Abstract
Urban waterfront green space is a critical component of urban ecosystems and can provide various types of cultural ecosystem services (CESs). In this study, the CESs of six waterfront green spaces with different planned functions in different areas along the Huangpu River were assessed, and a framework of CES types applicable to the assessment of waterfront green spaces was proposed. Based on an investigation of the basic indicators of different waterfront green spaces and the differences in planning in the regions where they are located, we explored the factors affecting the public's perception of CESs. We found that a waterfront green space with a clear theme and amusement facilities with special features improved public perceptions of CESs. Improved water accessibility and many winding walkways can increase the diversity of outdoor activities. The discrepancy between public perceptions of CESs and the CESs that city managers hope waterfront green spaces to provide in urban planning may be due to a lack of a detailed introduction to facilities for public within green spaces. We suggest promoting the public perception of CESs provided by waterfront green spaces through improved water accessibility and enhanced descriptions of their facilities. The results and suggestions generated from this study offer insights into the future planning and design of urban waterfront green spaces.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
1 Introduction
Historically, most major cities have developed along water networks, with urban waterfront spaces developing along with them (Cialdea and Pompei 2022). These linear open spaces along water networks have served as critical industrial districts and shipping ports but have experienced periods of decline due to overdevelopment. As cities have grown and more attention has been given to ecology, the redevelopment of urban waterfronts has often been accompanied by the planning and construction of urban green spaces; related research indicates that these efforts promote urban development and enhance urban vitality (Hagerman 2007). Green spaces are widely seen as integrated areas composed of any natural, seminatural, or artificial vegetation (Han et al. 2023). Waterfront green spaces, which combine green and blue spaces, are receiving increasing attention due to their important and powerful roles in ecosystem functions (MU et al. 2024). Several researchers have explored the impact of blue‒green infrastructure on the urban thermal environment (Wu et al. 2018). Studies have also shown that urban green spaces and surrounding water have cooling effects on the environment (Gao et al. 2016; Liang et al. 2015), which alleviate the urban heat island effect (He 2019). Urban blue‒green spaces can also improve air quality, reduce water pollution (Abhijith et al. 2017), and control urban flooding (He et al. 2019). Additionally, Smith et al. (2022) indicated that these spaces can help connect ecosystems as a whole since green spaces and water often converge. In addition to performing natural functions, waterfront green spaces can promote the physical and mental health of residents (Pouso et al. 2021) by providing cultural ecosystem services (CESs). The millennium ecosystem assessment (MEA) described CESs as providing the ‘‘nonmaterial benefits people obtain from ecosystems through spiritual enrichment, cognitive development, reflection, recreation, and aesthetic experiences” (MEA 2005, p 39). These services play an important role in connecting ecosystems and social systems (Costanza et al. 2017). Intangible experiences, such as a sense of place, recreation (Ghermandi 2018), aesthetics (Figueroa-Alfaro and Tang 2017), and spiritual beliefs that people gain through their interactions with nature, are components of the benefits people drive from nature (Summers et al. 2012). CESs provide insight into these issues, and qualifying and assessing this insight, as with all ecosystem services in urban areas, give managers with a deeper understanding of the connection between residents and waterfront green spaces.
Fish et al. (2016, p 209) developed a conceptual framework for assessing and understanding the interaction between human well-being and the ecosystem. Hegetschweiler et al. (2017) considered the ways in which the perceptions and evaluations of visitors to a waterfront green space were relevant to the size and shape of that space as well as the associated recreational infrastructure and diversity measures within it. Previous research has also focused on spatial characteristics, such as accessibility (Elliot et al. 2022), connectivity (Yencha 2019), and the frequency of residents’ visits to riverside spaces (Elliot et al. 2022). In addition to the characteristics of waterfront green space, demographic characteristics (e.g. age, sex, and socioeconomic status) and socioeconomic status (e.g. income, education, and occupation) have recently been accounted for in studies (Dou et al. 2017; Oviedo et al. 2022). The above studies indicate that public perceptions of the CESs of urban waterfront green spaces are affected by many factors, including spatial attributes and the sociodemographic characteristics of visitors (Hegetschweiler et al. 2017). However, few studies have explored whether urban planning for waterfront green space influences people’s actual perception of CESs. In addition, clarifying the actual values, patterns, and potential of CES usage can contribute to the design and management of urban areas and enhance the well-being of different user populations (Rall et al. 2017). Further exploration of the relationship between planning objectives and public perception is needed to determine the impact of the physical characteristics of waterfront green space on public perceptions of CESs (Gai et al. 2022). In this study, we focus particularly on the following questions: Do the distributions of CESs in waterfront green spaces along strips of urban rivers differ? Are there discrepancies between designers’ plans for waterfront green spaces and residents' perceptions of those spaces? What factors might influence residents' actual perceptions of waterfront green space CESs? The goals of this study are to (i) propose a framework of CES types adapted for waterfront green space to quantify and assess the CESs of six waterfront green spaces along urban rivers, (ii) explore the impact of basic waterfront green space indicators and planning on the actual perception of CESs, and (iii) advance proposals for the construction or renovation of waterfront areas.
We believe, based on social ecology, that an assessment of urban waterfront green spaces from the perspective of CESs can provide a foundation for urban green space planning that allows for more equitable and sustainable use of these green space resources. In addition, the results of this study show how different factors influence public perceptions of CESs. As the socioecological perspective is central to CESs, a comprehensive understanding of the factors influencing such services and public preferences can help promote socioecological research in urban areas. Furthermore, the results of this study provide insight into how future urban waterfront green spaces can better realize the value of ecosystems, especially in developing countries.
2 Data and methods
2.1 The study area
This study was conducted in Shanghai, which is the centre of China's international economy and a prime location for finance, trade, shipping, and scientific and technological innovation. The Huangpu River, which flows through Shanghai and is its central river, has witnessed the growth of and change in the city. Since the mid-nineteenth century, the advantages of Shanghai’s geographical location and the feasibility of water transportation have enabled modern industries to emerge and develop along the river. The Huangpu River played an important role in port transportation, but at the same time, pollution and overdevelopment seriously damaged its ecological function. In recent years, the waterfront area of Shanghai has begun to undergo functional and spatial reconstruction. The pertinence and representativeness of this development make this area useful for studying the management and planning of waterfront green spaces.
In this study, we comprehensively considered the planning and design of waterfront spaces on both sides of the Huangpu River and selected six waterfront spaces with different geographical locations (Fig. 1) and functional positions as the research sites. These spaces are the Wusong Paotaiwan Wetland (WPW) park, North Bund Riverside (NBR) green space, Lujiazui Riverside (LR) park, Xuhui Riverside (XR) green space, Qiantan Leisure (QL) park, and Pujiang Country (PC) park. They are located along different sections of the Huangpu River, and each has been planned differently. According to the Huangpu River Waterfront Area Construction Plan (2018–2035, p 15), different colours are used to indicate that these six parks belong to different planned ecological spaces. They are divided according to the location conditions, functional characteristics, scale, and construction progress of the waterfront shoreline. These waterfront green spaces have their own characteristics and facilities and provide a range of CESs.
2.2 Evaluation indicators
By combining field investigations and GIS technology, we were able to conduct a detailed survey of the six waterfront green spaces to evaluate certain basic indicators and facilities within them (Table 1). Green infrastructure includes greenbelts, lawns, and trees, which enhance ecological diversity and serve important ecological functions (Den Hartog 2021, pp 7–8); furthermore, the greening rate is one of the most important metrics for assessing urban green spaces. It reflects the construction of green infrastructure and its capacity to supply CESs. A waterfront walkway serves as a transition from the urban landscape to the natural landscape. It encourages people to approach the river (Zeballos-Velarde 2022), thus influencing visiting patterns and enhancing interactions between residents and urban natural landscapes (Wang et al. 2020, pp 10–15). We used shoreline curvature (number of curved segments/total length of shoreline * 100%) to reflect the diversity of the studied waterfront walkways (Yang and Shao 2018). The level of access to water is based on shoreline openness (4 levels in total, with 1 indicating inaccessibility owing to solid walls, 2 indicating inaccessibility owing to railings, 3 indicating accessibility with railings, and 4 indicating direct water contact); it reflects the level of opportunities for the public to access the river. Gao et al. (2020, p 12) found that dynamic water spaces and the combination of water and surrounding elements are attractive. Previous studies have demonstrated that facilities affect the public use of parks (Kerishnan and Maruthaveeran 2021; Liu et al. 2021). Parks with outdated facilities are not conducive to improving the public's mental health, while well-endowed facilities attract park visitors (Guo et al. 2019; Yang et al. 2021). Therefore, attractiveness to visitors is based on facility richness level (4 levels in total, with 4 indicating more than 5 facilities, 3 indicating 3–5, 2 indicating 1–3, and 1 indicating less than one).
2.3 Data collection regarding public preferences and progress
2.3.1 Social data sources
In recent years, emerging big data technology, such as social media platforms, has provided a means of obtaining usage patterns in urban ecosystems. The CES perception data in this study were collected through Dianping, one of the most widely used social media platforms in China; this platform includes consumer reviews. These data reveal preferences that can be used for research purposes. On Dianping, users can upload photographs or videos that they have taken during or after park visits and share their experiences and feelings; thus, the platform is a good source for gaging public perception. The survey was conducted by analysing the documents and photographs uploaded by users to Dianping. The advantage of conducting a study based on data from social media platforms is that the database provides a large amount of relatively easily accessible information. The large sample has good statistical feasibility and enables our research results to better represent the public's perception; furthermore, this approach can be expanded to more urban waterfront green spaces.
For this study, we conducted an analysis that coupled photograph analysis with document analysis (Tian et al. 2020) on the basis of the social media comments of each user. First, we excluded photographs taken outside green spaces and inside buildings, as well as those with only buildings and no blue‒green environment or where the subject of the image was a person who was not interacting with the natural environment (e.g. selfies). Next, we identified where valid photographs had been taken and distinguished the value types (Table 2) associated with each location by analysing each image. We assigned scores of different types of CESs by multiplying the proportion of each type of CES value assessed for each user by 100. Along with photographic data, relevant text uploaded by the same user was considered additional evidence. We analysed the various CES value types found in the text and assigned a score to each value type by multiplying the ratio of each type of CES value assessed for each user by 100. Finally, we added the two scores of the photograph and text analysis to calculate the final allocation of each value type. Together, the value type tables and the value assignment tables, which comprise the preference data used for the following CES evaluation, show people's perceptions of CESs and the levels of different value types.
2.3.2 Spatial data sources
Distance can effectively reflect the spatial relationship between points with social value and natural resources (D. Cheng et al. 2018). By comprehensively considering the geographical and environmental features of the six selected waterfront spaces, we were able to create three environmental layers to represent distance from the road, distance from the water body, and distance from attractions. These environmental layers were calculated with the Euclidian distance tool, one of the ArcGIS Spatial Analyst Tools. The survey points from the social preference data were also digitalized in ArcGIS 10.3.
2.3.3 Mapping and value quantification
We used the SolVES (http://solves.cr.usgs.gov) tool to map and value CESs. SolVES is “a tool that was designed to assess, map and quantify social values” (Sherrouse and Semmens 2015), particularly the values of cultural services. We employed the value mapping model to output a VI map and to explore the relationships among environmental metrics. The model reflects the spatial distribution of areas within parks that may be capable of providing different types of CESs.
The data used for operating SolVES were stored in a geodatabase source file named SolVES.gbd. It included a study area layer, a survey point layer, a value type table, and a value allocation table. These data were obtained and prepared through social and spatial data.
Figure 2 shows the evaluation framework of this study, including waterfront green space evaluation indicators and data for running the SolVES model.
3 Results
3.1 Basic facilities and environmental quality survey
Table 4 shows that the waterfront green spaces were quite distinct from each other, ranging from the available facilities to the infrastructure they contained. WPW and PC provided the highest number of facilities and had the largest size and greening rate. They are theme parks containing diverse terrains, which allow for a greater variety of infrastructure, such as amusement parks, picnic spaces, and public restrooms. Residents can also enjoy water activities such as boating and fishing, which provide further opportunities to access the water. No specific themes were found in the other four urban central green spaces, which were planned and designed according to local cultural characteristics. Because their main functions may be solely to provide open spaces for residents to socialize and engage in free activities, these green spaces contained fewer amusement facilities. In addition, they have less green infrastructure and a lower greening rate. Because these green spaces were constructed along the Huangpu River, flood walls were built along the riverside shoreline to provide flood protection; thus, the shoreline curvature and level of accessibility to the water are low.
3.2 Ranking and distribution of various value types within the waterfront green spaces
3.2.1 User survey
The number of survey users varied (Table 3) by waterfront green space. WPW had the most investigated users (2174) and CES value points (9493), while PC had the highest effective data rate (95.77%). These two waterfront green spaces embody certain themes that attract more visitors and thus receive more comments. Compared to these two theme parks, the other four green spaces yielded far fewer valid users and CES value points. The effective data rates of these four green spaces were also significantly lower than those of WPW and PC. NBR, LR, XR, and QL are linear strip waterfront green spaces that are often connected by bridges to other green spaces. These spaces are difficult to separate; thus, photographs uploaded by social media users often included other areas, which may have led to low data efficiency.
3.2.2 Planned function public perception survey
In accordance with the high values calculated by the SolVES tool, Table 5 shows the significant differences among the various CES value types in waterfront green spaces. Each waterfront green space has different rankings according to the CES high value indexes. Some CES value types are not identified in every waterfront green space. Some CES types of green spaces with high value indexes are closely related to the functional positioning of their construction plans, while others are not. The WPW is an oval-shaped park with a historical education theme. The type of value in this green space perceived to have the highest value index is the “sense of place”, which is a historical value consistent with the planned function of the WPW. In addition to its historical value, the WPW, a very popular urban green space, is better perceived by the public in terms of “activities in amusement areas”, which are of recreational value. The NBR and LR are located in the centre of the city, and their main function is to provide space within which residents can relax and socialize. The evaluation results indicate that their recreational and therapeutic values have received increased public attention. However, the area containing NBR is the most reflective of Shanghai's local history and culture; many historical buildings and cultural landscapes are distributed around and within the green space. This green space is recognized to have the highest value for “sense of place”. For QL, which was planned as a cultural and creative centre, the values of “being physically active outdoors”, “sense of place”, and “architectural environment” have high values. Although it contains children's playgrounds with features such as slides and sandpits, the value of “activities in amusement areas” is seldom perceived by the public in QL. In XR, aesthetic value (i.e. green landscape) and recreational value (i.e. interaction with the landscape along the riverside) are more commonly perceived by the public. The planned function of XR is as a “cultural and sports center”; however, historical values are less perceived by the public in XR. PC has a rich woodland and grassland landscape and thematically focuses on the integration of ecology into society. The types of CESs that the public primarily perceives in PC, such as “green landscape”, “water view”, and “activities in amusement area”, are in keeping with the main services that urban planning desires this green space to provide.
In terms of the distribution of value types, Figs. 3, 4, 5, and 6 show similarities in the hotspot distribution patterns within different waterfront green spaces. Among these six waterfront green spaces, areas of high aesthetic and therapeutic value are distributed mainly along walkways. In addition to promoting running and cycling, winding walkways are likely to attract visitors to linger and take photographs. In this study, distribution maps of therapeutic value could not be created for WPW or PC due to a lack of value points. High-value recreational and historical values are concentrated around the main attractions, while low-value recreational values have a wider distribution. Among the four types of CES values, aesthetic and recreational values are most widely perceived in each green space.
4 Discussion
4.1 Exploring the factors influencing the perception and distribution of CESs in waterfront green spaces
The goal of traditional planning for open space is to provide a high-density, well-connected open space that enriches people's outdoor activities, such as cycling, jogging, and walking, thereby increasing the frequency of social interactions (Jian et al. 2020). However, Bahrini et al. (2017) found that high accessibility alone cannot guarantee the high usage of space. The findings of this study revealed that although the two theme parks are quite distant from the central city, they saw a greater number of survey users than did the other areas. We believe that a waterfront green space with a clear theme is more likely to attract visitors, thereby increasing its visit frequency. The results of field research showed that the public perception of CESs is also influenced by the theme of the waterfront green space. WPW was planned as a historical and patriotic education base and therefore contains many historical sites and related background presentations. Higher “sense of place” and “historic site” values are perceived by the public in WPW. QL has many special infrastructure elements along the waterfront, such as skateboard parks, and rock-climbing facilities in the woods, so it is easy for people to perceive its outdoor sports value. In addition, amusement facilities and road signs affect public perceptions of different CES value types. Based on the CES value types adapted to the waterfront green space survey results, although amusement facilities with special features and road signs presenting introductory information decrease the diversity of CES types, they may enhance visitors’ perception of various CESs, resulting in an increase in the magnitude of attention given to those specific CESs. Although the design of the four downtown waterfront green spaces varies, these parks do not have clear themes. People perceive many different types of CESs when visiting these green spaces. The recreational and therapeutic values provided by their blue‒green infrastructure are perceived more often, while other specific values provided by the site's facilities, such as historical value, are only moderately perceived. It is not to say that recreational and therapeutic value is not important. Barton and Pretty (2010) reported that green exercise has health benefits. Zhang and Xu (2023) emphasized that urban green parks are preferred by residents for outdoor activities and have positive effects on regulating emotional states. In addition, we must emphasize that all the “facilities” mentioned above refer not only to the facilities but also to the areas in which they are located, including the surrounding blue‒green environment. When evaluating the CESs that people perceive based on artificial facilities, recreational facilities or historical buildings cannot be separated from blue‒green spaces. Because artificial facilities themselves cannot be regarded as ecosystems, the services they provide are not considered CESs; this situation creates problems in many CES studies. Our study avoids this problem by eliminating photographs without blue-green environments during the screening of valid images, ensuring that the services people received met the definition of CESs.
As these green areas were built next to the water, “fresh” and “open” visual sensations stood out, especially along the shoreline. Moreover, combining walkways and green landscapes improves the aesthetic experience. As shown in Figs. 3, 4, 5, 6, among the four value types, the high-value areas are distributed along the riverbank. The high-value areas for therapeutic value in Fig. 6 are distributed largely along walkways and waterfronts, suggesting that better water accessibility and winding walkways can increase the variety of outdoor activities. Visitors prefer landscapes near water and consider areas near water landscapes more suitable for recreational activities (Wang et al. 2016). Table 4 shows that PC has the highest rate of shoreline curvature and a higher level of access to water, with water and outdoor activity values receiving more attention in its functional value rankings. Increasing shoreline curvature while ensuring public access to water can enhance people’s interactions with both botanical and water landscapes, thus strengthening visitors’ aesthetic experience and therapeutic activities.
4.2 Understanding the gap between public perceptions of CESs in waterfront green spaces and the planning of these spaces
The waterfront green spaces in this study have clear planning objectives. Infrastructures with specific themes have been constructed within these spaces to provide one or several types of CES value. Table 5 shows the planned function of the six waterfront green spaces and the ranked values of their perceived CES value types. For WPW, NBR, LR, QL, and PC, the public perception of CESs matched their planned function. In general, waterfront green spaces meant for aesthetic experience and recreational activities provide CESs that match expectations.
However, there are still some discrepancies between planning and actual public perception. XR is located in a region with many historical and cultural sites and was planned as a cultural and creative centre. The examples of industrial heritage along the riverside, such as tower cranes, are intended to provide the public with a sense of place. Facilities within green spaces can also provide “hard recreationists” (Dick et al. 2022) with energy-intensive fitness activities such as rock climbing and skating. Nevertheless, Table 5 shows that the top three M-VI values contained neither historical nor therapeutic value. Rather, both “water view” and “green landscape” are types of aesthetic value, and “interaction with the landscape along the riverside” is a type of recreational value. Facilities are at the centre of people's activities, but activity type is not completely related to facility type. People can rock climb in XR; however, its “thematic sports activities” value ranked only fourth, which was unexpectedly low. This may be because locals and visitors are unaware of the symbolism of the tower cranes. In addition, rock climbing is not suitable for everyone who visits XR. This illustrates that detailed planning for different regions and populations is necessary.
In summary, the assessment of CES value types adapted to waterfront green spaces in this study reflects regional differences and highlights the importance of carefully planning and designing waterfront green spaces.
4.3 Rethinking the planning and design of waterfront green space.
Studies have shown that the CESs of waterfront green spaces are not only related to the facilities within those spaces, the degree of water accessibility, and the curvature of the shoreline but also influenced by planning to a certain extent. High-quality open waterfront green spaces with unique characteristics and activity areas serving different functions result from careful landscape planning and adequate facility support; they also benefit from consideration of the functional characteristics of different zones and the interactions among different plans.
To ensure that waterfront green spaces have features that attract visitors and can provide various types of CESs, planners first need to improve landscape diversity according to regional characteristics. Studies have shown that landscape diversity increases visual focus, which means that greater heterogeneity can increase the attractiveness of green spaces (Qiu et al. 2023). In addition, in this study, the provision of clear themes, open spaces, waterfront activities, and resting places enhanced the use and perception of CESs. Another study on urban green spaces also showed that urban forests, water bodies, and parks are preferred as urban green spaces (Syrbe et al. 2021).
Different types and locations of waterfront green spaces require different planning directions. A waterfront green space in the city centre is surrounded by dense buildings, so harmonious, complex scenery formed by intertwining plants and buildings should be considered (Qiu et al. 2023). This type of scenery may help city dwellers relieve stress. High-quality green space will attract people to participate in various sports activities and enjoy socializing in the area (Brindley et al. 2019). Therefore, an outdoor area needs to provide a certain amount of open space to provide a place for residents to socialize. Areas rich in history and culture should consider displaying industrial remnants along the shoreline or combining waterfront landscapes with historical industrial sites to provide a richer recreational experience. The upstream and downstream areas of the river are used mainly for ecological construction. Combining family activities and special sports facilities while fully developing the green landscape enhances the quality of these green spaces.
5 Conclusions and limitations
In this study, we assessed CESs through data obtained from a social media platform and explored the influence of planning and interior facilities on urban waterfront green space CESs by using the regeneration of Shanghai's Huangpu River waterfront as a case study. We found that waterfront green spaces with specific themes attract more visitors and provide a greater variety of CESs. In waterfront areas, high levels of accessibility to water and winding walkways enrich visitors’ activities, thereby increasing the recreational and therapeutic value of the area. The combination of building features with green landscapes and a good view of the water provide visual aesthetics. Additionally, we suggest that in planning, using a specific theme and providing an introduction about open spaces should be considered, as these approaches have been shown to improve residents’ perception of CESs, especially those associated with historical value.
This study was conducted along the Huangpu River. The reconstruction of this waterfront area is a typical city renewal project, and the results can provide a planning reference for other cities. However, there were limitations in the research process. The survey data, including photographs and text, were collected from a social media platform, which leads to bias in aesthetic value because the photographs were classified by the researchers (Clemente et al. 2019). Yoshimura and Hiura (2017) noted that when using photographs as proxies for CESs, there is an inevitable tendency to lean towards aesthetic values. Ultimately, photographs tend to exhibit pleasing and beautiful characteristics. In future research, traditional methods such as questionnaires, interviews, and social media surveys should be combined to more comprehensively measure public opinion and perception (Cheng et al. 2019). Moreover, only a few common green space assessment metrics were used. Future research should construct a metric framework for waterfront green space assessment to improve the accuracy and comprehensiveness of these types of studies.
In general, this study conducted a survey on CES perception to provide a basic understanding of the CES performance of existing urban waterfront spaces, explore the influences of these spaces on public perception, and offer suggestions for the future construction of urban spaces. The results should encourage government agencies and urban planners to build urban open spaces that are resilient, sustainable, and diverse.
References
Abhijith KV, Kumar P, Gallagher J, McNabola A, Baldauf R, Pilla F, Pulvirenti B (2017) Air pollution abatement performances of green infrastructure in open road and built-up street canyon environments—a review. Atmos Environ 162:71–86. https://doi.org/10.1016/j.atmosenv.2017.05.014
Bahrini F, Bell S, Mokhtarzadeh S (2017) The relationship between the distribution and use patterns of parks and their spatial accessibility at the city level: a case study from Tehran, Iran. Urban for Urban Green 27:332–342. https://doi.org/10.1016/j.ufug.2017.05.018
Barton J, Pretty J (2010) What is the best dose of nature and green exercise for improving mental health? A multi-study analysis. Environ Sci Technol 44(10):3947–3955. https://doi.org/10.1021/es903183r
Brindley P, Cameron RW, Ersoy E, Jorgensen A, Maheswaran R (2019) Is more always better? Exploring field survey and social media indicators of quality of urban greenspace, in relation to health. Urban for Urban Green 39:45–54. https://doi.org/10.1016/j.ufug.2019.01.015
Cheng D, Mengting LI, Ding Y, Che Y (2018) Assessment of the urban waterfront based on social values of ecosystem services: a case study of the Huangpu River waterfront. Shanghai Urban Plan Rev 5:125–130
Cheng X, Damme SV, Li L, Uyttenhove P (2019) Evaluation of cultural ecosystem services: a review of methods. Ecosyst Serv 37:100925
Cialdea D, Pompei C (2022) The waterfront development in Europe: between planning and urban design sustainability. Paper presented at the Innovating Strategies and Solutions for Urban Performance and Regeneration, Cham
Clemente P, Calvache M, Antunes P, Rui S, Cerdeira JO, Martins MJ (2019) Combining social media photographs and species distribution models to map cultural ecosystem services: the case of a Natural Park in Portugal. Ecol Ind 96:59–68
Costanza R, de Groot R, Braat L, Kubiszewski I, Fioramonti L, Sutton P, Grasso M (2017) Twenty years of ecosystem services: how far have we come and how far do we still need to go? Ecosyst Serv 28:1–16. https://doi.org/10.1016/j.ecoser.2017.09.008
Den Hartog H (2021) Engineering an ecological civilization along Shanghai’s main waterfront and coastline: evaluating ongoing efforts to construct an urban eco-network. Front Environ Sci 9:639739. https://doi.org/10.3389/fenvs.2021.639739
Dick J, Andrews C, Orenstein DE, Teff-Seker Y, Zulian G (2022) A mixed-methods approach to analyse recreational values and implications for management of protected areas: a case study of Cairngorms National Park, UK. Ecosyst Serv 56:101460. https://doi.org/10.1016/j.ecoser.2022.101460
Dou Y, Zhen L, De Groot R, Du B, Yu X (2017) Assessing the importance of cultural ecosystem services in urban areas of Beijing municipality, Ecosyst Serv 24:79–90. https://doi.org/10.1016/j.ecoser.2017.02.011
Durán Vian F, José Pons Izquierdo J, Martínez MS (2021) River-city recreational interaction: a classification of urban riverfront parks and walks. Urban For Urban Green 59:127042. https://doi.org/10.1016/j.ufug.2021.127042
Elliot T, Torres-Matallana JA, Goldstein B, Babí Almenar J, Gómez-Baggethun E, Proença V, Rugani B (2022) An expanded framing of ecosystem services is needed for a sustainable urban future. Renew Sustain Energy Rev 162:112418. https://doi.org/10.1016/j.rser.2022.112418
Figueroa-Alfaro RW, Tang Z (2017) Evaluating the aesthetic value of cultural ecosystem services by mapping geo-tagged photographs from social media data on Panoramio and Flickr. J Environ Planning Manag 60(2):266–281. https://doi.org/10.1080/09640568.2016.1151772
Fish R, Church A, Winter M (2016) Conceptualising cultural ecosystem services: a novel framework for research and critical engagement. Ecosyst Serv 21:208–217. https://doi.org/10.1016/j.ecoser.2016.09.002
Gai S, Fu J, Rong X, Dai L (2022) Users’ views on cultural ecosystem services of urban parks: an importance-performance analysis of a case in Beijing, China. Anthropocene 37:100323. https://doi.org/10.1016/j.ancene.2022.100323
Gao JX, Song T, Zhang B, Han YW, Gao XT, Feng CY (2016) The relationship between urban green space community structure and air temperature reduction and humidity increase in Beijing. Resourc Sci 38(6):1028–1038
Gao Y, Zhang T, Zhang W, Meng H, Zhang Z (2020) Research on visual behavior characteristics and cognitive evaluation of different types of forest landscape spaces. Urban for Urban Green 54:126788. https://doi.org/10.1016/j.ufug.2020.126788
Ghermandi A (2018) Integrating social media analysis and revealed preference methods to value the recreation services of ecologically engineered wetlands. Ecosyst Serv 31:351–357. https://doi.org/10.1016/j.ecoser.2017.12.012
Guo S, Yang G, Pei T, Ma T, Song C, Shu H, Du Y, Zhou C (2019) Analysis of factors affecting urban park service area in Beijing: perspectives from multi-source geographic data. Landsc Urban Plan 181:103–117. https://doi.org/10.1016/j.landurbplan.2018.09.016
Hagerman C (2007) Shaping neighborhoods and nature: urban political ecologies of urban waterfront transformations in Portland. Oregon Cities 24(4):285–297. https://doi.org/10.1016/j.cities.2006.12.003
Han S, Kwan M, Miao C, Sun B (2023) Exploring the effects of urban spatial structure on green space in Chinese cities proper. Urban For Urban Green 87:128059. https://doi.org/10.1016/j.ufug.2023.128059
He B-J (2019) Towards the next generation of green building for urban heat island mitigation: zero UHI impact building. Sustain Cities Soc 50:101647. https://doi.org/10.1016/j.scs.2019.101647
He B-J, Zhu J, Zhao D-X, Gou Z-H, Qi J-D, Wang J (2019) Co-benefits approach: opportunities for implementing sponge city and urban heat island mitigation. Land Use Policy 86:147–157. https://doi.org/10.1016/j.landusepol.2019.05.003
Hegetschweiler KT, de Vries S, Arnberger A, Bell S, Brennan M, Siter N, Hunziker M (2017) Linking demand and supply factors in identifying cultural ecosystem services of urban green infrastructures: a review of European studies. Urban for Urban Green 21:48–59. https://doi.org/10.1016/j.ufug.2016.11.002
Jian IY, Luo J, Chan EHW (2020) Spatial justice in public open space planning: accessibility and inclusivity. Habitat Int 97:102122. https://doi.org/10.1016/j.habitatint.2020.102122
Kerishnan PB, Maruthaveeran S (2021) Factors contributing to the usage of pocket parks—a review of the evidence. Urban for Urban Green 58:126985. https://doi.org/10.1016/j.ufug.2021.126985
Liang B, Ma Y, Li H (2015) Research on cooling effect of the landscape green space and urban water in Guilin City. Ecol and Environ Sci 24(2):278–285
Liu D, Kwan M, Kan Z (2021) Analysis of urban green space accessibility and distribution inequity in the City of Chicago. Urban for Urban Green 59:127029. https://doi.org/10.1016/j.ufug.2021.127029
MEA (Millennium Ecosystem Assessment) (2005) Ecosystems and human well-being: synthesis. http://www.millenniumassessment.org
Mu B, Zhao R, Liu Y, Yang L, Xu E, Zhang Y, Wei H, Tian G (2024) A bibliometric assessment of the science and practice of blue–green space (BGS): hot spots, lacunae, and opportunities. Socio Ecol Pract Res 6:5–20. https://doi.org/10.1007/s42532-024-00178-w
Oviedo M, Drescher M, Dean J (2022) Urban greenspace access, uses, and values: a case study of user perceptions in metropolitan ravine parks. Urban For Urban Green 70:127522. https://doi.org/10.1016/j.ufug.2022.127522
Pouso S, Borja Á, Fleming LE, Gómez-Baggethun E, White MP, Uyarra MC (2021) Contact with blue-green spaces during the COVID-19 pandemic lockdown beneficial for mental health. Sci Total Environ 756:143984. https://doi.org/10.1016/j.scitotenv.2020.143984
Qiu Y, Pan H, Kalantari Z, Giusti M, Che S (2023) The natural focus: combining deep learning and eye-tracking to understand public perceptions of urban ecosystem aesthetics. Ecol Ind 156:111181. https://doi.org/10.1016/j.ecolind.2023.111181
Rall E, Bieling C, Zytynska S, Haase D (2017) Exploring city-wide patterns of cultural ecosystem service perceptions and use. Ecol Ind 77:80–95. https://doi.org/10.1016/j.ecolind.2017.02.001
Sherrouse BC, Semmens DJ (2015) Social Values for Ecosystem Services, version 3.0 (SolVES 3.0): documentation and user manual. Open-File Report
Smith N, Georgiou M, King AC, Tieges Z, Chastin S (2022) Factors influencing usage of urban blue spaces: a systems-based approach to identify leverage points. Health Place 73:102735. https://doi.org/10.1016/j.healthplace.2021.102735
Summers JK, Smith LM, Case JL, Linthurst RA (2012) A review of the elements of human well-being with an emphasis on the contribution of ecosystem services. Ambio 41(4):327–340. https://doi.org/10.1007/s13280-012-0256-7
Syrbe R-U, Neumann I, Grunewald K, Brzoska P, Louda J, Kochan B, Bastian O (2021) The value of urban nature in terms of providing ecosystem services related to health and well-being: an empirical comparative pilot study of cities in Germany and the Czech Republic. Land 10(4):40341. https://doi.org/10.3390/land10040341
Tian T, Sun L, Peng S, Sun F, Che Y (2020) Understanding the process from perception to cultural ecosystem services assessment by comparing valuation methods. Urban for Urban Green 57:126945
Wang Y, Fu B, Lv Y, Yang K, Che Y (2016) Assessment of the social values of ecosystem services based on SolVES model: A case study of Wusong Paotaiwan Werland Forest Park, Shanghai, China. Chin J Appl Ecol 27(6):1767–1774
Wang Y, Dewancker BJ, Qi Q (2020) Citizens’ preferences and attitudes towards urban waterfront spaces: a case study of Qiantang riverside development. Environ Sci Pollut Res 27(36):45787–45801. https://doi.org/10.1007/s11356-020-10419-6
Wu D, Wang Y, Fan C, Xia B (2018) Thermal environment effects and interactions of reservoirs and forests as urban blue-green infrastructures. Ecol Ind 91:657–663. https://doi.org/10.1016/j.ecolind.2018.04.054
Yang C, Shao B (2018) Influence of waterfront public space elements on lingering vitality and strategies: taking two typical waterfronts along Huangpu River, Shanghai as examples. Urban Archit 4:40–47
Yang Z, Fang C, Li G, Mu X (2021) Integrating multiple semantics data to assess the dynamic change of urban green space in Beijing, China. Int J Appl Earth Obs Geoinf 103:102479. https://doi.org/10.1016/j.jag.2021.102479
Yencha C (2019) Valuing walkability: new evidence from computer vision methods. Transp Res Part A: Policy Pract 130:689–709. https://doi.org/10.1016/j.tra.2019.09.053
Yoshimura N, Hiura T (2017) Demand and supply of cultural ecosystem services: use of geotagged photos to map the aesthetic value of landscapes in Hokkaido. Ecosyst Serv 24:68–78. https://doi.org/10.1016/j.ecoser.2017.02.009
Zeballos-Velarde C (2022) A methodological framework for the conservation and planning of urban spaces in historical centers around riverfronts. The Case of Arequipa, Peru. Paper presented at the Conservation of Architectural Heritage, Cham
Zhang J, Xu E (2023) Investigating the spatial distribution of urban parks from the perspective of equity-efficiency: evidence from Chengdu, China. Urban for Urban Green 86:128019. https://doi.org/10.1016/j.ufug.2023.128019
Acknowledgements
This research was supported by the program of the Science and Technology Commission of Shanghai Municipality (Grant No. 21DZ1202702) and the Fundamental Research Funds for the Central Universities (No. 2022ECNU-XWK-XK001).
Funding
This research was supported by the program of the Science and Technology Commission of Shanghai Municipality (Grant No. 21DZ1202702), the Fundamental Research Funds for the Central Universities (No. 2022ECNU-XWK-XK001).
Author information
Authors and Affiliations
Contributions
Dr. Yue Che is responsible for the study conception and design, and providing critical revisions; Tian Tian is responsible for the acquisition of data, analysis of data, creating graphs, and drafting manuscript; Tao Yu is responsible for the acquisition and analysis of data; Yuzhen Qian is responsible for the interpretation of data and providing critical revisions; Lingzhi Deng is responsible for providing critical revision.
Corresponding author
Ethics declarations
Conflict of interest
Yue Che is a member of the Editorial Board of Socio-Ecological Practice Research. He was not involved in the review or handling of the manuscript. All authors have no conflict of interests to declare that are relevant to the content of this article.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Tian, T., Yu, T., Qian, Y. et al. Assessing public perceptions of the cultural ecosystem services waterfront spaces provide along the Huangpu River in Shanghai, China, in support of urban waterfront planning and design. Socio Ecol Pract Res 6, 141–154 (2024). https://doi.org/10.1007/s42532-024-00181-1
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s42532-024-00181-1