., Bierkens, Marc F. P., Bouwman, Arno, Jongman, Brenden, Kwadijk, Jaap C. J., Ligtvoet, Willem, Lucas, Paul L., van Vuuren, Detlef P., Ward, Philip J., Hydrologie, Environmental Sciences, Landscape functioning, Geocomputation and Hydrology, Winsemius, Hessel C., Aerts, Jeroen C. J. H., van Beek, Ludovicus P. H., Bierkens, Marc F. P., Bouwman, Arno, Jongman, Brenden, Kwadijk, Jaap C. J., Ligtvoet, Willem, Lucas, Paul L., van Vuuren, Detlef P., and Ward, Philip J.

Published
2016

Catalog

Books, media, physical & digital resources
See catalog results