Plastic Hotspot Mapping in Urban Water Systems

Reducing plastic pollution in rivers, lakes, and oceans is beneficial to aquatic animals and human livelihood. To achieve this, reliable observations of the abundance, spatiotemporal variation, and composition of plastics in aquatic ecosystems are crucial. Current efforts mainly focus on collecting data on the open ocean, on beaches and coastlines, and in river systems. Urban areas are the main source of plastic leakage into the natural environment, yet data on plastic pollution in urban water systems are scarce. In this paper, we present a simple method for plastic hotspot mapping in urban water systems. Through visual observations, macroplastic abundance and polymer categories are determined. Due to its simplicity, this method is suitable for citizen science data collection. A first application in the Dutch cities of Leiden and Wageningen showed similar mean plastic densities (111–133 items/km canal) and composition (75–80% soft plastics), but different spatial distributions. These observations emphasize the importance of long-term data collection to further understand and quantify spatiotemporal variations of plastics in urban water systems. In turn, this will support improved estimates of the contribution of urban areas to the plastic pollution of rivers and oceans.

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Stochastic stress-testing approach for assessing resilience of urban water systems from source to tap

10.5194/egusphere-egu21-13284 ◽

2021 ◽

Author(s):

Dionysios Nikolopoulos ◽

Panagiotis Kossieris ◽

Christos Makropoulos

Keyword(s):

Stress Testing ◽

Water Cycle ◽

Spatial Scales ◽

Water System ◽

Water Systems ◽

Distribution Model ◽

Generation Model ◽

Urban Water ◽

Urban Water Systems

Urban water systems are designed with the goal of delivering their service for several decades.&#160; The infrastructure will inevitably face long-term uncertainty in a multitude of parameters from the hydroclimatic and socioeconomic realms (e.g., climate change, limited supply of water in terms quantity and acceptable quality, population growth, shifting demand patterns, industrialization), as well as from the conceptual realm of the decision maker (e.g., changes in policy, system maintenance incentives, investment rate, expansion plans). Because urban water systems are overly complex, a holistic analysis involves the use of various models that individually pertain to a smaller sub-system and a variety of metrics to assess performance, whereas the analysis is accomplished at different temporal and spatial scales for each sub-system. In this work, we integrate a water resources management model with a water distribution model and a water demand generation model at smaller (household and district) scale, allowing us to simulate urban water systems &#8220;from source to tap&#8221;, covering the entire water cycle. We also couple a stochastic simulation module that supports the representation of uncertainty throughout the water cycle. The performance of the integrated system under long term uncertainty is assessed with the novel measure of system&#8217;s resilience i.e. the degree to which a water system continues to perform under progressively increasing disturbance. This evaluation is essentially a framework of systematic stress-testing, where the disturbance is described via stochastically changing parameters in an ensemble of scenarios that represent future world views. The framework is showcased through a synthesized case study of a medium-sized urban water system.AcknowledgementThis research is carried out / funded in the context of the project &#8220;A resilience assessment framework for water supply infrastructure under long-term uncertainty: A Source-to-Tap methodology integrating state of the art computational tools&#8221; (MIS 5049174) under the call for proposals &#8220;Researchers' support with an emphasis on young researchers- 2nd Cycle&#8221;. The project is co-financed by Greece and the European Union (European Social Fund- ESF) by the Operational Programme Human Resources Development, Education and Lifelong Learning 2014-2020.&#8221;

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Urban Water Systems & Floods III

10.2495/friar20 ◽

2020 ◽

Keyword(s):

Water Systems ◽

Urban Water ◽

Urban Water Systems

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Legal Constraints on Urban Water Systems

Journal of the Urban Planning and Development Division ◽

10.1061/jupdaj.0000181 ◽

1973 ◽

Vol 99 (2) ◽

pp. 137-145

Author(s):

Neil S. Grigg

Keyword(s):

Water Systems ◽

Urban Water ◽

Urban Water Systems ◽

Legal Constraints

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MUWS (Microbiology in Urban Water Systems) – an interdisciplinary approach to study microbial communities in urban water systems

Drinking Water Engineering and Science ◽

10.5194/dwes-3-91-2010 ◽

2010 ◽

Vol 3 (2) ◽

pp. 91-99 ◽

Cited By ~ 2

Author(s):

P. Deines ◽

R. Sekar ◽

H. S. Jensen ◽

S. Tait ◽

J. B. Boxall ◽

...

Keyword(s):

Microbial Ecology ◽

Distribution Systems ◽

Water Distribution ◽

Potable Water ◽

Water Distribution Systems ◽

Water Systems ◽

Urban Water ◽

Infrastructure Systems ◽

Urban Water Systems ◽

Sewer Networks

Abstract. Microbiology in Urban Water Systems (MUWS) is an integrated project, which aims to characterize the microorganisms found in both potable water distribution systems and sewer networks. These large infrastructure systems have a major impact on our quality of life, and despite the importance of these systems as major components of the water cycle, little is known about their microbial ecology. Potable water distribution systems and sewer networks are both large, highly interconnected, dynamic, subject to time and varying inputs and demands, and difficult to control. Their performance also faces increasing loading due to increasing urbanization and longer-term environmental changes. Therefore, understanding the link between microbial ecology and any potential impacts on short or long-term engineering performance within urban water infrastructure systems is important. By combining the strengths and research expertise of civil-, biochemical engineers and molecular microbial ecologists, we ultimately aim to link microbial community abundance, diversity and function to physical and engineering variables so that novel insights into the performance and management of both water distribution systems and sewer networks can be explored. By presenting the details and principals behind the molecular microbiological techniques that we use, this paper demonstrates the potential of an integrated approach to better understand how urban water system function, and so meet future challenges.

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