Identifying Surface Runoff Pathways for Cost-Effective Mitigation of Pollutant Inputs to Drinking Water Reservoir

Dąbrowska, Jolanta; Dąbek, Paweł; Lejcuś, Iwona

doi:10.3390/w10101300

Cited by 18 publications

(4 citation statements)

References 46 publications

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“…Correlation of chlorophyll-a (Chl-a) abundance with eutrophication has frequently been investigated using the integration approach of multivariate statistical analysis [4,5]. According to several studies, increased temperature, total precipitation and nutrient runoff are the main factors that enhances the eutrophication process in nature [5][6][7][8]. The nutrient factor is an important factor for predicting the eutrophic level.…”

Section: Introductionmentioning

confidence: 99%

Influencing Factors Analysis of Taiwan Eutrophicated Reservoirs

Putri

Lin

Hsieh

et al. 2020

Water

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Treatment cost and quality of domestic water are highly correlated with raw water quality in reservoirs. This study aims to identify the key factors that influence the trophic state levels and correlations among Carlson trophic state index (CTSI) levels, water quality parameters and weather factors in four major reservoirs in Taiwan from 2000 to 2017. Weather (e.g., air temperature, relative humidity, total precipitation, sunlight percentage and cloud cover) and water quality parameters (e.g., pH, chemical oxygen demand, suspended solids (SS), ammonia, total hardness, nitrate, nitrite and water temperature) were included in the principal component analysis and absolute principal component score models to evaluate the main governing factors of the trophic state levels (e.g., CTSI). SS were washed out by precipitation, thereby influencing the reservoir transparency tremendously and contributing over 50% to the CTSI level in eutrophicated reservoirs (e.g., the Shihmen and Chengchinghu Reservoirs). CTSI levels in the mesotrophic reservoir (e.g., Liyutan Reservoir) had strong correlation with chlorophyll-a and total phosphorus. Results show that rainfall/weather factors were the key driving factors that affected the CTSI levels in Taiwan eutrophicated reservoirs, indicating the need to consider basin management and the impacts of extreme precipitation in reservoir management and future policymaking.

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Section: Introductionmentioning

confidence: 99%

Influencing Factors Analysis of Taiwan Eutrophicated Reservoirs

Putri

Lin

Hsieh

et al. 2020

Water

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“…Smith et al, 2001; R. Smith et al, 2015) and contaminant transport (e.g., Chrétien et al, 2017; Coyne et al, 1995; Peyton et al, 2016; Rakonjac et al, 2022) from agricultural fields to surface waters. In this capacity, surface runoff has been linked to eutrophication and algal blooms (Dolph et al, 2019; Sharpley et al, 1994; Wurtsbaugh et al, 2019), loss of biodiversity (Dudgeon, 2019; Leip et al, 2015) and drinking water pollution (Dąbrowska et al, 2018; Gilliom, 2007; Kool et al, 2023). As surface runoff also leads to soil erosion and contributes to peak discharges in streams and rivers, there is a need for scientists and water managers to assess its occurrence, magnitude, and relative contribution to nutrient and contaminant transport (Massop et al, 2017; van der Velde et al, 2010; Worm et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

DTM resolution controls the accuracy of estimating surface runoff indicators in flat, lowland landscapes

Schaap,

van der Velde,

de Louw

et al. 2024

Hydrological Processes

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Surface runoff plays an important role in contaminant transport, nutrient loss, soil erosion and peak discharges in streams and rivers. Because it is the result of a variety of complex hydrological processes, estimating surface runoff using physically based hydrological models is challenging. Upscaling of physical soil properties is necessary to cope with the limits of computational power in surface runoff modelling. In flat landscapes, the (micro)topographic surface controls the onset and progression of surface runoff on saturated soils during rain events. Therefore, its proper representation is crucial when attempting to model and predict surface runoff. In this study, the influence of microtopography (centimetre scale) on estimations of maximum depression storage (MDS), random roughness (RR) and the connectivity threshold (CT) is explored. These properties are selected because they often serve as surface runoff indicators in hydrological modelling. To characterize microtopography, a terrestrial laser scanner (TLS) is used to generate a digital terrain model (DTM) of the study site with a horizontal spatial resolution of 5 cm. MDS, RR and CT are then calculated and compared to the values generated from the publicly available Dutch national DTM dataset with a resolution of 50 cm. Our results show considerable differences in MDS, RR and CT when calculated for the different input resolution datasets. Using DTMs that do not sufficiently capture microtopography leads to underestimation of MDS and RR, and to overestimation of CT. Our findings indicate that surface runoff indicators, and thereby the surface runoff response of a saturated surface to rainfall events, are defined at scales smaller than the scales of typically available DTMs. Understanding surface runoff through modelling studies therefore requires a framework that accounts for this lack of information arising from using coarser resolution DTMs. We demonstrate a linear relationship between MDS values generated from the different resolution DTMs. This opens the possibility of using empirical scaling relationships between high‐ and lower‐resolution DTMs to account for microtopography. Repetition of our measurements on similar surfaces would contribute to establishing such empirical scaling relationships. Our results should be seen as indicative of flat landscapes and surfaces where centimetre scale microtopography is relevant.

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“…Research related to soil and land management and environmental decision support systems is nowadays facilitated by increasing availability of high-resolution spatial data, remote sensing data and GIS analysis tools. Progressive climate change makes such studies a pressing need [50][51][52][53][54][55]. Current wind erosion models provide detailed knowledge necessary to predict and monitor this phenomenon and to implement effective mitigation measures, and are developed at different temporal and spatial scales using data integration from multiple sources [4,6,56,57].…”

Section: Introductionmentioning

confidence: 99%

Long-Term Impact of Wind Erosion on the Particle Size Distribution of Soils in the Eastern Part of the European Union

Lackóová

Pokrývková

Dufková

et al. 2021

Entropy

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Wind erosion is the leading cause of soil degradation and air pollution in many regions of the world. As wind erosion is controlled by climatic factors, research on this phenomenon is urgently needed in soil and land management in order to better adapt to climate change. In this paper, the impact of wind erosion on the soil surface in relation to particle size distribution was investigated. Changes in percentage of sand, silt and clay fractions based on historical KPP data (1961–1970), LUCAS data base (2009), and field measurements (2016) were analysed in five cadastral areas impacted by wind erosion (Záhorie Lowlands, Slovakia). With the use of GIS tools, models of spatial distribution of sand, silt, clay and erodible fraction (EF) content were developed based on those measurements. Our findings proved that soil texture change driven by wind erosion could happen relatively quickly, and a significant proportion of soil fine particles may be carried away within a few years. The results indicate that the soil surface became much rougher over the period of more than 50 years, but also that the accumulation of fraction of the silt particles occurred in most of the areas affected by the erosive effect.

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Identifying Surface Runoff Pathways for Cost-Effective Mitigation of Pollutant Inputs to Drinking Water Reservoir

Cited by 18 publications

References 46 publications

Influencing Factors Analysis of Taiwan Eutrophicated Reservoirs

Influencing Factors Analysis of Taiwan Eutrophicated Reservoirs

DTM resolution controls the accuracy of estimating surface runoff indicators in flat, lowland landscapes

Long-Term Impact of Wind Erosion on the Particle Size Distribution of Soils in the Eastern Part of the European Union

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