Impact of urbanization on groundwater recharge rates in Dübendorf, Switzerland

Minnig, Morgane; Moeck, Christian; Radny, Dirk; Schirmer, Mario

doi:10.1016/j.jhydrol.2017.09.058

Cited by 118 publications

(84 citation statements)

References 54 publications

(63 reference statements)

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“…Nevertheless, ET sensitivity analysis indicate that increase in urban areas and decrease in forestland can promote R e (PRCC values of −0.1222 and 0.002 for urban and forestland), but these values are not significant. Similar values are found in Minnig, et al [45] and it can most likely explain the R e trend from 1986 to 2013, which increases by 72.29 mm/year.…”

Section: Discussionsupporting

confidence: 89%

“…In Oaxaca, this is evident by a resurgence of forests [43,44]. Similar results to Minnig et al [45] can be found, indicating that urban increases and forest decrease can decrease ET and increases the likelihood of R e , but these results are not significant with PRCC values of −0.122 and 0.002, respectively.…”

Section: Sensitivity Analysissupporting

confidence: 80%

“…The effect of urbanization on water recharge is complex and the impact will depend on the features of the area, construction density, infrastructure to manage storm water, sewage systems, and water supply infrastructure [62]. However, the effect of urban growth can be mitigated by reducing evapotranspiration rates, and other, maybe new, matters may consequentially enhance recharge in some urban environments, such as leaks from sewage and water distribution systems and directing runoff into recharge infrastructure [45,63]. Unfortunately, urban growth is usually caused by population growth, which increases groundwater abstraction to meet the increasing water demand, and this can lead to increasing groundwater depletion.…”

Section: Discussionmentioning

confidence: 99%

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Climate Change, Land Use/Land Cover Change, and Population Growth as Drivers of Groundwater Depletion in the Central Valleys, Oaxaca, Mexico

et al. 2019

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Groundwater depletion is an important problem driven by population growth, land use and land cover (LULC) change, climate change, and other factors. Groundwater depletion generates water stress and encourages unstainable resource use. The aim of this study is to determine how population growth, LULC change, and climate change relate to groundwater depletion in the Alto Atoyac sub-basin, Oaxaca, Mexico. Twenty-five years of dry season water table data from 1984 to 2009 are analyzed to examine annual groundwater depletion. Kriging is used to interpolate the region’s groundwater levels in a geographic information system (GIS) from mapped point measurements. An analysis of remotely sensed data revealed patterns of LULC change during a 34-year (1986–2018) period, using a supervised, machine-learning classification algorithm to calculate the changes in LULC. This analysis is shown to have an 85% accuracy. A global circulation model (GFDL-CM3) and the RCP4.5 and RCP8.5 scenarios were used to estimate the effects of climate change on the region’s groundwater. Estimates of evapotranspiration (using HELP3.5 code) and runoff (USDA-SCS-CN), were calculated. Since 1984, the region’s mean annual temperature has increased 1.79 °C and urban areas have increased at a rate of 2.3 km2/year. Population growth has increased water consumption by 97.93 × 106 m3/year. The volume of groundwater is shrinking at a rate of 284.34 × 106 m3/year, reflecting the extreme pressure on groundwater supply in the region. This research reveals the nature of the direct impacts that climate change, changing LULCs, and population growth have in the process of groundwater depletion.

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Section: Discussionsupporting

confidence: 89%

Section: Sensitivity Analysissupporting

confidence: 80%

Section: Discussionmentioning

confidence: 99%

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Climate Change, Land Use/Land Cover Change, and Population Growth as Drivers of Groundwater Depletion in the Central Valleys, Oaxaca, Mexico

et al. 2019

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“…In addition, some studies in Beijing showed the effects of climate change and urbanization on groundwater recharge [55]. Studies indicated landscape pattern change, due to anthropogenic activities in the process of urbanization, played a major role to groundwater recharge [1,48].…”

Section: The Impacts Of Urbanization On Water Balancementioning

confidence: 99%

WetSpass-Based Study of the Effects of Urbanization on the Water Balance Components at Regional and Quadrat Scales in Beijing, China

Zhang

Liu

Cheng

et al. 2017

Water

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Abstract:China is the largest country in terms of population and its booming urbanization has exerted negative effects on ground-surface hydrological processes at different spatial scales, land-use types, and water balance, such as surface runoff, groundwater recharge, and evapotranspiration. However, it is not yet well understood as to how the modifications of the spatial patterns of landscapes affect the water balance on a regional scale. In this study, the water and energy transfer among soil, plants, and atmosphere (WetSpass) model was applied to evaluate the urbanization effects on the water balance on a regional scale by using Beijing as the case city for this current study. The relationships among impervious surfaces, landscape pattern indices, and water balance components were also quantified. Results indicated built-up land in 2012 was 673 km 2 larger than it in 2000, mostly converted from croplands. WetSpass model also indicated the variation rates of annual average surface runoff, evapotranspiration and groundwater recharge were 7%, 0.4% and −2% in the whole Beijing area, while they reached 52%, 6% and −24% in the urban area of Beijing from 2000 to 2012, respectively. At a city scale, four districts-Dongcheng, Xicheng, Chaoyang, and Haidian-were characterized by higher impervious percentage, as reflected by lower groundwater recharge and higher surface runoff than other districts. At quadrat scale, however, groundwater recharge (surface runoff) was negatively (positively) correlated with impervious percentages. For landscape indices, the Aggregation Index was positively correlated with surface runoff and negatively correlated with groundwater recharge while Patch Density Index, Splitting Index, Patch Richness Density Index, and Shannon's Diversity Index presented opposite relationships. The results of this study can help to develop human knowledge about the impacts of urbanization on hydrological cycles on a regional scale.

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“…However, unlike meteorological phenomena, which have a large discontinuity, groundwater acting as an intermediate medium to surface water is relatively slow in moving and is relatively less sensitive to changes in external factors [12]. Human activities and artificial construction can affect the groundwater system (e.g., recharge, flow paths, water quality [13][14][15]); however, if the anthropogenic influence is not significant, the groundwater level (GWL) displays a periodicity, such as daily, seasonal, or annual change [16][17][18][19], in addition, GWLs can also response to longer teleconnections and climate variability at multiannual, decadal, or longer time scales [20]. It experiences long-term trends of several hours to several months, depending on the depth and aquifer characteristics.…”

mentioning

confidence: 99%

Assessment of Groundwater Drought in the Mangyeong River Basin, Korea

et al. 2018

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When groundwater drought occurs, baseflow discharges to surface-water bodies will be reduced and then domestic and agricultural water usage becomes at risk of insufficient supply. Thus, in this study, several methods for groundwater drought assessment were tested with long-term monitoring water-level data in the study area to preserve groundwater sustainability from drought, principally caused by reduced precipitation and propagated through agricultural drought and groundwater drought. Because of the Monsoon climate on the Korean Peninsula, the groundwater storage (or water-level) is secured until the end of summer, then falls by natural discharge during the dry seasons of autumn, winter and the following spring. Thus, the rainfall in the wet season seems to mainly influence groundwater storage until the spring of the following year. As the groundwater level (GWL) declines due to natural drainage and the use of agricultural water increases by the end of the dry season (October-May), the GWL will become lowered below the critical level. Below this level, sufficient water supply is not secured. Using the Standardized Precipitation Index (SPI), threshold method and 95% probability occurrence method, drought detection and the frequency of drought are compared. Groundwater drought using the threshold method results in more frequent occurrence than using the SPI method. The 95% occurrence method responds to severe drought but it also has weakness in missing the man-induced GWL decline in every spring season. For groundwater drought assessment, an appropriate drought index should be utilized according to climatic conditions and catchment characteristics. In the study area, variations of the both natural and anthropogenic effects are mixed and the threshold method is more suitable as a measure for preventing water resources shortage.

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Impact of urbanization on groundwater recharge rates in Dübendorf, Switzerland

Cited by 118 publications

References 54 publications

Climate Change, Land Use/Land Cover Change, and Population Growth as Drivers of Groundwater Depletion in the Central Valleys, Oaxaca, Mexico

Climate Change, Land Use/Land Cover Change, and Population Growth as Drivers of Groundwater Depletion in the Central Valleys, Oaxaca, Mexico

WetSpass-Based Study of the Effects of Urbanization on the Water Balance Components at Regional and Quadrat Scales in Beijing, China

Assessment of Groundwater Drought in the Mangyeong River Basin, Korea

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