Spatial Compatibility of Implementing Nature-Based Solutions for Reducing Urban Heat Islands and Stormwater Pollution

Simperler, Lena; Ertl, Thomas; Matzinger, Andreas

doi:10.3390/su12155967

Cited by 15 publications

(7 citation statements)

References 35 publications

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“…Significant funding is available for upgrading and expanding conventional WRF and stormwater infrastructure, as well as natural infrastructure such as wetlands, riparian buffers, urban river parkways, and greenspaces. In addition to improving water quality, combining natural infrastructure with conventional systems can provide a broad array of co‐benefits including improved air quality, better health outcomes through recreation, flood risk reduction, and moderation of extreme heat (Jackson et al, 2014; Meerow & Newell, 2017; Simperler et al, 2020). Building water resilience through IIJA and other investments will, however, require a strategic approach to do the right projects, the right way (ASCE, 2022).…”

Section: Water Quality and Aquatic Ecosystemsmentioning

confidence: 99%

Water supply, waste assimilation, and low‐flow issues facing the Southeast Piedmont Interstate‐85 urban archipelago

Jackson

Wenger

Bledsoe

et al. 2023

J American Water Resour Assoc

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Rapidly growing cities along the Interstate‐85 corridor from Atlanta, GA, to Raleigh, NC, rely on small rivers for water supply and waste assimilation. These rivers share commonalities including water supply stress during droughts, seasonally low flows for wastewater dilution, increasing drought and precipitation extremes, downstream eutrophication issues, and high regional aquatic diversity. Further challenges include rapid growth; sprawl that exacerbates water quality and infrastructure issues; water infrastructure that spans numerous counties and municipalities; and large numbers of septic systems. Holistic multi‐jurisdiction cooperative water resource planning along with policy and infrastructure modifications is necessary to adapt to population growth and climate. We propose six actions to improve water infrastructure resilience: increase water‐use efficiency by municipal, industrial, agricultural, and thermoelectric power sectors; adopt indirect potable reuse or closed loop systems; allow for water sharing during droughts but regulate inter‐basin transfers to protect aquatic ecosystems; increase nutrient recovery and reduce discharges of carbon and nutrients in effluents; employ green infrastructure and better stormwater management to reduce nonpoint pollutant loadings and mitigate urban heat island effects; and apply the CRIDA framework to incorporate climate and hydrologic uncertainty into water planning.

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Section: Water Quality and Aquatic Ecosystemsmentioning

confidence: 99%

Water supply, waste assimilation, and low‐flow issues facing the Southeast Piedmont Interstate‐85 urban archipelago

Jackson

Wenger

Bledsoe

et al. 2023

J American Water Resour Assoc

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“…In the VGS, plant and PGM choice can allow the utilization of different pollutant loads in the irrigation water [60]. Still, a higher effort for planning and design of VGS would be required to integrate the run-off treatment in VGS, whereas a combination of pre-treatment and VGS is less complex [61]. Furthermore, water quality will deteriorate during storage, which is why long periods of storage should already be considered within the treatment requirements [37].…”

Section: Sub-module 3: Qualitymentioning

confidence: 99%

Rainwater Use for Vertical Greenery Systems: Development of a Conceptual Model for a Better Understanding of Processes and Influencing Factors

Prenner

Pucher

Zluwa

et al. 2021

Water

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Vertical greenery systems (VGS) are promoted as a nature-based solution to mitigate the urban heat island effect. In order to ensure the long-term provision of this function, sufficiently available irrigation water is the key element. Currently, potable water is one of the main resources for irrigation of VGS. While rainwater is often mentioned as an alternative, only a few studies investigate the actual application of rainwater for irrigation. In this study a conceptual model is developed to present the processes and influencing factors for a holistic investigation of rainwater use for irrigation. In this model, five sub-modules are identified: the atmospheric, hydraulic, quality, rainwater harvesting and VGS sub-module. The conceptual model depicts which processes and influencing factors are involved in the water demand of VGS. Thus, the conceptual model supports a holistic understanding of the interrelations between the identified sub-modules and their relevance for VGS irrigation with harvested rainwater. The results of this study support the implementation of rainwater harvesting as a sustainable resource for VGS irrigation.

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“…Rural communities also face high energy costs and have the highest per capita GHG emissions on average across the VICC (Krawchenko et al, 2020). Urban areas typically have more extensive mitigation and adaptation measures in place, but experience their own challenges, for example, greater development pressures, storm water management issues, and unique impacts such as urban heat islands (Simperler et al, 2020). They are also important service centres for surrounding areas.…”

Section: Understanding the Vancouver Island And Coastal Communities Rmentioning

confidence: 99%

Scaling up local climate action: A survey of climate policy priorities in the Vancouver Island and Coastal Communities region

Rhodes

Krawchenko

Pearce

et al. 2021

CPP-APC

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Regional planning can help functionally-connected communities share expertise and the costs of climate action and amplify collective concerns and needs to upper-level governments. Understanding communities’ climate impacts, policies and barriers to action is foundational to the development of regional-scale climate planning. In support of a nascent climate strategy in the Vancouver Island and Coastal Communities region of British Columbia, our study employs a web-based survey of local government officials (n=106) to identify the existing climate impacts, policy priorities, barriers, and opportunities that guide climate policy-making in the region, including the impacts of the COVID-19 pandemic. We find that nearly all communities have experienced climate-related impacts and have implemented a variety of climate policies. However, local governments face substantial barriers—including a lack of financial resources, authority and staffing capacity—to pursue climate action and planning.

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Spatial Compatibility of Implementing Nature-Based Solutions for Reducing Urban Heat Islands and Stormwater Pollution

Cited by 15 publications

References 35 publications

Water supply, waste assimilation, and low‐flow issues facing the Southeast Piedmont Interstate‐85 urban archipelago

Water supply, waste assimilation, and low‐flow issues facing the Southeast Piedmont Interstate‐85 urban archipelago

Rainwater Use for Vertical Greenery Systems: Development of a Conceptual Model for a Better Understanding of Processes and Influencing Factors

Scaling up local climate action: A survey of climate policy priorities in the Vancouver Island and Coastal Communities region

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