Your search keyword '"van der Ent, Ruud J."' showing total 5 results

1. Decline in Terrestrial Moisture Sources of the Mississippi River Basin in a Future Climate.

Author

Benedict, Imme, van Heerwaarden, Chiel C., van der Ent, Ruud J., Weerts, Albrecht H., and Hazeleger, Wilco

Subjects

WATERSHEDS, WATER storage, MOISTURE, OCEAN temperature, CLIMATOLOGY, WATER supply

Abstract

Assessment of the impact of climate change on water resources over land requires knowledge on the origin of the precipitation and changes therein toward the future. We determine the origin of precipitation over the Mississippi River basin (MRB) using high-resolution (~25 km) climate model simulations for present and future climate (RCP4.5). Moisture resulting in precipitation over the MRB is tracked back in time using Eulerian offline moisture tracking, in order to find out from where this water originally evaporated (i.e., the moisture sources). We find that the most important continental moisture sources are the MRB itself and the area southwest of the basin. The two most relevant oceanic sources are the Gulf of Mexico/Caribbean and the Pacific. The distribution of sources varies per season, with more recycling of moisture within the basin during summer and more transport of moisture from the ocean toward the basin in winter. In future winters, we find an increase in moisture source from the oceans (related to higher sea surface temperatures), resulting in more precipitation over the MRB. In future summers, we find an approximately 5% decrease in moisture source from the basin itself, while the decrease in precipitation is smaller (i.e., lower recycling ratios). The results here are based on one climate model, and we do not study low-frequency climate variability. We conclude that Mississippi's moisture sources will become less local in a future climate, with more water originating from the oceans. [ABSTRACT FROM AUTHOR]

Published

2020

2. Rising Temperatures Increase Importance of Oceanic Evaporation as a Source for Continental Precipitation.

Author

Findell, Kirsten L., Keys, Patrick W., van der Ent, Ruud J., Lintner, Benjamin R., Berg, Alexis, and Krasting, John P.

Subjects

ATMOSPHERIC temperature, METEOROLOGICAL precipitation, WATER storage, CROP yields, CLIMATE change, SOIL moisture

Abstract

Understanding vulnerabilities of continental precipitation to changing climatic conditions is of critical importance to society at large. Terrestrial precipitation is fed by moisture originating as evaporation from oceans and from recycling of water evaporated from continental sources. In this study, continental precipitation and evaporation recycling processes in the Earth system model GFDL-ESM2G are shown to be consistent with estimates from two different reanalysis products. The GFDL-ESM2G simulations of historical and future climate also show that values of continental moisture recycling ratios were systematically higher in the past and will be lower in the future. Global mean recycling ratios decrease 2%–3% with each degree of temperature increase, indicating the increased importance of oceanic evaporation for continental precipitation. Theoretical arguments for recycling changes stem from increasing atmospheric temperatures and evaporative demand that drive increases in evaporation over oceans that are more rapid than those over land as a result of terrestrial soil moisture limitations. Simulated recycling changes are demonstrated to be consistent with these theoretical arguments. A simple prototype describing this theory effectively captures the zonal mean behavior of GFDL-ESM2G. Implications of such behavior are particularly serious in rain-fed agricultural regions where crop yields will become increasingly soil moisture limited. [ABSTRACT FROM AUTHOR]

Published

2019

3. Moisture Source Changes Contributed to Different Precipitation Changes over the Northern and Southern Tibetan Plateau.

Author

Zhang, Chi, Tang, Qiuhong, Chen, Deliang, van der Ent, Ruud J., Liu, Xingcai, Li, Wenhong, and Haile, Gebremedhin Gebremeskel

Subjects

METEOROLOGICAL precipitation, MOISTURE, PLATEAUS, ATMOSPHERIC models, WESTERLIES, HYDROLOGIC cycle

Abstract

Precipitation on the Tibetan Plateau (TP) showed different spatial changes during 1979–2016, with an increasing trend over the northern Tibetan Plateau (NTP) and a slightly negative trend over the southern Tibetan Plateau (STP). The changes in precipitation moisture sources over the NTP and STP are investigated using the improved Water Accounting Model with an atmospheric reanalysis as well as observational precipitation and evaporation data. The results show the region in the northwest (region NW), ranging from the TP to Europe dominated by the westerlies, provides 38.9% of precipitation moisture for the NTP, and the region in the southeast (region SE), ranging from the TP to the Indian Ocean and Indochina dominated by the Asian monsoons, provides 51.4% of precipitation moisture for the STP. For the precipitation increase over the NTP, the SE and TP are the main contributors, contributing around 35.8% and 51.7% of the increase, respectively. The contributions from the SE and TP to the STP are, however, minor and insignificant. Meanwhile, the NW shows a negative trend of −4.2 ± 2.9 mm yr−1 decade−1 (significant at the 0.01 level), which contributes to the negative precipitation trend over the STP. Results during the wet season indicate that moisture sources from the areas dominated by the Asian monsoons have contributed more precipitated moisture for the NTP, but not for the STP. Further analysis reveals that precipitated moisture originating from the Indian subcontinent has increased for the NTP while it has decreased for the STP during 1979–2016. [ABSTRACT FROM AUTHOR]

Published

2019

4. Forest restoration: Transformative trees.

Author

Sheil, Douglas, Bargués-Tobella, Aida, Ilstedt, Ulrik, Ibisch, Pierre L., Makarieva, Anastassia, McAlpine, Clive, Morris, Cindy E., Murdiyarso, Daniel, Nobre, Antonio D., Poveda, Germán, Spracklen, Dominick V., Sullivan, Caroline A., Tuinenburg, Obbe A., van der Ent, Ruud J., Bastin, Jean-Francois, Finegold, Yelena, Garcia, Claude, Mollicone, Danilo, Rezende, Marcelo, and Routh, Devin

Subjects

*FOREST restoration, *CLIMATE change

Published

2019

5. Assessing water stress dynamics of the Amazonian rainforest through root zone storage capacity: A time-series approach.

Author

Singh, Chandrakant, Fetzer, Ingo, Wang-Erlandsson, Lan, and van der Ent, Ruud J.

Subjects

*FOREST resilience, *CLIMATE change, *WATER, *TIME series analysis, *FOREST declines

Abstract

Extended exposure to change in rainfall patterns and permanent land-use change (LUC) have reduced the capability of the forests to withstand any external stresses, also defined as forest resilience loss. Major parts of the Amazon forest is under threat of tipping towards a treeless savanna state due to these changes in rainfall patterns and LUC. This loss in forest resilience thus also prevents the forest to return to its pre-disturbed state of the natural cycle and makes the forest more prone to tipping. Yet, this change in natural cycle is not sudden and involves a certain time lag for the forest system to respond. Previous studies determined the forest resilience, but have only considered precipitation or climatological drought to be the key influencing factor. However, neither are a direct measure of the water stress of the forest and thus do not fully reflect the hydrological dynamics underlying forest resilience loss. This study addresses the research questions: (i) do change in climatic patterns have a significant effect on forest resilience?, (ii) how does the change in rainfall patterns or LUC affect the environmental dynamics of the forest over time?, (iii) whether the quantification of rainfall, root zone storage capacity and LUC patterns at a temporal scale better for understanding the resilience loss of the forest?The present study aims at understanding the complex dynamics of the resilience of the forest system using a time-series approach. Advanced remote sensing resources allow us to determine and understand patterns in the tipping behaviour at a temporal scale as well as to understand the hydrological dynamics and environmental triggers. For this, we combined precipitation data, root zone storage capacity and satellite-based forest cover and LUC data analyzed along a time-series. This is to better represent the resilience loss of the forest towards hydrological interactions and also provide a better understanding of the hydrological process for the forest tipping rather than a statistical relation. Landsat-7 data is ideal for determining the forest change, due to its regional time series availability from early 2000's until today. This study provides a better understanding of the hydrological dynamics of the rainforest by utilizing a time-series approach. Root zone storage capacity represents the water stored in the roots of the forest (a.k.a., water available to the forest) and it is a much better representation for assessing water stress of the Amazonian rainforest than precipitation. Thus, also a better parameter for evaluating forest resilience loss over time. [ABSTRACT FROM AUTHOR]

Published

2019