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Article

Nature-Based Solutions in Urban Areas: A European Analysis

by
Sara Bona
1,
Armando Silva-Afonso
1,2,
Ricardo Gomes
3,
Raquel Matos
1 and
Fernanda Rodrigues
1,*
1
RISCO—Research Center for Risks and Sustainability in Construction, Department of Civil Engineering, University of Aveiro, 3810-193 Aveiro, Portugal
2
ANQIP—National Association for Quality in Buildings Services, Civil Engineering Department, University of Aveiro, 3810-193 Aveiro, Portugal
3
INESC Coimbra and SMAS de Leiria, Department of Civil Engineering, Polytechnic of Leiria, Campus 2 Morro do Lena—Alto do Vieiro, 2411-901 Leiria, Portugal
*
Author to whom correspondence should be addressed.
Appl. Sci. 2023, 13(1), 168; https://doi.org/10.3390/app13010168
Submission received: 18 November 2022 / Revised: 9 December 2022 / Accepted: 21 December 2022 / Published: 23 December 2022
(This article belongs to the Special Issue Sustainability in Energy and Buildings: Future Perspectives and Challenges)
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Versions Notes

Abstract

:
Currently, the world is facing resource scarcity as the environmental impacts of human intervention continue to intensify. To facilitate the conservation and recovery of ecosystems and to transform cities into more sustainable, intelligent, regenerative, and resilient environments, the concepts of circularity and nature-based solutions (NbS) are applied. The role of NbS within green infrastructure in urban resilience is recognised, and considerable efforts are being made by the European Commission (EC) to achieve the European sustainability goals. However, it is not fully evidenced, in an integrated way, which are the main NbS implemented in the urban environment and their effects. This article aims to identify the main and most recent NbS applied in urban environments at the European level and to analyse the integration of different measures as an innovative analysis based on real cases. For this purpose, this work presents a literature review of 69 projects implemented in 24 European cities, as well as 8 urban actions and 3 spatial scales of implementation at the district level. Therefore, there is great potential for NbS adoption in buildings and their surroundings, which are still not prioritized, given the lack of effective monitoring of the effects of NbS.

1. Introduction

The effects of global climate change are unquestionably among the most considerable problems facing humanity today. The current model of economic development based on fossil fuels and the indiscriminate exploitation of natural resources has brought about a situation in which negative impacts are entering a critical phase. The IPCC (Intergovernmental Panel on Climate Change) Special Report, projects that global warming will reach 1.5 °C between 2030 and 2052 if it continues to increase at the current rate [1]. Reflecting this trend, numerous regional changes in climate are projected to occur, with global warming on the planet, including increasingly extreme temperatures in cities, as well as increases in the frequency, intensity, and amount of heavy rain and droughts [1].
Cities are major contributors to climate change. Today, more than half of the world’s population lives in urban settlements, and the United Nations (UN) predicts that by 2050, this urban share will reach 70% [2]. At present, cities are responsible for producing 50% of global waste [3], approximately 70% of greenhouse gas (GHG) emissions [2,4], and 75% of energy and natural resource consumption [4], generating increasing pressure on rural areas and natural ecosystems to guarantee the supply of water, energy, and food, as well as for the removal of waste [5], as the world’s cities occupy only 3% of the terrestrial landscape [6].
Following this trend, the likely scenario for the coming decades is a series of global challenges related to resource depletion as a result of climate change associated with increased pollution. Due to the negative impacts that global development and consumption impose on contemporary society, new global sustainability frameworks have been adopted in recent years, such as the UN 2030 Agenda for Sustainable Development and its corresponding Sustainable Development Goals (SDGs) [2]. This and other international agreements seek to establish goals, guidelines, and action models to ensure a liveable planet and a more just and sustainable society. In this context, strategic urban planning, in association with sustainability, represents a fundamental tool for the mitigation and adaptation of cities to new and emerging challenges.
As defined by the International Union for Conservation of Nature (IUCN), NbS are actions that protect, sustainably manage, and restore natural or modified ecosystems while addressing social challenges and providing benefits for both human well-being and biodiversity [7]. This mechanism, which transfers nature to cities [5], has great potential to respond to and minimize the effects of climate change in urban spaces, creating alternatives that return natural elements to the urban environment [8] that were previously disappearing with the growth and development of cities.
In order to facilitate the conservation and recovery of ecosystems and to transform cities into more sustainable, intelligent, regenerative, and resilient environments, the concepts of circular economy (CE) and nature-based solutions (NbS) are applied. NbS and the CE are interconnected, side-by-side conceptions for the development of renaturalized and circular cities [9,10].
This article presents research on the concept and application of NbS at the urban level. Recognising the NbS theme as a key element in achieving the European sustainability goals the following research question was formulated: “What are the recent and main NbS initiatives and practices being applied in urban environments in the European Union aiming at resilience and circularity in cities?”. To answer this question, a study was carried out through applied research with a qualitative approach around textual elements and considering the predefined content analysis methodology [11]. In a logical sequence, the fundamental phases of qualitative analysis were respected: preanalysis; exploration of the material; and treatment of results, including inference and interpretation.
In the sequence of the literature review, some knowledge gaps remain regarding the effectiveness of NbS in the urban environment, with an emphasis on short-term actions and long-term sustainability goals [12]. NbS have been promoted as a key tool in the search for innovative solutions to manage natural systems and to balance benefits for nature and society. However, the concepts and their practical applications remain imprecise and fragmented due to ambiguities linked to the integration of various scientific fields and the lack of clear standards in the NbS concept [13,14]. In recent years, several attempts have been made to define and clarify the actions inspired and driven by nature, as well as the associated benefits [12,13,14,15,16,17]. Therefore, it is possible to identify that the concept and the theme of NbS are still recent and are in an evolutionary process. Many studies point to the lack of methodology for the compilation and systematic evaluation, in a comprehensive and integrative way, of NbS knowledge [18,19]. Barriers have also been identified regarding the uncertainties concerning the performance, functionality, and implementation of NbS [20]. The ecosystem approach aligned with NbS initiatives is an example of an integrated principle and concept essential to achieving social and environmental sustainability [14]. Recognising that NbS are measures that provide multiple benefits is key to ensuring that NbS interventions deliver far-reaching benefits rather than unilateral outcomes [21]. Thus, the importance of this article consists of the integration of NbS initiatives in the urban environment, considering the performance of the provided ecosystem services. In this work, we identify and present the main and most recent NbS practices implemented in urban environments at the European scale and analyse the complementarity and integration of various measures, presenting an innovative analysis based on real-world examples. This study contributes to an improved understanding of NbS and provides a synthesis of knowledge and applicability of NbS, emphasizing the complementarity of NbS measures in the urban environment.

2. Sustainability in the Built Environment

2.1. Circular Economy

An important aspect of approaching contemporary urban systems is circularity. The transition to a CE is fundamental to face environmental challenges, as cities will have to play an essential role in this economic model. CE is a concept that directly contrasts with the traditional economic model, characterized by a predominantly linear pattern. CE can be defined as a production and consumption model that includes, whenever possible, sharing, leasing, reusing, repairing, refurbishing, and recycling of existing materials and products [22] with the aim of minimizing waste and making the most of resources [5]. In this way, the product life cycle can be extended with the expectation of fostering a closed-loop market. In a circular system, the input and waste of resources, emissions, and energy consumption are minimized by decelerating and narrowing energy and material cycles [5]. This means rethinking current paradigms, aiming at a greener and more sustainable economy.
In 2020, the EC adopted the new Circular Economy Action Plan (CEAP), which constitutes one of the main elements of the European Green Deal, Europe’s agenda for sustainable growth [23]. According to CEAP, the Commission has committed itself to launch a new comprehensive Strategy for a Sustainable Built Environment to increase material efficiency and reduce the climate impacts of the built environment, particularly by promoting the principles of circularity throughout the life cycle of buildings. For this purpose, the fields of energy efficiency, resource efficiency, construction, and demolition waste management should be addressed in a sustainable strategy [23]. Implementing and addressing CE principles at the various stages of a building’s life cycle is of utmost importance in the transition to a circular and dynamic built environment, as the way buildings are designed is critical to how they are used and the impact they have on their surroundings [9].

2.2. Nature-Based Solutions

NbS is a new concept that started to be used at the beginning of the 21st century and was later adopted by several global institutions [24]. NbS has evolved as an “umbrella” concept [25,26] that incorporates several existing concepts and practices [27] that can be applied to the strategic dimension, spatial planning dimension, soft engineering dimension, and performance dimension (Figure 1) [25]. The most recent EC report on NbS states that this concept embodies new ways of approaching socioecological adaptation and resilience, with equal confidence in the social, environmental, and economic domains [25].
NbS provide several beneficial ecosystem services [5,26], such as their ability to store carbon and regulate water flow [29] in order to achieve desired outcomes in urban spaces, such as disaster risk reduction, microclimate regulation, improved human health, and socially inclusive green growth [5,8,28,29].
In this sense, NbS can help in facing social and economic challenges within the sustainable development paradigm, providing benefits that meet—directly and indirectly—SDG 2, SDG 3, SDG 6, SDG 8, SDG 10, SDG 11, SDG 12, SDG 13, SDG 14, and SDG 15 [28]. Indeed, the ability to simultaneously achieve multiple SDGs is a big part of what makes NbS implementation attractive [25,30].
One of the challenges that can be addressed using NbS is the urban heat island (UHI) effect, with respect to which these solutions can be effective in mitigating air pollution and reducing air temperature in urban areas [10,31]. Systems and technologies integrated into nature-inspired construction projects (green buildings), such as green roofs and green walls—green facades, vertical gardens, or living walls—are opportunities to foster a transformation in buildings by creating effective NbS solutions [9,10,25,29], reducing thermal stress in cities, and improving air quality [28,31]. NbS also offer synergies in reducing flood and drought risks while improving water quality and quantity [29], meeting the objectives of various European regulations such as the Floods Directive and the Water Framework Directive [28,32].
In general, NbS can be grouped according to sectors and thematic areas of social importance [28,33]: (I) water management, (II) forests and forestry, (III) agriculture, (IV) urban areas, and (V) coastal areas (Table 1).
The EU’s ambition is to establish Europe as an inspiration and world leader in markets for NbS through research (development of a technical and scientific evidence base for NbS) and innovation (development of methods and identification of innovative best-practice approaches) [29,35]. The main objective in the field of implementation is to improve the visibility of NbS at all stages, developing demonstration sites and experiences (practical examples on a large scale) to ensure and share the relevance of these initiatives in the current market [29]. The EC has made significant efforts in promoting and disseminating NbS knowledge, experiences, and results [35] through publications, programs, and a network of NbS projects funded by Horizon 2020 (H2020 Research and Innovation Program, 2014–2020) [36]. Continuing the investments and work carried out in recent years, the EU recently launched “HORIZON Europe” (2021–2027). This is the EU’s flagship research and innovation funding program (budget of EUR 95.5 billion) [37], which promises to prepare Europe to tackle climate disruption, accelerate the transition to a healthy and prosperous future, and apply solutions for resilience that will lead to the transformation of society. It also aims to accelerate soil and food health, as well as climate-neutral smart cities by 2030, among other mission areas [38]. The HORIZON Europe program emphasizes the acceptance and integration of NbS initiatives in public and private decision making [35].

2.3. Nature-Based Solutions in the Built Environment

Around the world, NbS have been developed and are being implemented to respond to current challenges and improve the quality of urbanized areas and, consequently, human health and well-being [26]. For example, in the context of the COVID-19 pandemic, NbS have been shown to provide additional health benefits, providing both physical and mental relief [39]. As a result, there has been an increase in green roof initiatives, aiding biodiversity and the expansion of urban agriculture [40]. Therefore, designing and building nature-based restorative spaces emerges as a potential response [35] in resolving public health crises [40,41].
In its annual publication, the Global Alliance for Buildings and Construction (GlobalABC) reported on the global progress of the construction and building sector towards meeting international goals with respect to climate change. According to the 2021 Global Status Report for Buildings and Construction, in 2020, the construction and operation of buildings were responsible for 37% of global energy-related carbon dioxide (CO2) emissions, in addition to the sector’s energy consumption, representing approximately 36% of global demand [42]. The document also indicates that if the effect of the COVID-19 pandemic is excluded (due to the decrease in economic activity in the period under analysis), the level of decarbonization in 2020 was only 40% of the 2050 reference path to reach the targets set out in the Paris Agreement [42]. For an alignment with the SDGs, the construction and building sector must incorporate concepts related to the CE in order to decrease the demand for building materials and reduce embodied carbon, in addition to the adoption of NbS that improve the resilience of the construction industry [43].
The use of NbS can be understood as an essential urban planning tool for cities to increase their resilience in response to climate change. In particular, in urban areas, multifunctionality makes these actions references for cities to achieve the transition from a linear to circular model, as NbS offers several benefits with respect to the main challenges highlighted in urban circularity: restoring and maintaining the water cycle (by rainwater management); water and waste treatment, recovery, and reuse; nutrient recovery and reuse; material recovery and reuse; food and biomass production; energy efficiency and recovery; and building system recovery [44].
Furthermore, the implementation of NbS in an urban environment is a central element of European strategies [25] and is directly aligned with the objectives of the 2030 Agenda [28,45] as a way to achieve sustainable cities and communities while playing an active role in the strategic implementation and fulfilment of the SDGs [28], specifically “SDG 11—Sustainable cities and communities: make cities and human settlements inclusive, safe, resilient and sustainable” and “SDG 13—Climate action: take urgent action to combat climate change and its impacts” [25,45]. In the built environment, NbS implementation can be integrated into three levels [10] characterized by:
  • Green building materials: raw natural materials taken from the biological cycle. Their processing must have minimal negative effects on the environment, with low incorporated consumption of energy, carbon, water, and chemicals. Optimal production and construction methods should allow for the safe return of nutrients to the ecosystem after the material use cycle.
  • Green building systems (systems for the greening of buildings), including green and living components integrated into structures and used for the afforestation of buildings, for example, green roofs, facade greenery, living walls, and house trees.
  • Green building sites (green urban sites): areas of land adjacent to buildings (e.g., pocket parks, urban plazas, and small community parks), which play a blue–green role in cities, emphasizing the value of open spaces with vegetation and water-sensitive urban design. These environments provide a variety of ecosystem services and reflect resilient and regenerative approaches to addressing diverse challenges such as reducing noise pollution and mitigating climate change.
Inspired and based on nature and the adoption of ecosystem principles, NbS aim to recover and regenerate natural processes and flows in the urban environment at different scales (Table 2). NbS address social challenges at a range of spatial scales—local, regional, and global [26]—which can be classified according to the level of interventions [34], representing actions from buildings or plots, including districts or neighbourhoods, to cities and beyond (other larger interventions) [46,47].
To differentiate the scale and scope of interventions, another approach used for NbS classification—for implementation in urban environments—is the proGIreg projects (funded by the EC under the Horizon 2020 programme). Specifically, NbS are classified into eight different types [48]:(1) leisure activities and clean energy on former landfills, (2) new regenerated soil, (3) community-based urban farms and gardens, (4) aquaponics, (5) green walls and roofs, (6) accessible green corridors, (7) local environmental compensation processes, and (8) pollinator biodiversity.

3. Materials and Methods

An initial literature search of 69 case studies was carried out in the Oppla repository (https://oppla.eu/ (accessed on 5 September 2022)), a platform that serves as an EU information centre for knowledge and exemplary NbS cases; proGIreg (https://progireg.eu/ (accessed on 20 September 2022)) “Living Labs” projects for the implementation of innovative NbS in pioneering and strategic cities with the potential for the development of “productive Green Infrastructure for post-industrial urban regeneration”; and CLEVER Cities (https://clevercities.eu/ (accessed on 30 September 2022)) nature-based intervention projects in key city regions to promote urban regeneration. With this selection, it was possible to analyse case studies in different places in Europe, making it possible to enrich the research due to the diversity of realities. Altogether, these are projects with a particular focus on thematic coverage of the urban implementation of NbS and have received funding from the EU’s Horizon 2020 innovation action programme.
Through the applied methodology, it was possible to analyse projects for 24 different European cities. The reported solutions and the knowledge acquired about NbS in different locations in the EU were analysed and acquired through the investigation of empirical knowledge, and data collection was performed through indirect and online observation and made available for public access.
The second stage of the research is to enrich the initial stage and to assist in the construction of scientific knowledge about the main strategies and current interventions with respect to urbanization in the implementation and development of more resilient and environmentally sustainable cities, consisting of the selection of keywords and adequate databases to search. The keywords used in the research were: “nature-based solutions” and the name of the cities under analysis (24 mentioned above). The sets were sequentially combined in “Scopus” and “Web of Science” by searching the “All fields” scope using the Boolean operator “AND” between sets of keywords. Then, some criteria were defined to narrow down the information, as presented below: (1) date: only articles published in the last five years were included; (2) source type: only peer-reviewed journals were considered; and (3) language: only articles written in English were included in the study. In terms of eligibility criteria, any article that provided relevant information regarding NbS in the city under study was included in the analysis, i.e., information was accepted indifferently from interested parties (for example, research institutions, local organisations, or public authorities) at all scales (building, district, or city) and during each stage of urban development (planning, design, implementation, or management).
All textual materials were gathered, compiled, and consolidated (from September to November 2022) to provide an overview of recurring NbS themes. This task was aided by the development of an Excel datasheet, which included the following elements: location and country, period or project end projections, title/name of project/program, main objectives, main impacts, project name or name of NbS actions, the spatial scale of NbS implementation, classification of types of urban actions for NbS, types of ecosystem services, classification of ecosystem services, types of benefits, and classification of multiple benefits in the implementation of NbS actions. Then, the qualitative information was synthesized and refined.
As it is a new concept, there is no unique and unambiguous identification and classification method for NbS [34]. Given the lack of standardized criteria and taking the urban context of adaptation to climate change in nature-based planning into account, it was considered appropriate to classify NbS actions implemented in an urban environment through a methodology defined by the Naturvation project (funded by the EU’s Horizon 2020 research and innovation programme) [49] and the categories shown in Table 1. Therefore, eight different types of NbS classification were established for the urban sustainability challenges of a city, district, or building, namely (1) blue infrastructure, (2) community gardens and allotments, (3) green areas for water management, (4) green buildings, (5) infrastructure with green features, (6) parks and urban forests, (7) renaturing of abandoned areas and opportunity plots, and (8) urban gardens and green spaces between buildings. For the differentiation of the spatial scale, on which the impacts of NbS were evaluated, together with the type of NbS adopted and the dimension (micro, meso, or macro) in which it is implemented, and respecting the classification shown in Table 2, the following scenarios were established: (1) district or neighbourhood; (2) regional, metropolitan, or urban; and (3) street, plot, or building. Regarding the categorization of the different urban ecosystem services and multiple benefits in the implementation of NbS actions, when not made available by the program, this factor was evaluated according to the EC manuals published by and available from the “Publications Office of the European Union” [50,51,52].

4. Results

As the focus of the research—current initiatives to implement NbS in urban areas in the European panorama—it was possible to analyse case studies in the following cities: Amsterdam (The Netherlands), Bari (Italy), Berlin (Germany), Bilbao (Spain), Bristol (United Kingdom), Budapest (Hungary), Dresden (Germany), Dublin (Ireland), Dortmund (Germany), Edinburgh (United Kingdom), Genk (Belgium), Hamburg (Germany), Linz (Austria), Lisbon (Portugal), Ljubljana (Slovenia), London (United Kingdom), Milan (Italy), Oradea (Romania), Poznan (Poland), Rotterdam (The Netherlands), Szeged (Hungary), Turin (Italy), Utrecht (The Netherlands), and Zagreb (Croatia). The first step was to analyse the country of origin of each study (Figure 2). The colours in Figure 2 indicate the countries and the respective number of cities analysed. The most representative country was Germany, with four cities, followed by Italy, The Netherlands, and the United Kingdom, with three cities each, and Hungary, with two cities. The remaining countries include only one city under study.
Following the preliminary analysis, Figure 3 represents the distribution of the number of NbS projects implemented by European countries. The most representative countries are Italy and the United Kingdom, followed by Germany and The Netherlands.
Table 3 presents a complete list of cities with exploratory cases and experimental applications related to NbS. This list includes the identification data, main objectives, and impacts of specific and/or combined NbS initiatives and actions that support urban circular thinking and the use NbS concepts in the built environment. In the last column, the articles are identified after the selection of data and comprehensive information under the research objective and methodology implemented.
Figure 4 presents the unfolding of NbS actions classified as interventions in an urban environment. A total of 69 projects (singular or combined) were identified, corresponding to 185 actions implemented in the 24 cities under analysis. The large number of actions compared to the number of samples (cities and projects) is because, in most cases, nature-based interventions fall into more than one domain. This holistic and integrative nature of NbS has been highlighted in the literature, emphasizing its multifunctionality as the main advantage over traditional (grey) infrastructure-based solutions [101]. For example, in Budapest, in the creation of pocket parks as an initiative to increase the number of green areas in a district of the city, they are multifunctional; that is, they provide spaces for small-scale food production and the possibility of recreation and community sharing through gardening, assisting in water retention and the region’s microclimate [53]. In this case, the project is characterized by all relevant types of NbS, namely “infrastructure with green features”, “parks and urban forests”, “community gardens and allotments”, and “green areas for water management”.
The types of NbS most represented in the built environment are “infrastructure with green features” (18%), “parks and urban forests” (20%), and “green areas for water management” (17%). On the other hand, the least represented is “urban gardens and green spaces between buildings” (3%).
Figure 5 represents the spatial distribution of NbS implementation scales in urban space. Analysis shows that the NbS implemented on the “district or neighbourhood” scale correspond to 43% of the total sample, followed by “regional, metropolitan, or urban” and “street, plot, or building”, representing 35% and 22%, respectively.
From the classification of different urban ecosystem services and multiple benefits in the implementation of NbS actions, according to which 69 projects were analysed, it was possible to compile the data and represent them through Figure 6, Figure 7, Figure 8 and Figure 9.
The most prevalent NbS challenges addressed in the survey concern issues of increasing sustainable urbanization (38%), followed, in equivalence, by developing climate change adaptation and improving risk management and resilience (28%) and restoring ecosystems and their functions (26%). Challenges related to the development of climate change mitigation were less common among the analysed case studies, corresponding to 8% of NbS projects. In particular, the types of benefits most highlighted were “increasing infiltration”, “reduce run-off”, “reducing the temperature at meso or micro-scale”, “carbon sequestration and storage”, “changing image of the urban environment”, and “increase biodiversity”.
The last type of characterization (ecosystem services provided) includes five different categories, where, according to the results of the analyses, the most frequently provided services among the analysed NbS are related the interaction of more ecosystem-based approaches (23%), for example, natural water retention measures (NWRM) and ecosystem-based disaster risk reduction (Eco-DRR); green space management (20%); and air quality (18%). Fewer ecosystem services related to sustainable urban regeneration were provided, corresponding to 5% of NbS projects. In particular, most case studies offer services equivalent to “water flow regulation and runoff mitigation”, “green infrastructure”, “ecosystem-based adaptation”, and “habitat and gene pool regulation”, designating the crucial role of these practices for the environment.

5. Discussion

The EU has been actively engaged with the research community to better address NbS knowledge and technology gaps through its framework programs and its research and innovation strategy, namely Horizon 2020 and HORIZON Europe. Reflecting on its leading role in the spread of NbS [18,35], the EC, through its funded programs, is focused on the development and availability of a knowledge base on NbS. Indeed, many European cities and regions have undertaken NbS-inspired initiatives to address a range of societal challenges through the delivery of essential ecosystem services. This is evident in fourteen countries represented by the total sample of case studies analysed with different scenarios and applications of NbS in the urban environment.
The articles from eligible scientific journals, in their entirety, did not show similarities with the present study, confirming that the NbS theme is still evolving and that there is a lack of methods for systematic, comprehensive, and integrative compilation and assessment of NbS knowledge [18,19]. It is noted that much of the ongoing efforts are focused on addressing NbS solutions in unique ways for the evapotranspiration performance of vertical vegetation systems [57], for the emotional reaction to urban vegetation [82], for CO2 reduction in a hermetic museum environment [83], or for its potential to attract young generations [95]. These approaches are important to answer several critical gaps in NbS knowledge; however, barriers have been identified regarding uncertainties in terms of the performance, functionality, and implementation of NbS [20]. Therefore, an integrated approach to the provided ecosystem services is fundamental, assigning the crucial role of NbS practices to the environment and mitigation of climate change impacts, as well as the performance of NbS related to the identified challenges [19].
During the second stage of the research (consultation of the “Scopus” and “Web of Science” databases), a considerable number of cities were not addressed and cited in published articles on NbS under penalty of the exclusion and eligibility criteria previously defined in the Methodology section. Thus, it was not possible to find articles that contained relevant information for the analysis of NbS actions in the following cities: Bari, Bilbao, Bristol, Budapest, Dortmund, Dresden, Edinburgh, Linz, Oradea, and Zagreb. The rest of the documents were important for classifying the different NbS actions, their benefits, and ecosystem services associated with the urban environment.
Urban environments are associated with a significant number of actions that focus on changing green infrastructure towards multifunctionality and improved quality, whereas actions to support citizens in its use are lacking [89]. Nature-based interventions require a collaborative approach to their planning and implementation [93]. The urban environment constitutes opportunities for the participation of citizens and society actors in the formation and planning of green spaces [54], with a significant importance of being at the centre of policy formulation [71]. Therefore, the implementation of NbS in urban contexts requires the cooperation of different public and private actors to manage these processes, directly contributing to learning among the participants, as evidenced in Hamburg within the scope of the CLEVER Cities project [68].
In the city of Milan, after the adoption of NbS, a study pointed out the importance of NbS interventions in citizens’ perceptions of their well-being, general health, and a strong sense of belonging to the neighbourhood [80]. These benefits correspond to the increase in sustainable urbanization, as evidenced in the results presented for the multiple NbS benefits.
Studies have identified that knowledge about indicators is needed to monitor and evaluate the implementation of NbS [60,65], with the aim of transformation into a strategic green–blue link in cities, although this remains a considerable challenge to overcome [63]. Different approaches to urban planning, particularly the use and guarantee of effective NbS, shape the design of cities that are more resilient to the effects of climate change in terms of increasing the density of green areas and ensuring permeability, influencing cooling capacity [88], and the impact of floods during extreme weather events [97]. Therefore, it is of great importance to integrate ecological components into a real dynamic green infrastructure [86] throughout the design process when implementing NbS [92,102].
NbS represent an effective tool to improve ecosystem services, value environmental and sociocultural issues [84], and offer integrated benefits with environmental and water management practices [71]. Actions such as “blue infrastructure” and “green areas for water management” have been implemented in the urban environment. The highlighted benefits include “improve connectivity and functionality of green and blue infrastructures”, “reduce run-off”, and “increasing infiltration”. With respect to the provided ecosystem services, the highlights are “water flow regulation and runoff mitigation”, “flood control”, and “natural water retention measures”.
Many studies emphasize the potential and effectiveness of NbS adoption in urban water management [66,74,75,76,77,96,98]. The activities proposed for Hamburg, among others, focus on the management of rainwater, which will be used in irrigation systems for plantation areas, increasing the efficiency of rainwater reuse [66]. Similarly, the Leidsche Rijn water system in Utrecht is a sustainable, nature-based, closed-loop surface water system providing clean, clear surface water and supporting biodiversity and climate adaptation. The system includes NbS components in urban infrastructure regimes such as bioswales, ecological water banks, a network of canals, buffer lakes, dams with water gates, water pump stations, and permeable paving [98]. Ljubljana stands out in terms of land use planning and urban water management in the city, with retention areas that are attractive for leisure activities and have a positive impact on the microclimate [76]. Efficient waste management in Ljubljana is an example of the promotion of circularity through the processing of biological waste and mixed waste. Ljubljana Regional Center for Waste Management (RCERO) facilities are capable of producing green electricity from renewable sources of biogas composed of biological waste and electricity and heat [74,75].
Another potential for the implementation of NbS in an urban environment is the possibility of transforming abandoned land into strategic areas promoting green infrastructure and urban regeneration [79]. Many projects, such as post-industrial districts that host living laboratories [62,87], enable the development, testing, and implementation of NbS. This potential is readily identified in the Results. “Renaturing abandoned areas and opportunity plots” is prominent among interventions in urban environments and has a great influence on ecosystem services of “ecosystem-based adaptation” and the benefits of “greater ecological connectivity across urban regenerated sites” and “changing image of the urban environment”.
Large green spaces with NbS have the potential to increase the volume of business, increasing revenues, in addition to creating a pleasant feeling of usability of the space for the population [81]. Vegetation contributes to real estate appreciation in the built environment, for example, in housing projects, reflecting economic benefits for the community [90]. It is worth noting that NbS actions in the social body, such as gardens in subdivisions or community gardens, are important and multifunctional areas in cities [91] that promote social cohesion and equity in the neighbourhood [99].
Although it is not the focus of this research, it is worth noting that a major advantage of implementing NbS is their high cost–benefit ratio over traditional solutions [25,28,29], as they are solutions that represent a flexible approach to sustainable inclusive growth at an affordable cost [8]. Thus, NbS represent an important tool for the development of a regenerative, shared, and circular economy in cities.
A study of the identification of NbS shares in the city of Amsterdam addressed NbS classification according to the level of applied technology (this reinforces the existence of other NbS classification methods). An example of high-tech NbS classification is the intervention of a tree-lined central square (IJburg Island), with great efforts due to the enormous amount of vegetation and the creation of a water retention system. On the other hand, an urban park (Roofpark Orly Square) classified as low-tech NbS transformed a grey space into a green space, with the intention of retaining rainwater and capillary irrigation [55]. Another example of low-tech NbS is urban gardens characterized by low-impact solutions, particularly in Lisbon, where the cost of gardening is lower than in other European regions [70].
However, with respect to differences in classification, many articles approached the initiatives in an urban environment with the same logic adopted in the present work. Research shows positive results of microscale interventions, for example, green roofs generate benefits in food production, energy savings (10-30%), and rainwater storage for cultivation and local cooling [56]. Among NbS solutions, facade vegetation and green roofs on buildings play an important role in temperature regulation, with improvements in thermal load, thermal comfort, and thermal storage of the building [67], as well as in reducing the harmful effects of heat waves on human health [85]. Therefore, buildings play an important part in these processes, not just in terms of carbon reduction but also in terms of adaptability and resilience in urban areas [103]. Furthermore, when deployed on a large scale, green roofs show great potential to develop a robust flood control network [60,103] and reduce runoff [67], in addition to potential to increase biodiversity [100]. Tree planting along streets or in urban parks has the greatest impact on heat mitigation and “greenness” (benefits in terms of restoration and mental health related to the amount of natural and seminatural areas that people experience in their surroundings, either by seeing them or directly accessing them) [100]. Small gardens also demonstrate cooling potential, as evidenced in the heavily urbanized region of Lisbon [69].
With great potential for the urban environment, as mentioned above, the actions of “green buildings” and “urban gardens and green spaces between buildings”, characterized by the same scale of implementation, represent actions with less frequency in the sample of the analysed case studies. This may mean that large European investments in NbS initiatives in the urban environment occur in projects with larger scales of implementation.
On a mesoscale, studies reported projected in the city of Amsterdam, with an alternative of ditches and filter strips (water decelerating green strip), which allows for local cooling and reduced runoff and storage capacity [56]. In Ljubljana, public orchards and nectar gardens with the planting of fruit trees (mesoscale) have increased livelihoods in the city by providing additional green areas, creating recreational areas, and generating a local cooling effect during hot summer periods [56]. This scale of implementation corresponds to most actions in an urban environment, representing approximately 45% of the total cases analysed. The actions of “parks and urban forests” and “community gardens and allotments” are highly correlated with the mesoscale.
With the adoption of macroscale solutions, for example the Gorla Maggiore Water Park, there was the possibility of peak flow reduction of 86% (downstream flooding) [56]. Another example is the city of Lisbon (European Green Capital 2020), which has a network of green corridors that are part of the urban green infrastructure and actively contribute to ecological connectivity [72]. Another highlight is in Rotterdam, which is an example of a multicultural and resilient city with major green initiatives and movements (urban agriculture combined with sustainable water management systems) [94].
The application of NbS has proven to be a valuable measure to improve climate resilience and citizens’ quality of life, as well as environmental justice and social coherence [67]. Urban spaces have great potential for green infrastructures [76,78], although this potential has not yet been fully discovered or used [58].
In many vulnerable regions, harnessing the power of nature is a promising and cost-effective strategy to strengthen climate resilience while promoting shared social, economic, and sustainable prosperity. Ongoing efforts are noted in Europe in scaling up and integrating NbS for mitigation of and adaptation to climate challenges, with the development of resilience in cities aiming at sustainability. Similarly, some countries in North America and East Asia have steadily advanced the use of NbS in urban planning. References to the use of NbS to combat climate change and reduce environmental degradation can be found political agendas in the United States [104], as well as in Chinese government statements supporting such solutions aimed at combating the causes of climate change [105].
To realize their full potential, NbS should be developed with reference to the expertise of all relevant stakeholders so that these solutions contribute to achieving all dimensions of sustainability in urban space. It is worth highlighting the importance of adding several NbS issues to scientific and policy agendas to address climate change adaptation and mitigation measures. With respect to the development of the present study, it is important to remark that the partners in the 69 analysed projects, beyond researchers from universities and companies, include local authorities. All projects implemented in municipalities demonstrate a real concern and interest in changing and improving the urban environment through NbS. Thus, local governments are increasing the interest and implementation of these types of innovative solutions inspired and driven by nature to face current and future challenges due to the consequences of climate change, making the urban environment more resilient.

6. Conclusions

Given the complexity of urban development and climate change, the pressure on natural resources is expected to continue. As a consequence, public agents in particular have to develop and implement long-term solutions for the sustainable and resilient development of cities based on new technologies and the establishment of development policies. Additionally, the ways of building and applying the concept of NbS, which encompasses solutions that provide a series of ecosystem services and multiple challenges and benefits, whether built permanently or environmentally, are expected to increase. Furthermore, the EU intends to continue its investment in the theorizing and operationalization of NbS, which is expected to increase with the HORIZON Europe program.
From the analysis of the results, it is possible to identify the implementation of urban actions for the development of urban parks and forests, the promotion of green areas for water management, and interventions of existing infrastructure with resources. The results also refer to the need to increase incentives for interventions in nature at a local scale, namely initiatives that promote the greening of buildings. This is essential to improve the local climate (mitigation of the heat island effect), to retain and reduce rainwater runoff, to increase biodiversity, and to improve human well-being through, for example, energy-parity solutions, such as the construction of a thermal cover to contribute to the thermal comfort of buildings through improved thermal insulation and increased potential performing in terms of energy.
The main goal of this article is to identify and present the main and most recent NbS practices applied in urban environments in the European panorama to support the analysis of the complementarity and integration of different measures, as an innovative analysis based on real cases. This study represents a systematic, comprehensive, and integrative compilation and assessment of NbS knowledge, highlighting the complementarity of NbS measures in the urban environment and the need for further research on this topic. NbS research on urban water and sewage networks is expected to continue, with the aim of reducing their inefficacity and improving both sustainability and performance on the path of urban greening.

Author Contributions

Conceptualization, F.R. and S.B.; methodology, S.B.; investigation, S.B.; writing—original draft preparation, S.B.; writing—review and editing, A.S.-A., F.R., R.G., R.M. and S.B.; visualization, F.R.; supervision, F.R. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Foundation for Science and Technology (FCT)—Aveiro Research Centre for Risks and Sustainability in Construction (RISCO), Universidade de Aveiro, Portugal [FCT/UIDB/ECI/04450/2020]. This research work was partially funded by the Foundation for Science and Technology (FCT) under Doctoral Grant 2021 MPP2030-FCT, MIT Portugal Program (PRT/BD/152847/2021) awarded to the first author (S.B.). This research work was partially funded by the Portuguese Government through the FCT and European Social Fund under the PhD grant SFRH/BD/147532/2019, awarded to the fourth author (R.M.).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. IPCC. Global Warming of 1.5 °C. In An IPCC Special Report on the Impacts of Global Warming of 1.5 °C above Pre-Industrial Levels and Related Global Greenhouse Gas Emission Pathways, in the Context of Strengthening the Global Response to the Threat of Climate Change, Sustainable Development, and Efforts to Eradicate Poverty; Cambridge University Press: Cambridge, UK; New York, NY, USA, 2018. [Google Scholar] [CrossRef]
  2. United Nations. The Sustainable Development Goals Report 2022. 2022. Available online: https://unstats.un.org/sdgs/report/2022/ (accessed on 12 October 2022).
  3. Williams, J. Circular Cities: Challenges to Implementing Looping Actions. Sustainability 2019, 11, 423. [Google Scholar] [CrossRef] [Green Version]
  4. UNEP—UN Environment Programme. Global Forum on Cities Highlights Need for Sustainable Development. 2022. Available online: https://www.unep.org/news-and-stories/story/global-forum-cities-highlights-need-sustainable-development (accessed on 12 October 2022).
  5. Langergraber, G.; Pucher, B.; Simperler, L.; Kisser, J.; Katsou, E.; Buehler, D.; Mateo, M.C.G.; Atanasova, N. Implementing nature-based solutions for creating a resourceful circular city. Blue-Green Syst. 2020, 2, 173–185. [Google Scholar] [CrossRef]
  6. United Nations. Goal 11: Make Cities Inclusive, Safe, Resilient and Sustainable. Available online: https://www.un.org/sustainabledevelopment/cities/ (accessed on 13 October 2022).
  7. IUCN. Global Standard for Nature-Based Solutions: A User-Friendly Framework for the Verification, Design and Scaling Up of NbS, 1st ed.; IUCN: Gland, Switzerland, 2020. [Google Scholar] [CrossRef]
  8. UN-Habitat—United Nations Human Settlements Programme. World Cities Report 2022: Envisaging the Future of Cities. 2022. Available online: https://unhabitat.org/wcr/ (accessed on 13 October 2022).
  9. Pineda-Martos, R.; Calheiros, C.S.C. Nature-Based Solutions in Cities—Contribution of the Portuguese National Association of Green Roofs to Urban Circularity. Circ. Econ. Sustain. 2021, 1, 1019–1035. [Google Scholar] [CrossRef]
  10. Pearlmutter, D.; Theochari, D.; Nehls, T.; Pinho, P.; Piro, P.; Korolova, A.; Papaefthimiou, S.; Mateo, M.C.G.; Calheiros, C.; Zluwa, I.; et al. Enhancing the circular economy with nature-based solutions in the built urban environment: Green building materials, systems and sites. Blue-Green Syst. 2020, 2, 46–72. [Google Scholar] [CrossRef] [Green Version]
  11. Bardin, L. Análise de Conteúdo, 70th ed.; Edicao Revista Actualizada; Almedian: Lisbon, Portugal, 2009. [Google Scholar]
  12. Kabisch, N.; Frantzeskaki, N.; Pauleit, S.; Naumann, S.; Davis, M.; Artmann, M.; Haase, D.; Knapp, S.; Korn, H.; Stadler, J.; et al. Nature-based solutions to climate change mitigation and adaptation in urban areas: Perspectives on indicators, knowledge gaps, barriers, and opportunities for action. Ecol. Soc. 2016, 21, 39. [Google Scholar] [CrossRef] [Green Version]
  13. Sowińska-Świerkosz, B.; García, J. What are Nature-based solutions (NBS)? Setting core ideas for concept clarification. Nat. -Based Solut. 2022, 2, 100009. [Google Scholar] [CrossRef]
  14. Nesshöver, C.; Assmuth, T.; Irvine, K.N.; Rusch, G.M.; Waylen, K.A.; Delbaere, B.; Haase, D.; Jones-Walters, L.; Keune, H.; Kovacs, E.; et al. The science, policy and practice of nature-based solutions: An interdisciplinary perspective. Sci. Total Environ. 2017, 579, 1215–1227. [Google Scholar] [CrossRef]
  15. Albert, C.; Schröter, B.; Haase, D.; Brillinger, M.; Henze, J.; Herrmann, S.; Gottwald, S.; Guerrero, P.; Nicolas, C.; Matzdorf, B. Addressing societal challenges through nature-based solutions: How can landscape planning and governance research contribute? Landsc. Urban Plan. 2019, 182, 12–21. [Google Scholar] [CrossRef]
  16. Krauze, K.; Wagner, I. From classical water-ecosystem theories to nature-based solutions—Contextualizing nature-based solutions for sustainable city. Sci. Total Environ. 2019, 655, 697–706. [Google Scholar] [CrossRef]
  17. Sarabi, S.E.; Han, Q.; Romme, A.; de Vries, B.; Wendling, L. Key Enablers of and Barriers to the Uptake and Implementation of Nature-Based Solutions in Urban Settings: A Review. Resources 2019, 8, 121. [Google Scholar] [CrossRef] [Green Version]
  18. Calliari, E.; Castellari, S.; Davis, M.; Linnerooth-Bayer, J.; Martin, J.; Mysiak, J.; Pastor, T.; Ramieri, E.; Scolobig, A.; Sterk, M.; et al. Building climate resilience through nature-based solutions in Europe: A review of enabling knowledge, finance and governance frameworks. Clim. Risk Manag. 2022, 37, 100450. [Google Scholar] [CrossRef]
  19. Grace, M.; Balzan, M.; Collier, M.; Geneletti, D.; Tomaskinova, J.; Abela, R.; Borg, D.; Buhagiar, G.; Camilleri, L.; Cardona, M.; et al. Priority knowledge needs for implementing nature-based solutions in the Mediterranean islands. Environ. Sci. Policy 2021, 116, 56–68. [Google Scholar] [CrossRef]
  20. Sarabi, S.; Han, Q.; Romme, A.; de Vries, B.; Valkenburg, R.; den Ouden, E. Uptake and implementation of Nature-Based Solutions: An analysis of barriers using Interpretive Structural Modeling. J. Environ. Manag. 2020, 270, 110749. [Google Scholar] [CrossRef] [PubMed]
  21. Science for Environment Policy. Future Brief: The Solution Is in Nature; Issue 24; EU Publications Office: Luxemburg, 2021. [Google Scholar]
  22. European Parliament. Circular Economy: Definition, Importance and Benefits|News|European Parliament. 2022. Available online: https://www.europarl.europa.eu/news/en/headlines/economy/20151201STO05603/circular-economy-definition-importance-and-benefits (accessed on 12 October 2022).
  23. European Commission. COM 2020—Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions—A New Circular Economy Action Plan—For a cleaner and More Competitive Europe. 2020. Available online: https://eur-lex.europa.eu/legal-content/EN/TXT/?qid=1583933814386&uri=COM:2020:98:FIN (accessed on 12 October 2022).
  24. Giorgos, S.; Stavros, S.; Nektarios, C.; Horizon, T.N. 2020 Research and Innovation Programme under Grant Agreement No. 730338. 2019. Available online: https://www.researchgate.net/publication/339983272_ThinkNature_Nature-Based_Solutions_Handbook. (accessed on 2 November 2022).
  25. European Commission. Evaluating the Impact of Nature-Based Solutions: A Handbook for Practitioners; Publications Office of the European Union: Luxemburg, 2021. [Google Scholar] [CrossRef]
  26. Dick, J.; Miller, J.D.; Carruthers-Jones, J.; Dobel, A.J.; Carver, S.; Garbutt, A.; Hester, A.; Hails, R.; Magreehan, V.; Quinn, M. How are nature based solutions contributing to priority societal challenges surrounding human well-being in the United Kingdom: A systematic map protocol. Environ. Evid. 2019, 8, 37. [Google Scholar] [CrossRef] [Green Version]
  27. Escobedo, F.J.; Giannico, V.; Jim, C.; Sanesi, G.; Lafortezza, R. Urban forests, ecosystem services, green infrastructure and nature-based solutions: Nexus or evolving metaphors? Urban For. Urban Green 2019, 37, 3–12. [Google Scholar] [CrossRef]
  28. European Environment Agency. Nature-Based Solutions in Europe: Policy, Knowledge and Practice for Climate Change Adaptation and Disaster Risk Reduction; EU Publication Office: Luxembourg, 2021. [Google Scholar] [CrossRef]
  29. European Commission; Directorate-General for Research, and Innovation. Towards an EU Research and Innovation Policy Agenda for Nature-Based Solutions & Re-Naturing Cities—Final report of the Horizon 2020, full version; EU Publications Office: Luxembourg, 2015. [Google Scholar] [CrossRef]
  30. Chausson, A.; Turner, B.; Seddon, D.; Chabaneix, N.; Girardin, C.A.J.; Kapos, V.; Key, I.; Roe, D.; Smith, A.; Woroniecki, S.; et al. Mapping the effectiveness of nature-based solutions for climate change adaptation. Glob. Chang. Biol. 2020, 26, 6134–6155. [Google Scholar] [CrossRef] [PubMed]
  31. Vieira, J.; Matos, P.; Mexia, T.; Silva, P.; Lopes, N.; Freitas, C.; Correia, O.; Santos-Reis, M.; Branquinho, C.; Pinho, P. Green spaces are not all the same for the provision of air purification and climate regulation services: The case of urban parks. Environ. Res. 2018, 160, 306–313. [Google Scholar] [CrossRef]
  32. Brillinger, M.; Henze, J.; Albert, C.; Schwarze, R. Integrating nature-based solutions in flood risk management plans: A matter of individual beliefs? Sci. Total Environ. 2021, 795, 148896. [Google Scholar] [CrossRef]
  33. McVittie, A.; Cole, L.; Wreford, A.; Sgobbi, A.; Yordi, B. Ecosystem-based solutions for disaster risk reduction: Lessons from European applications of ecosystem-based adaptation measures. Int. J. Disaster Risk Reduct. 2018, 32, 42–54. [Google Scholar] [CrossRef]
  34. Ihobe Environmental Management Agency; Ministry of the Environment Territorial Planning and Housing—Basque Government. Nature-Based Solutions for Local Climate Adaptation in the Basque Country; Methodological Guide for Their Identification and Mapping, Donostia/San Sebastián Case Study; Ihobe: Bilbao, Spain, 2017. [Google Scholar]
  35. Davies, C.; Chen, W.; Sanesi, G.; Lafortezza, R. The European Union roadmap for implementing nature-based solutions: A review. Environ. Sci. Policy 2021, 121, 49–67. [Google Scholar] [CrossRef]
  36. European Commission; Directorate—General for Research and Innovation. Nature-Based Solutions: State of the Art in EU-Funded Projects; EU Publications Office: Luxembourg, 2020. [Google Scholar] [CrossRef]
  37. European Commission. Horizon Europe. Available online: https://research-and-innovation.ec.europa.eu/funding/funding-opportunities/funding-programmes-and-open-calls/horizon-europe_en (accessed on 3 November 2022).
  38. European Commission; Directorate-General for Research and Innovation. A New Horizon for Europe: Impact Assessment of the 9th EU Framework Programme for Research and Innovation; EU Publications Office: Luxembourg, 2018. [Google Scholar] [CrossRef]
  39. Ashley, R.M.; Horton, B.; Walker, L.; Digman, C.; Shaffer, P.; van Herk, S. The benefits of Nature Based Systems in a changing and uncertain world. Proc. Inst. Civ. Eng. Eng. Sustain. 2022; ahead of print. [Google Scholar] [CrossRef]
  40. Gillis, K. Nature-based restorative environments are needed now more than ever. Cities Health 2020, 5, S237–S240. [Google Scholar] [CrossRef]
  41. Dubey, P.K. Biodiversity: The Nature-Based Solution for Pandemics and Human Well-being. Clim. Change Environ. Sustain. 2020, 8, 93. [Google Scholar] [CrossRef]
  42. United Nations Environment Programme. 2021 Global Status Report for Buildings and Construction: Towards a Zero-Emission, Efficient and Resilient Buildings and Construction Sector; UNEP: Nairobi, Kenya, 2021. [Google Scholar]
  43. United Nations Environment Programme. 2020 Global Status Report for Buildings and Construction: Towards a Zero-Emission, Efficient and Resilient Buildings and Construction Sector; UNEP: Nairobi, Kenya, 2020. [Google Scholar]
  44. Atanasova, N.; Castellar, J.A.; Pineda-Martos, R.; Nika, C.E.; Katsou, E.; Istenič, D.; Pucher, B.; Andreucci, M.B.; Langergraber, G. Nature-Based Solutions and Circularity in Cities. Circ. Econ. Sustain. 2021, 1, 319–332. [Google Scholar] [CrossRef]
  45. Anderson, V.; Gough, W.A. Enabling Nature-Based Solutions to Build Back Better—An Environmental Regulatory Impact Analysis of Green Infrastructure in Ontario, Canada. Buildings 2022, 12, 61. [Google Scholar] [CrossRef] [PubMed]
  46. Herzog, C.P.; Rozado, C.A. The EU-Brazil Sector Dialogue on Nature-Based Solutions: Contribution to a Brazilian Roadmap on Nature-Based Solutions for Resilient Cities; EU Publication Office: Luxembourg, 2019. [Google Scholar] [CrossRef]
  47. Nature4Cities. Nature Based Solutions. Available online: https://www.nature4cities.eu/nature-based-solutions (accessed on 19 October 2022).
  48. proGIreg. Nature-Based Solutions. Available online: https://progireg.eu/ (accessed on 20 October 2022).
  49. NAVIGATOR. Urban Nature Navigator Discovering the Potential of Nature-Based Solutions. Available online: https://naturvation.eu/sites/default/files/result/files/briefing_note_unn_purpose_and_potential (accessed on 25 October 2022).
  50. European Commission; Directorate—General for Research and Innovation. Mapping and Assessment of Ecosystems and Their Services: An EU Wide Ecosystem Assessment in Support of the EU Biodiversity Strategy; Supplement (indicator fact sheets); EU Publications Office: Luxembourg, 2020. [Google Scholar] [CrossRef]
  51. CICES—European Environment Agency (EEA). Towards a Common Classification of Ecosystem Services. Available online: https://cices.eu/resources/ (accessed on 5 November 2022).
  52. Raymond, C.; Berry, P.M.; Breil, M.; Nita, M.R. An Impact Evaluation Framework to Support Planning and Evaluation of Nature-Based Solutions Projects; Centre of Ecology and Hydrology: Bangor, UK, 2017. [Google Scholar] [CrossRef]
  53. Case Studies|Oppla. Available online: https://oppla.eu/case-study-finder (accessed on 5 October 2022).
  54. Mabon, L.; Barkved, L.; de Bruin, K.; Shih, W.-Y. Whose knowledge counts in nature-based solutions? Understanding epistemic justice for nature-based solutions through a multi-city comparison across Europe and Asia. Environ. Sci. Policy 2022, 136, 652–664. [Google Scholar] [CrossRef]
  55. Snep, R.P.H.; Voeten, J.; Mol, G.; van Hattum, T. Nature Based Solutions for Urban Resilience: A Distinction Between No-Tech, Low-Tech and High-Tech Solutions. Front. Environ. Sci. 2020, 8, 259. [Google Scholar] [CrossRef]
  56. Carvalho, P.N.; Finger, D.C.; Masi, F.; Cipolletta, G.; Oral, H.V.; Tóth, A.; Regelsberger, M.; Exposito, A. Nature-based solutions addressing the water-energy-food nexus: Review of theoretical concepts and urban case studies. J. Clean. Prod. 2022, 338, 130652. [Google Scholar] [CrossRef]
  57. Pearlmutter, D.; Pucher, B.; Calheiros, C.S.C.; Hoffmann, K.A.; Aicher, A.; Pinho, P.; Stracqualursi, A.; Korolova, A.; Pobric, A.; Galvão, A.; et al. Closing water cycles in the built environment through nature-based solutions: The contribution of vertical greening systems and green roofs. Water 2021, 13, 2165. [Google Scholar] [CrossRef]
  58. Zwierzchowska, I.; Haase, D.; Dushkova, D. Discovering the environmental potential of multi-family residential areas for nature-based solutions. A Central European cities perspective. Landsc. Urban Plan. 2021, 206, 103975. [Google Scholar] [CrossRef]
  59. Simperler, L.; Ertl, T.; Matzinger, A. Spatial Compatibility of Implementing Nature-Based Solutions for Reducing Urban Heat Islands and Stormwater Pollution. Sustainability 2020, 12, 5967. [Google Scholar] [CrossRef]
  60. Basu, A.S.; Pilla, F.; Sannigrahi, S.; Gengembre, R.; Guilland, A.; Basu, B. Theoretical Framework to Assess Green Roof Performance in Mitigating Urban Flooding as a Potential Nature-Based Solution. Sustainability 2021, 13, 13231. [Google Scholar] [CrossRef]
  61. Collier, M.J.; Bourke, M. The case for mainstreaming nature-based solutions into integrated catchment management in Ireland. Proc. R. Ir. Acad. 2020, 120, 107–113. [Google Scholar] [CrossRef]
  62. Case Studies|proGIreg. Available online: https://progireg.eu/ (accessed on 5 October 2022).
  63. Frantzeskaki, N.; Vandergert, P.; Connop, S.; Schipper, K.; Zwierzchowska, I.; Collier, M.; Lodder, M. Examining the policy needs for implementing nature-based solutions in cities: Findings from city-wide transdisciplinary experiences in Glasgow (UK), Genk (Belgium) and Poznań (Poland). Land Use Policy 2020, 96, 104688. [Google Scholar] [CrossRef]
  64. Case Studies|CleverCities. Available online: https://clevercities.eu/ (accessed on 5 October 2022).
  65. Rödl, A.; Arlati, A. A general procedure to identify indicators for evaluation and monitoring of nature-based solution projects. Ambio 2022, 51, 2278–2293. [Google Scholar] [CrossRef]
  66. Tosun, J.; Leopold, L. Aligning Climate Governance with Urban Water Management: Insights from Transnational City Networks. Water 2019, 11, 701. [Google Scholar] [CrossRef] [Green Version]
  67. Scharf, B.; Kogler, M.; Kraus, F.; Perez, I.; Garcia, L.G. NBS Impact Evaluation with GREENPASS Methodology Shown by the Case Study ‘Fischbeker Höfe’ in Hamburg/Germany. Sustainability 2021, 13, 9167. [Google Scholar] [CrossRef]
  68. Arlati, A.; Rödl, A.; Kanjaria-Christian, S.; Knieling, J. Stakeholder Participation in the Planning and Design of Nature-Based Solutions. Insights from CLEVER Cities Project in Hamburg. Sustainability 2021, 13, 2572. [Google Scholar] [CrossRef]
  69. Kumar, P.; Debele, S.E.; Sahani, J.; Rawat, N.; Marti-Cardona, B.; Alfieri, S.M.; Basu, B.; Basu, A.S.; Bowyer, P.; Charizopoulos, N.; et al. An overview of monitoring methods for assessing the performance of nature-based solutions against natural hazards. Earth Sci. Rev. 2021, 217, 103603. [Google Scholar] [CrossRef]
  70. Poniży, L.; Latkowska, M.J.; Breuste, J.; Hursthouse, A.; Joimel, S.; Külvik, M.; Leitão, T.E.; Mizgajski, A.; Voigt, A.; Kacprzak, E.; et al. The Rich Diversity of Urban Allotment Gardens in Europe: Contemporary Trends in the Context of Historical, Socio-Economic and Legal Conditions. Sustainability 2021, 13, 11076. [Google Scholar] [CrossRef]
  71. Cui, M.; Ferreira, F.; Fung, T.; Matos, J.S. Tale of two cities: How nature-based solutions help create adaptive and resilient urban water management practices in singapore and lisbon. Sustainability 2021, 13, 10427. [Google Scholar] [CrossRef]
  72. Canet-Martí, A.; Pineda-Martos, R.; Junge, R.; Bohn, K.; Paço, T.A.; Delgado, C.; Alenčikienė, G.; Skar, S.L.G.; Baganz, G.F.M. Nature-based solutions for agriculture in circular cities: Challenges, gaps, and opportunities. Water 2021, 13, 2565. [Google Scholar] [CrossRef]
  73. Mahmoud, I.H.; Morello, E.; Ludlow, D.; Salvia, G. Co-creation Pathways to Inform Shared Governance of Urban Living Labs in Practice: Lessons from Three European Projects. Front. Sustain. Cities 2021, 3, 80. [Google Scholar] [CrossRef]
  74. Kisser, J.; Wirth, M.; De Gusseme, B.; Van Eekert, M.; Zeeman, G.; Schoenborn, A.; Vinnerås, B.; Finger, D.C.; Repinc, S.K.; Bulc, T.G.; et al. A review of nature-based solutions for resource recovery in cities. Blue-Green Syst. 2020, 2, 138–172. [Google Scholar] [CrossRef] [Green Version]
  75. van Hullebusch, E.D.; Bani, A.; Carvalho, M.; Cetecioglu, Z.; De Gusseme, B.; Di Lonardo, S.; Djolic, M.; van Eekert, M.; Griessler Bulc, T.; Haznedaroglu, B.Z.; et al. Nature-based units as building blocks for resource recovery systems in cities. Water 2021, 13, 3153. [Google Scholar] [CrossRef]
  76. Radinja, M.; Atanasova, N.; Lamovšek, A.Z. The water-management aspect of blue-green infrastructure in cities. Urbani Izziv 2021, 32, 98–110. [Google Scholar] [CrossRef]
  77. Pagano, A.; Pluchinotta, I.; Pengal, P.; Cokan, B.; Giordano, R. Engaging stakeholders in the assessment of NBS effectiveness in flood risk reduction: A participatory System Dynamics Model for benefits and co-benefits evaluation. Sci. Total Environ. 2019, 690, 543–555. [Google Scholar] [CrossRef]
  78. O’Keeffe, J.; Pluchinotta, I.; De Stercke, S.; Hinson, C.; Puchol-Salort, P.; Mijic, A.; Zimmermann, N.; Collins, A.M. Evaluating natural capital performance of urban development through system dynamics: A case study from London. Sci. Total Environ. 2022, 824, 153673. [Google Scholar] [CrossRef]
  79. Song, Y.; Kirkwood, N.; Maksimović, Č.; Zheng, X.; O’Connor, D.; Jin, Y.; Hou, D. Nature based solutions for contaminated land remediation and brownfield redevelopment in cities: A review. Sci. Total Environ. 2019, 663, 568–579. [Google Scholar] [CrossRef]
  80. Mahmoud, I.H.; Morello, E.; Vona, C.; Benciolini, M.; Sejdullahu, I.; Trentin, M.; Pascual, K.H. Setting the social monitoring framework for nature-based solutions impact: Methodological approach and pre-greening measurements in the case study from clever cities milan. Sustainability 2021, 13, 9672. [Google Scholar] [CrossRef]
  81. Koppelaar, R.; Marvuglia, A.; Havinga, L.; Brajković, J.; Rugani, B. Is Agent-Based Simulation a Valid Tool for Studying the Impact of Nature-Based Solutions on Local Economy? A Case Study of Four European Cities. Sustainability 2021, 13, 7466. [Google Scholar] [CrossRef]
  82. Piga, B.E.A.; Stancato, G.; Rainisio, N.; Boffi, M. How Do Nature-Based Solutions’ Color Tones Influence People’s Emotional Reaction? An Assessment via Virtual and Augmented Reality in a Participatory Process. Sustainability 2021, 13, 13388. [Google Scholar] [CrossRef]
  83. Salvatori, E.; Gentile, C.; Altieri, A.; Aramini, F.; Manes, F. Nature-Based Solution for Reducing CO2 Levels in Museum Environments: A Phytoremediation Study for the Leonardo da Vinci’s ‘Last Supper’. Sustainability 2020, 12, 565. [Google Scholar] [CrossRef] [Green Version]
  84. di Biagi, P.; Basso, S.; Marin, A.; Tzortzi, J.; Guaita, L.; Kouzoupi, A. Sustainable Strategies for Urban and Landscape Regeneration Related to Agri-Cultural Heritage in the Urban-Periphery of South Milan. Sustainability 2022, 14, 6581. [Google Scholar] [CrossRef]
  85. Marvuglia, A.; Koppelaar, R.; Rugani, B. The effect of green roofs on the reduction of mortality due to heatwaves: Results from the application of a spatial microsimulation model to four European cities. Ecol. Modell. 2020, 438, 109351. [Google Scholar] [CrossRef]
  86. Ronchi, S.; Arcidiacono, A.; Pogliani, L. Integrating green infrastructure into spatial planning regulations to improve the performance of urban ecosystems. Insights from an Italian case study. Sustain. Cities Soc. 2020, 53, 101907. [Google Scholar] [CrossRef]
  87. Conti, M.E.; Battaglia, M.; Calabrese, M.; Simone, C. Fostering Sustainable Cities through Resilience Thinking: The Role of Nature-Based Solutions (NBSs): Lessons Learned from Two Italian Case Studies. Sustainability 2021, 13, 12875. [Google Scholar] [CrossRef]
  88. Ronchi, S.; Salata, S.; Arcidiacono, A. Which urban design parameters provide climate-proof cities? An application of the Urban Cooling InVEST Model in the city of Milan comparing historical planning morphologies. Sustain. Cities Soc. 2020, 63, 102459. [Google Scholar] [CrossRef]
  89. Zwierzchowska, I.; Fagiewicz, K.; Poniży, L.; Lupa, P.; Mizgajski, A. Introducing nature-based solutions into urban policy—Facts and gaps. Case study of Poznań. Land Use Policy 2019, 85, 161–175. [Google Scholar] [CrossRef]
  90. Gałecka-Drozda, A.; Wilkaniec, A.; Szczepańska, M.; Świerk, D. Potential nature-based solutions and greenwashing to generate green spaces: Developers’ claims versus reality in new housing offers. Urban Urban Green. 2021, 65, 127345. [Google Scholar] [CrossRef]
  91. Dymek, D.; Wilkaniec, A.; Bednorz, L.; Szczepańska, M. Significance of allotment gardens in urban green space systems and their classification for spatial planning purposes: A case study of poznań, poland. Sustainability 2021, 13, 1044. [Google Scholar] [CrossRef]
  92. van Cauwenbergh, N.; Dourojeanni, P.; van der Zaag, P.; Brugnach, M.; Dartee, K.; Giordano, R.; Lopez-Gunn, E. Beyond TRL—Understanding institutional readiness for implementation of nature-based solutions. Environ. Sci. Policy 2022, 127, 293–302. [Google Scholar] [CrossRef]
  93. Frantzeskaki, N. Seven lessons for planning nature-based solutions in cities. Environ. Sci. Policy 2019, 93, 101–111. [Google Scholar] [CrossRef]
  94. Säumel, I.; Reddy, S.; Wachtel, T. Edible City Solutions—One Step Further to Foster Social Resilience through Enhanced Socio-Cultural Ecosystem Services in Cities. Sustainability 2019, 11, 972. [Google Scholar] [CrossRef] [Green Version]
  95. Giachino, C.; Pattanaro, G.; Bertoldi, B.; Bollani, L.; Bonadonna, A. Nature-based solutions and their potential to attract the young generations. Land Use Policy 2021, 101, 105176. [Google Scholar] [CrossRef]
  96. Qi, Y.; Chan, F.K.S.; Thorne, C.; O’Donnell, E.; Quagliolo, C.; Comino, E.; Pezzoli, A.; Li, L.; Griffiths, J.; Sang, Y.; et al. Addressing Challenges of Urban Water Management in Chinese Sponge Cities via Nature-Based Solutions. Water 2020, 12, 2788. [Google Scholar] [CrossRef]
  97. Salata, S.; Ronchi, S.; Giaimo, C.; Arcidiacono, A.; Pantaloni, G.G. Performance-Based Planning to Reduce Flooding Vulnerability Insights from the Case of Turin (North-West Italy). Sustainability 2021, 13, 5697. [Google Scholar] [CrossRef]
  98. Dorst, H.; van der Jagt, A.; Runhaar, H.; Raven, R. Structural conditions for the wider uptake of urban nature-based solutions—A conceptual framework. Cities 2021, 116, 103283. [Google Scholar] [CrossRef]
  99. Dignum, M.; Dorst, H.; van Schie, M.; Dassen, T.; Raven, R. Nurturing nature: Exploring socio-spatial conditions for urban experimentation. Environ. Innov. Soc. Transit. 2020, 34, 7–25. [Google Scholar] [CrossRef]
  100. Cortinovis, C.; Olsson, P.; Boke-Olén, N.; Hedlund, K. Scaling up nature-based solutions for climate-change adaptation: Potential and benefits in three European cities. Urban Urban Green. 2022, 67, 127450. [Google Scholar] [CrossRef]
  101. Raymond, C.M.; Frantzeskaki, N.; Kabisch, N.; Berry, P.; Breil, M.; Nita, M.R.; Geneletti, D.; Calfapietra, C. A framework for assessing and implementing the co-benefits of nature-based solutions in urban areas. Environ. Sci. Policy 2017, 77, 15–24. [Google Scholar] [CrossRef]
  102. Boros, J.; Mahmoud, I. Urban Design and the Role of Placemaking in Mainstreaming Nature-Based Solutions. Learning From the Biblioteca Degli Alberi Case Study in Milan. Front. Sustain. Cities 2021, 3, 38. [Google Scholar] [CrossRef]
  103. Pimentel-Rodrigues, C.; Silva-Afonso, A. Contributions of Water-Related Building Installations to Urban Strategies for Mitigation and Adaptation to Face Climate Change. Appl. Sci. 2019, 9, 3575. [Google Scholar] [CrossRef]
  104. Executive Order on Tackling the Climate Crisis at Home and Abroad|the White House. Available online: https://www.whitehouse.gov/briefing-room/presidential-actions/2021/01/27/executive-order-on-tackling-the-climate-crisis-at-home-and-abroad/ (accessed on 6 December 2022).
  105. China Pushes Technical Solutions in Race to Meet Climate Goals|Reuters. Available online: https://www.reuters.com/article/us-china-climatechange/china-pushes-technical-solutions-in-race-to-meet-climate-goals-idUSKBN29I1EA (accessed on 6 December 2022).
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Figure 1. Overview of nature-based concepts and their relationship to existing key concepts. Adapted from [25,28].
Figure 1. Overview of nature-based concepts and their relationship to existing key concepts. Adapted from [25,28].
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Figure 2. Spatial distribution of cities by country.
Figure 2. Spatial distribution of cities by country.
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Figure 3. Number of NbS Projects by European countries.
Figure 3. Number of NbS Projects by European countries.
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Figure 4. Distribution of NbS urban actions.
Figure 4. Distribution of NbS urban actions.
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Figure 5. Spatial scale NbS of implementation.
Figure 5. Spatial scale NbS of implementation.
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Figure 6. Distribution of the multiple benefits of NbS.
Figure 6. Distribution of the multiple benefits of NbS.
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Figure 7. Distribution of NbS ecosystem services.
Figure 7. Distribution of NbS ecosystem services.
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Figure 8. Multiple benefits NbS.
Figure 8. Multiple benefits NbS.
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Figure 9. NbS ecosystem services.
Figure 9. NbS ecosystem services.
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Table
Table 1. Benefits of nature-based solutions to address climate risks in specific sectors and thematic areas.
Table 1. Benefits of nature-based solutions to address climate risks in specific sectors and thematic areas.
Sectors and AreasNbS OptionsNbS BenefitsClimate
Impacts
Water
Management		Sustainable urban drainage systems (SUDS)
Renaturalization of rivers, streams, and flood plains
Restoration of ponds and lakes
River buffers (vegetation strips)
Water-sensitive forest management
Controlled flood plains		Regulation of the water cycle
Reduction in floods
Improvement of the water quality
Improvement of the soil quality, stability, and erosion
Biodiversity
Regeneration of degraded areas
Recreation and aesthetic appreciation
Health and quality of life		Droughts
Floods
Forests and ForestryProtection and restoration of forests
Sustainable forest management
Integration of trees/forests into the landscape
Wetlands		Regulation of the water cycle
Reduction in floods
Improvement of the water quality
Improvement of the soil quality, stability, and erosion
Biodiversity
Carbon sequestration
Control of disease and pests
Recreation and aesthetic appreciation
Health and quality of life		Droughts
Floods
Fires
AgricultureImproved soil and water management
Crop-type diversification and rotation
Agroforestry		Retention of water and soil retention
Mitigation of heat stress
Biodiversity
Carbon sequestration
Control of disease and pests
Soil fertility		Droughts
Floods
Heat stress
Urban AreasUrban parks, forests, and street trees
Green buildings
Renaturing of abandoned areas and opportunity plots
NbS for water management (bioswales, detention ponds, and rainwater harvesting)
NbS for transport infrastructure (greening of streets and previous pavement and greening infrastructure)
Regenerated soil
Pollinator biodiversity
Environmental compensation		Cooling air temperature
Regulation of water runoff
Improvement of the water quality
Improvement of noise quality and comfort
Biodiversity
Carbon sequestration
Regeneration of degraded areas
Recreation and aesthetic appreciation
Increasing the value of land and property
Health and quality of life		Floods
Heat stress
Coastal AreasRehabilitation and restoration of coastal habitats
Beach regeneration, barrier islands, and beach nourishment
Hybrid solutions (green dykes and vegetated levees)		Reduction in coastal flooding
Stabilization of the coast
Carbon sequestration
Biodiversity
Regeneration of degraded areas
Recreation		Sea level rise
Storm surges
Coastal erosion
Adapted from [28,34].
Table
Table 2. Nature-based solutions and actions at different scales in urban areas.
Table 2. Nature-based solutions and actions at different scales in urban areas.
ScaleActions and Interventions
Micro:
Building or plot		Previous pavement
Urban meadow
Private garden
Regreening spaces between buildings
Actions in community courtyards
Shelter for auxiliary fauna (insects and earthworms)
Green facades and vertical gardens
Sustainable urban drainage systems
Green roof and meadow
Combined solutions—green roof with renewable energy
Rooftop farming and in-height orchards
Meso:
District or neighbourhood		Street furniture
Previous pavement
Comfortable urban places
Urban microclimates (public fountains and lakes)
Green wharf
Spontaneous flora
Street trees
Community garden
Allotment gardens
Urban parks
Permeable riverbanks and waterbodies
Renaturing of abandoned areas and opportunity plots
Macro:
City and beyond		Urban farming
Constructed wetlands
Green street networks
Urban forests
Ecological corridors
Urban planning
Renaturing of rivers and streams
Controlled flood plains
Adapted from: [34,46,47].
Table
Table 3. List of cities and their projects.
Table 3. List of cities and their projects.
LocationName of Project/ProgramMain ObjectivesMain ImpactsProject Name or Name of NbS ActionsSupporting References
Amsterdam, The NetherlandsNbS for greening the city and increasing resilienceCreate a creative and varied city with an integrated public transport network, high-quality urban planning, and investment in recreational green spaces, water, and renewable energyGreen spaces created/renovated; reduced flood risks; increased social awareness and political support for water diplomacy and climate change adaptation City Parks
Green Neighbourhoods
Greening the city
Green corridors
Deltaplan		[53,54,55,56]
Bari, ItalyNbS for greening the urban spaceImprove urban quality and green areas, reduce the urban heat island effect, and manage stormwaterHealth benefits, mitigation of the urban heat island effect, air purification, restoration/maintenance of habitats and biodiversity, water flow regulation, and reduced impacts of heavy precipitation eventsOperation Zero Degradation: Revitalizing residual urban areas as green spaces
Shagree: the Green shadows programme
Lama Balice Nature Park		[53]
Berlin, GermanyNbS for urban green connectivity and biodiversityCreate connectivity across the city and a ‘greenbelt’ as a border boundary for urban growth and protection against urban sprawlGreen adaptation to climate change, increasing urban resilience, green/blue connectivity and functionality, biodiversity, cultural wealth, water infiltration/storage, NbS social learning, and health benefitsBENE (urban greening)
Green Moabit (rainwater management)
Mischwaldprogramm (mixed forests)
Transforming vacant urban areas into green spaces
School gardens (Urban Living Lab)
Twenty green walks
Prinzessinnengarten (nomadic gardening)		[53,57,58,59]
Bilbao, SpainNbS for dealing with extreme temperature and rainfall eventsMake the city more resilient towards cold spells, heat waves, and frequent floodsMitigation and adaptation to climate change in urban planning, social and economic cohesion, well-being, health, and a more attractive cityZorrotzaurre project (new floodproof district)
Bilbao Greenbelt Expansion (expansion and connection of green areas)		[53]
Bristol, United KingdomNbS for a sustainable futureCreate a socially inclusive environment with facilities for sport and recreation and a natural environment with urban regeneration and renewal through green networks to minimize and mitigate climate changeProtect, provide, enhance, and expand green infrastructure; promote healthy lifestyles and social inclusion; and increase connectivity with natureGreen infrastructure
Green areas for flood management		[53]
Budapest, HungaryNbS for climate resilience and pollution controlProtection of and increase in the number of green areas, ensuring ecological connectivity and the development of ‘smart’ and environmentally conscious citiesUrban biodiversity, better water management (water retention), better air quality, social cohesion, public awareness of nature, health, and recreational benefitsPocket parks
Urban gardens
Renewing city parks
Preserving forests on the outskirts and existing green areas		[53]
Dresden, GermanyNbS for sustainable urban transitionA compact city to accommodate more development and include a network of functional green spacesBottom-up initiatives for community gardens for diverse environmental, social, and economic benefits; a better quality of urban life; urban renewal; and increased city attractivenessLiving lab: transforming former allotment gardens into community gardens
Urban landscape plan: ecological network		[53]
Dublin, IrelandNbS for a more sustainable city by 2030Create a sustainable and resilient city based on economy, environment, and equityProviding an attractive place to live, work, and visit; air and water regulation; climate adaptation; and pollution reductionSustainable urban drainage
Green infrastructure
Green roofs and green walls		[53,60,61]
Dortmund, GermanyThe Living Lab: From the Duesenberg to the Huckarde districtStrengthen high-quality green infrastructure and industries with a focus on urban agriculture and improved qualityReconstruction of derelict land previously used by industry for residential areas and green leisure areas, increasing natural potential with a greenbeltRenaturing landfill sites
Urban farming and gardening on post-industrial sites
Connecting Huckarde with River Emscher and Duesenberg
Aquaponics as soil-less agriculture
Pollinator biodiversity and citizen science		[62]
Edinburgh, United KingdomNbS enhancing health, wealth, and sustainabilityCreate a low-carbon, resource-efficient city, providing a resilient local economy and vibrant, thriving communitiesNew business and knowledge opportunities, public awareness, green infrastructure connectivity, biodiversity, cultural wealth, ownership, water management, and climate adaptationPollinator Pledge
Granton Community Gardeners
Duddingston Field Group		[53]
Genk, BelgiumNbS bridging green and industrial heritageUse Genk’s natural and human capital for sustainable value creationSocial cohesion, economic opportunities, green jobs, and transition to sustainabilityUrban farming—Modeltuin Genk Noord
Green Corridor—Stiemerbeek Valley
Bee Plan—Bijenplan and Heempark		[53,63]
Hamburg, GermanyHamburg’s CLEVER Action Lab: Neugraben-FischbekPromote sustainable and socially integrative urban renewal through NbS and demonstrate the capacity and potential of these solutions in terms of technical, social, and economic innovationEcologically regenerated and healthier urban environments with greater social cohesion, more economic opportunities, and greater environmental qualityGreen corridor
Green roofs and green facades
School playgrounds/yards		[64,65,66,67,68]
Linz, AustriaNbS as a motor for urban growthEnhancing and protecting urban green areas as a way to increase the attractiveness of the city and position it as an important location for regional and international businessRecreation; biodiversity; microclimate; traffic noise control; stormwater management; and a high-quality urban landscape for real estate value, air quality, and pollution reductionLandschaftspark Bindermichl-Spallerhof
SolarCity
Urban greening strategy		[53]
Lisbon, PortugalNbS enhancing resilience through urban regenerationIncrease resilience through urban regeneration and increase the importance of preserving natural, forestry, agricultural, and cultural heritageBetter ecological flows and landscape functions; green infrastructure to adapt to climate change, improve drainage, control air and water pollution, and promote leisure, contributing to healthy lifestyles and an attractive cityGreen corridors and street trees
Urban agriculture		[53,57,69,70,71,72,73]
Ljubljana, SloveniaNbS for urban regeneration and well-beingProtect and enhance the city’s natural environmentMitigation of the urban heat island effect, accessibility for pedestrians and cyclists, gardens for recreation and leisure, and restoration of the river with an ecological corridorGreen areas (including agricultural allotments)
Urban ecological zone
Restoration of the river Ljubljanica (Ljubljanica Connects)		[53,56,74,75,76,77]
London, United KingdomNbS for a leading sustainable cityIncrease green space, improve air quality, reduce the UHI effect (heat island), and prevent flash floods through climate change adaptation and mitigationOpportunity to develop and market green skills;
NbS can mitigate heat stress, flood risk, and air quality issues		Green roofs (London/Barking Riverside)
Natural water retention measures—River Quaggy
Brownfield restoration, Barking Riverside
Olympic Park—biosolar roofs
Beetle Bump, University of East London campus		[53,64,73,78,79]
London’s CLEVER Action Lab: ThamesmeadProvide opportunities to connect with natural landscapes, economic opportunities, social cohesion, and citizen well-being and advance NbS research and urban regenerationQuality green spaces working together with education and community networks; connection with nature; social, economic, and environmental impactConnecting people and places “Healthy Streets”—Parkview, South Thamesmead
Greening Unusual and Underused Spaces—South Thamesmead
Activating Southmere Lake—Southmere, South Thamesmead
Milan, ItalyNbS for urban regenerationGreen infrastructure is the best way to achieve environmental goals; promote social development and improve social well-beingSocial cohesion; promotion of multipurpose green infrastructure; offering inhabitants agricultural, forestry, cultural, and recreational activitiesParco Agricolo Sud (periurban agriculture and nature conservation)
Urban gardening
Bosco Verticale (vertical forest)
Gorla Maggiore Water Park		[53,56,64,73,80,81,82,83,84,85,86,87,88]
CLEVER Cities MilanExperimenting with innovative green and NbS infrastructure for city regeneration, climate change mitigation, and building a better future for citizensDiffusion of green roofs and facades; support for experimental projects; development of public green areas with innovative and shared methods in terms of planning, management, maintenance, and monitoring; and the experimental integration of green spaces into railway infrastructureGreen roofs and walls: ‘Rinverdiamo Milano’—Let’s re-green Milan
Development of public green areas: A new park for Giambellino 129
A new green hub for Tibaldi station
Oradea, RomaniaImproving the quality of life with NbSImprove the quality of life of citizens, prioritizing increased leisure opportunitiesActive utilization of new areas with improved recreation, increased connectivity, and more biodiversity; improved air quality and climate conditions; new employment and business opportunities; and positive cooperation in public–private partnershipsGreen area rehabilitation and development of green infrastructure
Creation of outdoor leisure areas
Lake creation		[53]
Poznan, PolandNbS for a friendly, mobile cityTransforming into a green city and improving the quality of life of all inhabitants in such a way that they have a stake in cocreating the cityGreen wedge system with high cooling capacity, the transformation of parking lots into green areas, riverside areas with seasonal beaches for leisure, high tourist potential, and new housing projects close to green areasMaintaining the green wedge system
Planting 18,000 trees on the roadside and using transitional green elements;
Transforming car parks into green areas
Community gardens
Creating seasonal beaches		[53,58,63,70,89,90,91]
Rotterdam, The NetherlandsNbS for building a waterproof cityMake the city 100% weatherproof by 2025, with a focus on adaptive measures including rainwater capture and delayed drainageBlue–green corridors to facilitate natural hydrological processes, increased biodiversity, and improved quality of lifeWater storage capacity
Deltaplan
Tidal park programme—Esch, Mallegat		[53,92,93,94]
Szeged, HungaryNbS for urban regeneration and adaptation to climate changeImprove the quality of green areas, restore natural habitats and ecological corridors for social and recreational purposes, and mitigate the impacts of climate changeMore recreational environments and public awareness, more stable biodiversity and ecosystems, and better air and soil qualityGreen area rehabilitation
Green infrastructure development
Urban gardening		[53,81,85]
Turin, ItalyThe Living Lab: Mirafiori SudStrengthen green infrastructure in areas previously dominated by industry; improve urban quality, social, and economic issues through NbS implementation; involve citizens in activities; and promote NbS-based business modelsIntroduction of more green space, contribution to education in schools, the inclusion of disadvantaged social groups, support for new entrepreneurship and new green jobs, and NbS regulationNew soil and plant species for urban forestry (Parco Sangone)
Greenway and cycling corridor (Sangone river)
Urban farming and gardening
Pollinator-friendly green spaces
Aquaponics tests
Green roofs and walls		[62,95,96,97]
Utrecht, The NetherlandsNbS for urban resilience and citizens’ well-beingPromoting healthy urban living, an integrated and systemic urban life that combines the cleanest local approach, recreation, and noise reductionA water system for diverse ecosystem services, street trees, and street vegetation contributes to quality of life through the realization of a comprehensive green structure based on historical–cultural, spatial, environmental, and ecological valuesCentral station—a ‘Smart Sustainable District’
Leidsche Rijn—sustainable urban drainage systems
City trees and greenery		[53,98,99,100]
Zagreb, CroatiaThe Living Lab: SesveteStrengthening green infrastructure in areas previously dominated by industry, social inclusion, supporting new entrepreneurship and new green jobs, and introducing NbS as a catalyst in urban regenerationNew public spaces and the introduction of NbS to sustainable urban planning, strengthening urban resilience, wellness programs (recreation and sports areas), community activities, and bioclimatic building principlesUrban gardens and green areas (educational area)
Aquaponic testing
New connecting cycle path (urban gardens and neighbourhood)
Green roofs and/or green walls in historic buildings (former factories)		[62]
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Bona, S.; Silva-Afonso, A.; Gomes, R.; Matos, R.; Rodrigues, F. Nature-Based Solutions in Urban Areas: A European Analysis. Appl. Sci. 2023, 13, 168. https://doi.org/10.3390/app13010168

AMA Style

Bona S, Silva-Afonso A, Gomes R, Matos R, Rodrigues F. Nature-Based Solutions in Urban Areas: A European Analysis. Applied Sciences. 2023; 13(1):168. https://doi.org/10.3390/app13010168

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Bona, Sara, Armando Silva-Afonso, Ricardo Gomes, Raquel Matos, and Fernanda Rodrigues. 2023. "Nature-Based Solutions in Urban Areas: A European Analysis" Applied Sciences 13, no. 1: 168. https://doi.org/10.3390/app13010168

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