Skip to main content
NCBI home page
Ambio logoLink to Ambio
. 2021 May 13;51(1):135–151. doi: 10.1007/s13280-021-01556-4

Freshwater systems and ecosystem services: Challenges and chances for cross-fertilization of disciplines

Ágnes Vári 1,, Simone A Podschun 2, Tibor Erős 3, Thomas Hein 4,5, Beáta Pataki 6, Ioan-Cristian Iojă 7, Cristian Mihai Adamescu 8, Almut Gerhardt 9, Tamás Gruber 10, Anita Dedić 11, Miloš Ćirić 12, Bojan Gavrilović 13, András Báldi 1
PMCID: PMC8651970  PMID: 33983559

Abstract

Freshwater ecosystems are among the most threatened in the world, while providing numerous essential ecosystem services (ES) to humans. Despite their importance, research on freshwater ecosystem services is limited. Here, we examine how freshwater studies could help to advance ES research and vice versa. We summarize major knowledge gaps and suggest solutions focusing on science and policy in Europe. We found several features that are unique to freshwater ecosystems, but often disregarded in ES assessments. Insufficient transfer of knowledge towards stakeholders is also problematic. Knowledge transfer and implementation seems to be less effective towards South-east Europe. Focusing on the strengths of freshwater research regarding connectivity, across borders, involving multiple actors can help to improve ES research towards a more dynamic, landscape-level approach, which we believe can boost the implementation of the ES concept in freshwater policies. Bridging these gaps can contribute to achieve the ambitious targets of the EU’s Green Deal.

Keywords: Aquatic ecosystems, Blue infrastructure, Ecosystem functions, EU Water Framework Directive, Inland waters

Introduction

Nature is valued by people in many different ways, while at the same time natural ecosystems are being degraded and destroyed at an unprecedented scale (Díaz et al. 2015; European Environment Agency (EEA) 2019). One approach to assess and convey the value of nature to mankind relies on formulating the vital dependence of humans on nature in terms of ‘ecosystem services’, or as ‘nature’s contribution to people’ (Díaz et al. 2015; Pascual et al. 2017). In order to enhance policy uptake and the chances of success of conservation and restoration attempts, high-level science-policy platforms have been established that served policy makers with integrated and agreed information on the extent of biodiversity and ecosystem loss and also presented projections to the future (Díaz et al. 2015; IPBES 2018a; European Environment Agency (EEA) 2019).

Freshwater ecosystems are among the most threatened in the world, with global declines in their area by 64% from 1997 to 2011, and for Europe by 50% from 1970 to 2008 (Costanza et al. 2014; IPBES 2018a; Gozlan et al. 2019). They are also especially vulnerable to multistressor effects (Borgwardt et al. 2019). Freshwaters—lakes, rivers, wetlands, including floodplains—have always played a major role in the history of humankind and the goods and services they provide are of key importance to our survival and well-being (Wantzen et al. 2016). Systematic reviews list between 20 and 32 ecosystem services (ES), the most frequently mentioned ones being recreation and tourism, water supply, water quality control, habitat provision, erosion prevention as well as food supply and climate regulation (Hanna et al. 2018; Kaval 2019). Freshwater ES studies name numerous provisioning services, like supplying fertile soils for agriculture and places for orchards in the floodplains, reed for construction, drinking water, and food (fish, crustaceans, molluscs) (Reynaud and Lanzanova 2017; Tomscha et al. 2017; Hanna et al. 2018; Hossu et al. 2019). Freshwater ecosystems also provide several regulating services, like groundwater recharge, flood regulation, microclimate regulation, carbon sequestration, water quality control (Bullock and Acreman 2003; Aldous et al. 2011; Tomscha et al. 2017; Hossu et al. 2019) as well as cultural services, such as the existence of spiritual places, their symbolic and aesthetic value, inspiration, giving a sense of place to people and several recreational aspects—swimming, angling, boating (Wantzen et al. 2016; Hanna et al. 2018; Hossu et al. 2019; Thiele et al. 2020). In addition, services like providing habitat for fish, amphibian and bird populations, including spawning grounds and migration as well as seed dispersal (Aldous et al. 2011; Hettiarachchi et al. 2015; Tomscha et al. 2017; Hanna et al. 2018) support the overall functioning of the ecosystem. Hence, it is not surprising that river and lake ecosystems as well as wetlands have the highest estimated per ha value of ES supply of all inland ecosystems (12,512 × 1012 $/year and 25,681 × 1012 $/year for lakes/rivers and for freshwater wetlands, compared to 3137–4166 × 1012 $/year for temperate forests and grasslands) while being the smallest in terms of surface area (0.39% and 0.12% for lakes/rivers and for freshwater wetlands—Costanza et al. 2014).

Despite their importance, research on freshwater ecosystem services (FES) is limited. For example, reviews on riverine ES found only 69–89 studies across the past years (Hanna et al. 2018; Kaval 2019), and 1026 studies for lake and wetland ES together (Xu et al. 2018), while Reynaud and Lanzanova (2017) found 133 studies focusing solely on lake economic valuation. A systematic review on the assessment and conservation management in large floodplain rivers revealed that only 1.6% of the studies addressed ES (Erős et al. 2019), even though considering ES can be highly relevant when assessing the effects of river restoration as shown in the recent study by Funk et al. (2020). On the other hand, a review of ~ 3.000 publications showed that many papers on ES were published in general environmental journals, or specific sectoral journals (forestry, agriculture, etc.), but hardly any in water-related journals (McDonough et al. 2017). It is only in recent years that more comprehensive water-related projects on ES can be found, such as AQUACROSS (Anzaldua et al. 2018; Langhans et al. 2019) and RESI (Podschun et al. 2018).

On the one hand, several reviews (e.g. Martin-Ortega et al. 2015; Tomscha et al. 2017; Hanna et al. 2018; Kaval 2019) identified research gaps in freshwater ES related to the assessment of multiple ES, ES interactions (trade-offs and synergies) and transdisciplinary approaches, which are more of a general nature and not restricted to ES applications in freshwater ecosystems. On the other hand, ‘traditional’ freshwater ecological literature has dealt with a diversity of freshwater-specific issues and developed a set of ecosystem-specific concepts e.g. River Continuum Concept (Vannote et al. 1980), Flood Pulse Concept (Junk et al. 1989), Stable States theory for shallow lakes (Scheffer 1990). Integrating freshwater-related ecological concepts and discussing elementary features of lentic and lotic waters can help advance ES research as well as aquatic management practices.

In this paper we summarise the output of a workshop aimed at identifying knowledge gaps in freshwater ecosystem services (FES)-related research and addressed the following research questions:

What are the challenges and knowledge gaps in freshwater ES studies that are of outstanding importance:

  1. specifically for the analysis of freshwater ecosystems and their services?

  2. for the implementation of the ES concept in management and integrated valuation of freshwaters and related policies?

  3. for future work in ES research in general, where freshwater research can advance ES research?

Methods

The workshop ‘Aquatic ecosystem services—assessment, management and socio-economic challenges’ took place between 27th and 28th of November 2019, in Budapest, Hungary (http://aquaticES.ecolres.hu/). The workshop aimed to give an overview on the state-of-the-art knowledge on aquatic ecosystem services, from (anthropogenic) pressures to the condition of rivers and lakes and the diversity of benefits that humans obtain from these ecosystems, including the possibilities and potential drawbacks of quantifying natural systems.

The 22 participants were all experts working in the field of freshwater research and/or ecosystem service research and coming from Central and Eastern Europe (from Serbia, Bosnia and Herzegovina, Croatia, Romania, Hungary, Austria, Germany). The workshop comprised three steps (1) introducing participants and some invited presentations as food for thought (2) a world café with two rounds and two groups in each (3) a joint reflection and summary of results.

In the first round of the world café issues were collected that the participants found relevant in their own (freshwater related) experience regarding the application of the ES framework. Lead by the moderators, positive as well as negative experiences were gathered, aspects where the ES framework was found useful and where difficulties were encountered in its application to freshwater ecosystems. In the second round of the world café the participants changed groups. After the moderators wrapped up the first round, the presented difficulties were further developed towards the identification of knowledge gaps. The second day, this collection was structured into emerging clusters, discussed and refined in a joint reflection by the thirteen authors of this paper.

After the workshop, the topics were complemented with an extensive literature review. Thus, while all workshop members framed the study and contributed evidence and ideas, the decisions on the final content were made by the authors of the paper (including decisions on knowledge gap categorization and direction of knowledge transfer). Literature was screened based on keyword searches related to the emerging issues, background knowledge and expertise of the authors and snowballing.

Altogether, we identified six major topics, with a number of challenges and knowledge gaps (Table 1). We classified four different types of knowledge gaps: some topics involve real gaps in knowledge which can be called “conceptual or relationship knowledge gaps”, others reflect gaps in methodological implementation (“methodology gaps”). In some cases, knowledge is theoretically available, but not sufficiently widespread (see also 3.6): transfer is limited either geographically (e.g. from Western Europe towards South-east Europe) or between sectors or organizations (e.g. from academia towards management) or simply not well enough known (possibly also because methodology is not easy to implement)—we can refer to these rather as “challenges” that need attention and fostering.

Table 1.

Overview of challenges and knowledge gaps summarizing special features related to freshwater ecosystems and their assessment within an ecosystem services (ES) framework with good examples (possible steps) towards a solution

No. Special features Possible steps KT Good examples KG
1 Unique features of freshwater habitats and their role in the supply of ESs
Unique spatial structure—more complex to model Combine 3D and linear features of waters (embedded in terrestrial ecosystems) in holistic watershed models F→ES Nedkov & Burkhard (2012) show how results from hydrological modelling (KINEROS) in the municipality of Etropole, Bulgaria, were extracted and recombine based on ratios of landcover in a matrix-type approach. This is a good example for integrating flood regulation in the watershed, but less successful for floodplain processes. Calculating ES “backwards”, from a specific model to a matrix might be also feasible for other areas of ES assessment. 2
Directional connections, flow hierarchy, connectivity—fragmentation effects – more complex to manage Link ES assessment to basic ecological/hydrological concepts of riverine systems F→ES 2 & 3
Strong connections: longitudinal & lateral (flood pulses, water level fluctuations) & subsurface (invisible connections with groundwater) Add sub-surface waters to models F→ES

Some databases available, e.g. EU-SoilHydroGrids, but linkage to models difficult.

https://esdac.jrc.ec.europa.eu/content/3d-soil-hydraulic-database-europe-1-km-and-250-m-resolution

 2
Mapping small/linear extent Harmonise coarse-resolution terrestrial maps and fine-scale maps of small freshwater bodies We are not aware of any good examples. 2 & 3
2 Find solutions across ecological and administrative scales for ES assessments
Administrative borders limiting watershed approach Co-operations: integration of ES assessments across administrative units (aligned to basin boundaries) F→ES

More funding for transboundary assessments; some pilot projects available, e.g. Interreg IDES, which aims at improving water quality in the Danube river and its tributaries by integrative floodplain management based on Ecosystem Services, by joining 10 countries along the Danube.

http://www.interreg-danube.eu/approved-projects/ides

 4
Upstream–downstream and lateral flooding issues mirrored in social & management problems Upstream—downstream governance as example for good management practices F→ES A good example is provided by the ‘Upstream Thinking’ initiative of the regional water company in Cornwall (UK): they work with farmers to improve the quantity and quality of water through land use change as an alternative to engineering and chemical treatment options, emphasizing their responsibility regarding spatially remote effects of their actions (Schaafsma et al. 2015). 4
Diversity of dataset scales & resolution Integrate data across institutions and countries F↔ES

A first step is the common collection of data, e.g. WISE WFD data. However, integration needs to be solved as a next step.

www.eea.europa.eu/data-and-maps/data/wise-wfd-4

 2 & 4
Remote effects scantily quantified Understand the distance functions of spill-over/zonal effects of water bodies and wetland areas F↔ES Some knowledge on applications of groundwater recharge and its remote effects, e.g. by successfully creating numerous water holes in India in order to revitalize surrounding land (Everard 2015) but very few sufficiently exact and generalizable quantifications. 3
3 Integrated valuation of freshwater ecosystem services
Monetization perceived as dangerous Integrate and emphasize non-monetary values in assessments ES→F Ranking preferences e.g. for differing management options under consideration for wetland restoration planning in Rhode Island, USA makes non-monetary values integrateable into the decision-making process (e.g. Martin & Mazzotta, 2018). 2 & 4
Values dependent on socio-ecological system setting Streamline scenario analyses for different socio-ecological settings ES→F Estimation of service flow in biophysical units per area and year in Nordic catchments and then estimation of a monetary value for each service in each scenario (Vermaat et al. 2020). They posit that the estimation of total economic value would work as a tangible indicator for comparative use in scenario evaluations and in communication with policy makers. 2 & 4
ES indicators & assessments diverse and difficult to standardize Provide unified and comparable indicators and valuation systems with intercalibration techniques F↔ES Good example is the River Ecosystem Services Index (RESI) developed for German rivers and calibrated at several sites, incorporating also WFD-used features (Podschun et al. 2018). 2 & 3
Multiple aspects to reconcile (social, conservation, etc.) Promote decision-support and other frameworks for landscape-level decisions (based on multifunctionality and conservation focus) F↔ES Multifaceted problem-solving and decision making is developed by Colloff et al. (2019), including new ways to connect with the societal decision system. Applying scenario analysis, the results can be used to visualize trade-offs that affect livelihoods, human wellbeing, water resources & the environment. 2 & 3
4 Enhancing databases and methods
Multitude of different databases in data-developed regions Develop methods to integrate different databases across disciplines and across countries, with intelligent databases ES→F We are not aware of any good examples. 2
Lack of data in data-poor regions – less complex assessments possible Assess freshwater ES on large scale in data poor regions, develop ‘quick & dirty‘methods, test downscaling ES→F

Enhance funding for basic/monitoring data collection, especially in South-east Europe.

While there are some rough estimating methods available for terrestrial ES (e.g. crop provisioning), for water related they are much more complex (see Vallecillo et al. 2019 for both).

 1 & 2
Accuracy and uncertainty of assessments often not visible or not assessed Visualize uncertainty levels (e.g. flag data/results), compare with higher tier models, test upscaling F↔ES A useful approach towards assessing uncertainty is presented in the EU Ecosystem assessment (Maes et al. 2020). With the use of basic uncertainty categories derived from the used methodology and quality of datasources gives a first approach of how to categorize uncertainty when otherwise not quantifiable (i.e. no model calculations possible). 2
5 Incorporate ESs into management and increase EU policy coherence on water-related ESs
EU policy lacks coherence on water-related ES Develop & promote guidance on integration between ES assessments, policy, and specific measure F↔ES Several overview studies compare different policies, e.g. Bouwma et al. (2018) analysing 12 policies, which show some coherence, but further integration based on ES is needed. 2 & 4
Need to recognize rivers and lakes as blue infrastructure Recognize rivers and lakes as blue infrastructure, link freshwater ES to up-to-date policy directions F↔ES

Within the project ‘ENABLE’ a framework was developed and applied in six pilot cities, that evaluates functionally connected green and blue features (Andersson et al. 2019) with three key factors including : 1) the interactions among green, blue, and built infrastructures, 2) institutions 3) peoples perceptions and values. The framework can be used to support more effective urban planning, decision-making and implementation of green & blue infrastructure. The full extent of its potential is not yet established in research & policy, further efforts are needed.

https://www.iucn.org/regions/europe/our-work/nature-based-solutions/enable-improving-green-and-blue-infrastructure-cities

 4
6 Improve communication, education and knowledge transfer
Gap in knowledge transfer towards policy makers, conservation practitioners and from high GDP to lower GDP countries Improve communication efficiency towards decision makers and practitioners; involve knowledge brokers ES→F With constant negotiation between researchers and knowledge users (policy actors), knowledge brokering could provide Finnish civil servants with pre-digested and fit-for-purpose information about the ES indicators and thus help urban green space planning (Saarela & Rinne 2016). 4
Positive psychological effects Use emotional attachment to enhance communication F↔ES “Big Jump for Europe’s Rivers” calls for greater protection for continent’s rivers and lakes—people participate in simultaneous events in 18 European countries every year as part of the Big Jump—jumping, diving, wading, kayaking and swimming in streams and ponds, rivers and lakes. WWF & locals jointly organised > 160 events. 4
Dynamic/periodic changes in freshwater ecosystems are difficult to manage with static approaches Integrate lessons from traditional ecological knowledge on the coexistence of people and dynamic aquatic habitats F↔ES We are not aware of any good examples. 4
Open in a new tab

Knowledge transfer: we indicated where freshwater research can advance ES research (F→ES), where ES research can assist FES research (ES→F) and where knowledge development in both is needed (F↔ES). KG: Knowledge gap types: 1—data gap (raw data not available, e.g. status of some water bodies); 2—methodology gap (methodology is not (readily) available, e.g. to combine datasets from different sources or scales); 3—conceptual or relationship knowledge gap (knowledge is not available); 4—transfer gap (knowledge available, but not to all relevant participants; e.g. geographic inequality, or between research and implementation/management)

We also evaluated the specific findings from the point of view of knowledge transfer: wherever knowledge or methods of assessment/management are more developed, better accepted or work in some way better regarding freshwater ecosystems than ES research in general, we mark this, as well as the other way round: issues/practices that work better in more general ES approaches and are less successfully implemented in FES studies.

In the following sections, we present the emerging issues and complement them with suggestions on how to address these complex questions.

Results

We developed a conceptual framework (see also Fig. 1): at the core of most issues identified are several features which are unique to freshwater ecosystems and have a firm (bio)physical basis. These are embedded in a landscape that is divided into ecological and administrative units. Both,’unchangeable’ biophysical features as well as relatively fixed ecological entities need to be reconciled with man-made administrative units. Integration between the different relevant sectors—as well as between different valuation approaches resulting in an integrated valuation of ES—might be one way forward. Integrated valuation of ES itself holds a number of challenges regarding datasets and methods like accessibility, geographical coverage and availability for example. These challenges are shaped by properties of the socio-ecological system (research infrastructure, funding, etc.), which in turn can be influenced by policy. Both of these are human-made and can be changed relatively easily, at least compared to biophysical attributes. The exchange of knowledge (between science and other stakeholders, like policy actors and managers) and the enhancement of knowledge exchange—factors that rely on all of us—is the key to ensure the preservation the functioning of freshwater ecosystems.

Fig. 1.

Fig. 1

Open in a new tab

The unique features of freshwater ecosystems (1) are at the very core of all of the discussed issues. These are nested within ecological and administrative borders (2, blue-watershed, red-administrative border), that makes integrated valuation of the ES necessary (3), to which issues regarding datasets and methods are related (4). Accessibility, coverage and availability of both, data and methods, are shaped by the features of the socio-ecological system (violet) defined by management and policy (5) as well as knowledge exchange among stakeholders (including policy actors and management) (6). For details regarding the six specific issues, see Table 1

The unique features of freshwater ecosystems and their role in the supply of ES

One of the most prominent features of freshwaters is their unique spatial structure that distinguishes them from terrestrial habitats, influencing the spatial and temporal distribution of ES and their interactions. Waterbodies are embedded within the terrestrial landscape constituting’transitional systems in space and time’ (Hettiarachchi et al. 2015). As the watershed area is much greater than the surface area of either rivers or lakes, interactions between land and water are more pronounced when we include the strong impact of land on water (e.g. through fertilizer input) emphasizing the critical role of connectivity and interfaces for the overall functioning of freshwater systems. The strong directionality of the flow of material and energy distinguishes lotic freshwaters from terrestrial systems, while fluctuations in water level are crucial for wetlands and lakes. Both constitute changes in extent and shoreline and have the potential to affect biota as well as stakeholders. In riverine habitats, interactions resulting from the distinct directionality and unique connectedness of rivers across broad spatial scales strongly influence local-scale habitat features and organization of the biota (Thorp et al. 2013; Erős and Grant 2015), with inevitable effects on ecosystem functions and services.

Due to their linear structure, rivers are especially susceptible to fragmentation effects, like those resulting from building hydroelectric power plants (transversal) or by building levees along river banks (longitudinal). In fact, these connectivity relationships may be the most fundamental difference between riverscapes and terrestrial landscapes because the linear structure of rivers allows for disproportionately large effects of barriers. Studies proved that hydropower dams can cause enormous degradation of biodiversity and ecosystem services by impeding connectivity in freshwater networks (Wu et al. 2003; Poff et al. 2007; Borgwardt et al. 2019). In terrestrial habitats, one single obstacle could rarely cause such disproportionate harm, as circumventing barriers is more feasible (Erős and Lowe 2019). Thus, whereas terrestrial ecosystems are often valued as more or less closed entities, with local-scale supply of ES, this is not possible for water-related ecosystems and services, as inputs from other ecosystems and catchment-level effects have to be taken into account (Bennett et al. 2009; Thorp et al. 2010; Qiu and Turner 2013; Hanna et al. 2018). Resulting from the high connectedness of aquatic ecosystems, a quantification of interactions between their ES is challenging (c.f. “Integrated valuation of freshwater ecosystem services” section) but all the more important due to the potential impact of management measures on both terrestrial and freshwater systems (c.f. “Incorporating ES into management and to increase EU policy coherence on water related ES” section).

Waters are not only connected on the surface, but also in an invisible way, to groundwater. Surface water bodies can be connected along aquifers, whereas within the whole watershed, sub-surface and surface run-off connects both terrestrial influences to waterbodies and groundwater. Therefore, ES of surface waters should be managed with regard to hydrologic processes connecting both (Qiu and Turner 2013). Although mainly driven by abiotic factors, groundwater ecosystems can provide numerous ES, which is rarely taken into consideration (Griebler and Avramov 2015; Pinke et al. 2020). Groundwater levels have been declining due to direct water abstraction (pumping) for drinking water and irrigation (Gozlan et al. 2019) for example, but also due to reduced opportunities for recharge. Recharge can occur in wetlands of floodplains, but river regulations in the past centuries resulted in a reduction of potential recharge areas (Bullock and Acreman 2003; Aldous et al. 2011).

Temporal aspects also need to be considered, as due to water level fluctuations the borders of freshwater systems are dynamically changing. The periodic change in size/volume is thus another unique feature of most freshwater ecosystems: regular flood events, potentially occurring both in rivers and lakes, provide an even stronger linkage between terrestrial and aquatic habitats, enhancing lateral connectivity—the connections between the main river/water body and its surrounding floodplains and oxbows. However, droughts and drying also change the boundaries and have massive impacts on ecosystem functioning and ES (Moomaw et al. 2018; Keller et al. 2020). Riparian zones constitute transitional areas between land and freshwater that are of special value for biodiversity and ecosystem functioning (e.g. Flood Pulse Concept, Junk et al. 1989; Wantzen et al. 2016; Tomscha et al. 2017). However, management of an ecosystem that regularly changes its extent poses special challenges, especially if the pulsing is to be reconciled with human needs. Haines-Young and Potschin (2010) classified ES based on their spatial characteristics, and listed several basic water related ES ‘water regulation/flood protection’, ‘water supply’, ‘sediment regulation/erosion control’, ‘nutrient regulation’ as ‘directional flow related’, in contrast to local scale or global, but non-directional ES. Nevertheless, the majority of later ES mapping and assessment works neglected the more complex spatial aspects and concentrated on the easy-to-map local or ‘proximal’ ES. Concepts of ‘service providing units’ and ‘service benefitting areas‘have been developed, but are still challenging to implement (Syrbe and Walz 2012). Therefore, frameworks attempting to adapt general ES approaches to waters, and rivers need to take directional flow into account, e.g. by integrating hydrologic models into their frameworks (e.g. Keeler et al. 2012; Hallouin et al. 2018).

Mapping habitats, land cover/land use, or ecosystems constitutes an essential task for ES assessments. The narrow, linear shape of streams and the small size of many lentic waters is a challenge for proper representation in the maps: if the grid used is too coarse, the extent of the ecosystem might be strongly underrepresented or completely missing from the maps (e.g. Tomscha et al. 2017). Also, the correct mapping/representation of the terrain elevation is crucial in order to be able to model water flow directions properly.

Finding solutions across ecological and administrative scales for ES assessments

Spatial scaling is an issue that has been around for decades with some more recent advances based on fine-resolution remotely sensed data (Tomscha et al. 2017). Deciding about the right scale—or multiple scales—for an ES assessment is of great importance, as different scales can yield different results (Friberg et al. 2017; Hanna et al. 2018). Most water-focused studies use a watershed approach, and this is also suggested as the appropriate scale for management by the EEA (Hanna et al. 2018; European Environment Agency 2019), as well as for Water Framework Directive assessments (EC 2003). Nevertheless, there are still a great number of studies complying with jurisdictional boundaries, as this is the scale for administrative actions, including national funding and regulations (Mihók et al. 2017). This approach however, cannot give optimal results from an ecological point of view (Kaval 2019). International and/or cross-border co-operation could help in tackling this problem.

Directional flow also entails a line of social and management issues, where the effects of upstream decisions are being carried on by people and ecosystems further downstream, potentially to different administrative units (Thorp et al. 2006; Brauman et al. 2007; Hanna et al. 2018). Sensibilization towards this fact has been successfully applied in the UK for example (‘upstream thinking’—Schaafsma et al. 2015).

Questions regarding how integration between different scales should be implemented can also arise at the data level, when working with a diversity of datasets. Datasets from different sources, with different spatial scales, resolution and units need to be transformed and integrated into one comprehensive dataset for large scale studies. As databases—even within countries (e.g. Engloner et al. 2019)—are developed by different agencies or institutions, their integration poses difficulties and is often missing (for example regarding hydrological and meteorological data).

The spill-over (zonal/remote) effects of water bodies—effects of water that are detectable across a wider area within their surroundings—are not sufficiently known, e.g. at what distance water bodies can have an effect on microclimate via evaporation, potentially providing climate regulation even at regional scale, or how retaining water in floodplains effects groundwater levels in the surrounding areas in the long run (Bullock and Acreman 2003; Pinke et al. 2020). Changes in local and regional air temperature could be detected and analysed by remote sensing, backed with data provided by local in situ sensors for calibration.

Integrated valuation of freshwater ecosystem services

Assessment of ES is often seen as synonymous with monetary valuation since at least Costanza’s work on the world’s ecosystem services in (1997). Putting monetary values on ‘nature’ is a critical issue that crystallized during the workshop, as monetization is perceived as dangerous, which was the most controversial experience that participants reflected on. This shows that the misconception that monetary valuation is the only way to make ES comparable is still persistent outside the ES community and the fact that the ES concept embraces a much wider range of values should be communicated widely (Schröter et al. 2014).

Focusing on non-monetary values, like the perceived importance of different FES, taking a deliberative approach with inclusion of traditional ecological knowledge, preferences of local stakeholders as well as presenting bio-physical values wherever possible can be a good solution towards a well-balanced assessment, e.g. as multi-criteria decision analysis, elicitation of socio-cultural preferences or by analysing social networks (Martín-López et al. 2012; Gómez-Baggethun et al. 2016; Martin and Mazzotta 2018). The value of ES, no matter if monetary or non-monetary, depends on various factors. Monetary value depends especially strongly on the demand and the examined economic situation, e.g. the availability of the specific asset (Bateman et al. 2011; Reynaud and Lanzanova 2017). Demand for a service however, might change quickly, if the societal setting or the supply changes. The perceived value of ES has been shown to depend on the viewpoint of the stakeholders (Martín-López et al. 2012; Paudyal et al. 2018; Hossu et al. 2019). Changes in both the social and the ecological system—including land use-changes—can therefore lead to very different valuation results, both in monetary and non-monetary terms (e.g. Shackleton et al. 2018). Scenario analyses might shed light on anticipated changes in ES value as well as adopting values from other regions to a hypothetical situation, similar to the benefit transfer technique widely used for economic valuation of ES (e.g. Reynaud and Lanzanova 2017; Decsi et al. 2020; Vermaat et al. 2020).

Assessing single ecosystem services is one step. However, the strength of the ecosystem services concept lies in assessing multiple ES at once for underpinning holistic management measures. For aggregating multiple ES, a common denominator is needed, which can either be achieved by monetization (Reynaud and Lanzanova 2017), but also by other quantitative methods, e.g. hotspot analysis (Qui and Turner 2013; Schulp et al. 2014; Tomscha et al. 2017). Relative scales—e.g. an ordinal scale with scores from 1 to 5, as often used in ES matrix applications—seem to offer an easy solution, but should be handled with care and not be mistaken for interval or ratio values, that can actually be added up (Czúcz et al. 2018). In order to give relative scales a meaningful interpretation, they need to be standardized and connected to biophysical values.

The Water Framework Directive (WFD; Poikane et al. 2014) is a valuable tool for evaluating the ecological quality/potential of freshwater systems on a relative scale, where biological and chemical indicators are combined in an intercalibration process and used to evaluate water body quality and give guidance on the necessary management needs. The WFD monitoring could be complemented by an ES valuation system in the future as there are already several direct and indirect links (Kistenkas and Bouwma 2018). An adaptation to terrestrial ecosystems based on a similar, systematic intercalibration process to assess the ecological quality could open up new directions in the development of a terrestrial ES valuation system. The approach developed in the RESI (River Ecosystem Service Index, Podschun et al. 2018) project allows the integration of the WFD relative scores and combines them with additional datasets (such as land use, digital elevation model, soil maps etc.) towards an ES assessment including up to 15 ES relevant in rivers and floodplains. Thereby, all ES values are based on individual indicators and models that are finally valued on a relative scale from very low (1) to very high (5) service provision (Podschun et al. 2018). This enables an evaluation of freshwater management scenarios based on the change in overall functionality of the ecosystem, as e.g. shown for a 75 km stretch of the Danube in Stammel et al. (2020). As the use of relative scales is already established in the WFD, stakeholders’ acceptance towards relative ES scales might be higher than for monetary approaches.

While there are several frameworks according to which landscape-level decisions could be made (optimization, e.g. according to pareto-optimal combinations of ES—Vallet et al. 2018), within the ES-related topics, it is often multifunctionality that is promoted as the best solution (Sanon et al. 2012; Funk et al. 2020). Sensitive and protected areas might however not always be outstanding in terms of multifunctionality. Along these lines, there is an on-going debate in nature conservation: whether land should be used as multifunctional as possible (‘land-sharing’) (e.g. assessed for floodplains: Funk et al. 2020), or whether there should be designated areas, for one specific or a set of prioritized functions (e.g. for conservation, ‘land sparing‘). These approaches could be combined using spatial optimization, in which win–win solutions are sought by accounting for ES delivery in each scenario (Erős et al. 2018).

Enhancing databases and methods

With remote sensing and processing and big (EU-wide) monitoring schemes, the availability and also the diversity of datasets has increased, but so has the effort to overview them and find the best/available datasets. This enables EU-wide ES assessments on the one hand (Grizzetti et al. 2019) but also offers an opportunity for downscaling (Aldous et al. 2011) that might be especially valuable in data-scarce regions (e.g. towards SE Europe). The development of intelligent databases that compile themselves based on a pre-defined search algorithm within an (internet-based) application could be an innovative solution (e.g. Ames et al. 2012). The use of social media and citizen-science based data is an emerging field in environmental research that has mainly been used to assess cultural ES but also to monitor aquatic ecosystems (Ghermandi and Sinclair 2019). Despite the increasing availability of data and coordinated attempts to gather more (e.g. as part of the WFD implementation), there are still large information gaps on the status of freshwater ecosystems: according to the EEA (2019), the status of 40% of these ecosystems is still unknown, while outside of the EU, data is mainly focused on protected areas, leaving other areas’ status in the dark.

The usual way of developing ES assessments is based on gathering existing knowledge via consulting experts (IPBES 2018b). However, there are still several areas, especially within freshwater environments, where appropriate evidence is missing or assessed only with limited confidence. Here, often small-scale modelling tools exist, which are not feasible at larger scales (see scaling issues above). Building and testing some ‘quick-and-dirty’ methods to give a rough estimate on ES within a reasonable time frame are needed. Here, the ES matrix approach (Burkhard et al. 2009; Jacobs et al. 2015) that combines ecosystem types with ES via look-up tables has proven to be a valuable tool that still needs to be adapted to local conditions. An assessment of uncertainty is highly recommended, albeit rarely performed (Burkhard et al. 2009; Campagne et al. 2020; Maes et al. 2020). As many aspects within freshwaters are more interconnected (see above), it is probably more difficult to develop easy-to-implement ES assessment methods than it is for terrestrial ecosystems, while for some ES it is simply not possible. For example, nutrient retention still poses a great challenge as very detailed information on relevant processes is required for a thorough quantification (Grizzetti et al. 2019).

Modelling approaches for ES encompass a wide variety of methods and tools (Schulp et al. 2014; Hanna et al. 2018): from the very simple matrix models to somewhat more refined, but still land-use based models, including spatial rules (Kienast et al. 2009; Czúcz et al. 2018; Arany et al. 2019) and up to higher tier models, which are often process-based, empirical or statistical models (Schulp et al. 2014). For assessing ES, highly developed, data-intense modelling tools are mainly available for specific fields and at local to regional scales, e.g. hydrological models (e.g. SWAT, Hydrus1-D). If large scale ES assessments are to be completed or multiple ES are to be assessed at the same time (e.g. national MAES), simpler models are more often the only feasible ones, due to limited resources. With matrix-based modelling it is hardly possible to include any directional influences, which limits applicability when modelling ES related to the flow of water. Comparing simple models with higher tier models offers the opportunity to assess uncertainty. Upscaling higher tier models from the local/regional/watershed scale to larger areas is not evident, but potentially feasible and needs testing (Grêt-Regamey et al. 2015; Hanna et al. 2018).

Incorporating ES into management and to increase EU policy coherence on water related ES

While institutions and governance are recognized to be of key importance for ES co-production (Pascual et al. 2017; Mastrángelo et al. 2019), regarding planning, design and management, there are still several points that hinder implementation. Already before the rise of the ES concept, the IWRM (Integrated Water Resources Management) approach emphasized the importance to connect environmental issues and human well-being, and partly already implemented stakeholder integration, while also aiming at multidisciplinarity (Blackstock et al. 2015; Maynard et al. 2015; Grizzetti et al. 2016a). Still, added value is seen in including an ES approach in river basin management plans by its potential for trade-off analysis, better linkages towards and recognition of human well-being aspects (Maynard et al. 2015; Grizzetti et al. 2016b; Crossman et al. 2019) or in its combination with cost-effectiveness analyses (Boerema et al. 2018).

A general lack of ES-based integration between the different EU-level policies and management measures can be observed regarding the numerous policies related to water, e.g. the Nitrate Directive, the Flood Directive, the Habitat Directive, the Biodiversity Strategy, the Drinking Water and the Bathing Water Directives as well as others on adaptation to climate change (Council Directives 91/676/EEC, Directive 2007/60/EC, 92/43/EEC, 98/83/EC, 2006/7/EC, EC, 2011, 2013), social cohesion (EU Regulation No 1300/2013) and energy efficiency (Council Directive 2012/27/EU). Often different policies either contradict each other, or are disregarded by one another (Naumann et al. 2011).

Putting for example measures of the WFD and flood directives in direct relation to their potential effect on ES delivery can help to compare consequences of different measures in a systematic way (Schindler et al. 2016; Hornung et al. 2019). Due to the interactions between ES, trade-offs arise with the implementation of different management measures, typically between (agricultural) provisioning and cultural ES (Hornung et al. 2019).

Freshwaters can also be seen as ‘blue infrastructure’ (EC 2013a, b). The importance of green and blue infrastructure is also acknowledged in the EU Biodiversity Strategy for 2030 (2020/380/EC). An integrated consideration of blue-green infrastructure networks in landscape planning and governance can also help to address societal challenges using nature-based solutions (Albert et al. 2019).

Improve communication, education and knowledge transfer

Forwarding and communicating cutting-edge findings in science towards society, practice/implementation and policy is vital in order to channel the interest of stakeholders and funding to these areas. For this latter, however, a clear communication between science and decision-makers is needed. This seems to be less efficient in eastern Europe as experienced by the workshop participants—a pattern observed generally in knowledge transfer and accessibility between high- vs low-GDP countries (Karlsson et al. 2007; Jeffery 2014; Blicharska et al. 2017). There is a gap between available knowledge in theory, that is accessible in academic studies and knowledge actually implemented and integrated in management (Langhans et al. 2014; Xu et al. 2018; Lindenmayer 2020). Thus, communication and education targeting nature conservation needs to be enhanced. Better knowledge transfer was also seen by workshop participants as a key to implement and make use of the advantages offered by the ecosystem services concept. In cases where practitioners did have experience with the ecosystem services approach, they perceived it as a very useful tool for involving stakeholders’ perspectives and highly suitable for solving conflicts (own experience; Maynard et al. 2015; Grizzetti et al. 2016b).

For more effective communication, ‘knowledge brokers’ (Saarela and Rinne 2016) who work exclusively on the transfer of knowledge from science to practice could be involved. In this regard freshwater science can learn from ES research and even more from social sciences by adopting truly interdisciplinary methods in order to enhance system-, target- and transformation knowledge for integrated planning (Albert et al. 2019).

Rivers and their floodplains are outstanding in the provision of cultural ES (Thiele et al. 2020) as people are highly connected to water historically, culturally and also emotionally (Corral-Verdugo et al. 2015). This attachment represents a good starting point for communication, education and knowledge transfer regarding conservation issues, while the ES concept helps to communicate these issues with a multitude of stakeholders and to balance between different uses/needs.

Knowledge transfer is also needed from traditional knowledge holders towards science and policy (Molnár and Berkes 2018). The effective integration of traditional knowledge (or indigeneous and local knowledge) is a key priority of the IPBES assessments (Díaz et al. 2015; Mastrángelo et al. 2019). Former cultures settling in floodplains dynamically adapted to flood pulses in contrast to todays’ static structures—this knowledge/practices should be taken more into consideration in formulating alternative water management solutions (see also Wantzen et al. 2016). Historically, one option for floodplain management was the use of oxbow lakes in Hungary—fluvial lakes that were periodically connected to the river during high water levels and used for raising fish stocks, while their flooding decreased flood levels at the same time (Biró 2009; Molnár and Berkes 2018). Nowadays, possibilities of re-vitalizing this management system are discussed intensely (Werners et al. 2009; Derts and Koncsos 2012; Guida et al. 2015).

Conclusions

In this paper, we highlighted that freshwaters comprise numerous unique features (e.g. high lateral and longitudinal connectivity, directional flow, vertical connections to the subsurface), which make their assessment and management more challenging. These aspects also hold true when including them in an ES assessment framework. Many features presented in the previous sections not only pose problems to be solved, but can also present an opportunity with which we might be able to better address more general questions in ES research, and thereby add to the development of the ES framework. As such, we discussed strong spatial interlinkages that are often incorporated in (water-related) modelling tools, but disregarded in terrestrial assessments; the watershed approach, which takes hydrological borders and not administrative borders as the basis of an assessment; and upstream–downstream issues that show the discrepancy between service providing units and service benefitting areas in a pronounced way in river environments that need to be accounted for in terrestrial environments, too—for these, a number of good practice examples are available from riversides (Schaafsma et al. 2015). Due to their special features, it is more evident to adopt a holistic, integrated approach in many freshwater cases. With this, the multifunctionality within an ecological entity or the interlinking changes related to different sectoral policies can also be analysed better (Schindler et al. 2014; Hornung et al. 2019). Addressing issues like connectivity would be a significant improvement for ES assessments in terrestrial systems that might well fit the concepts of green infrastructure. Harmonizing EU policy related to water and integrating ES assessments into relevant policy pieces could assist in developing target specific measures, in governance as well as in research, like for the incoming EU Horizon Europe research and innovation framework. Focusing on the strengths of freshwater research can help to improve the ecosystem services framework towards a more holistic, landscape-level approach, which we believe can boost realization of conservation attempts and achieving EU and global sustainability goals. As the overview of possible solutions showed, the first steps are already on the way giving rise to more intense cooperations across disciplines and countries.

Acknowledgement

This paper is mainly based on a workshop with the title ‘Aquatic Ecosystem Services—assessment, management and socio-economic challenges’ (http://aquatices.ecolres.hu/), co-organised by the Centre for Ecological Research (CER), the Hungarian Water Science Program of the Hungarian Academy of Sciences, and the Kompetenzzentrum Wasser Bodensee e.V. (KWBo), Germany. Financial support was provided by the Project Danube Water Net, co-financed by the Baden Württemberg Stiftung (Germany), IPBES 2.0 (National Research, Development and Innovation Fund), the National Water Science Program (Hungarian Academy of Sciences) and the Ecology for Society project (MTA KEP).

Biographies

Ágnes Vári

(Ph.D.) is a research fellow at the Centre for Ecological Research, Hungary and has been working on ecosystem services (ES) assessments for the past 6 years at, taking part in several international projects as well as in the national Mapping and Assessment of ES in Hungary. Within the latter, she has been leading the working group on hydrological ES. Before, she worked as an aquatic ecologist at the Balaton Limnological Institute (Tihany, Hungary), where she investigated macrophytes and shallow lake ecological processes.

Simone A. Podschun

(Ph.D.) is a Researcher and Project Coordinator at the Leibniz-Institute of Freshwater Ecology and Inland Fisheries (IGB) and is involved in the collaborative projects RESI - River Ecosystem Service Index and AQUATAG (recreational activities in/on/arround freshwater ecosystems). Her main research interests are social-ecological systems, spatial assessment methods and applied research aimed at enhancing the management of ecosystems with special focus on ecosystem services of rivers, floodplains and urban ecosystems.

Tibor Erős

(D.Sc.) is a Director of the Balaton Limnological Research Institute, Hungary. His research generally focuses on the organization of aquatic communities, environmental monitoring and assessment and conservation of freshwaters. In his recent research he is mainly interested in finding optimal solutions to land sharing and sparing spatial designs for the maintenance of biodiversity and delivery of ecosystem services.

Thomas Hein

is Full Professor at the Institute of Hydrobiology and Aquatic Ecosystem Management since 2017 and was managing director of WasserCluster Lunz from 2008 to 2020. The research interests of Prof. Thomas Hein are aquatic ecosystem – human interactions in riverine landscapes, with a focus on water – sediment interactions, aquatic – terrestrial linkages, ecosystem restoration and the coupling between society and ecosystems in riverine landscapes, viewing them as socio-ecological systems. In recent years changes in ecosystem services, their link to bio-physical properties as well as to management measures and trade-offs between different categories have been analysed.

Beáta Pataki

(Ph.D.) is Professor at the University of Debrecen, Department of Civil engineering, teaching hydrology and environmental studies. Before, she worked on the topics of water quality regulation and Integrated Water Resources Management. She took part in the project WetWin and investigated there ES of the Danube floodplain. Recently, she has been involved in the Hungarian national mapping and assessing of ES.

Ioan-Cristian Iojă

(Ph.D.) is professor in Environmental Sciences at the University of Bucharest and researcher at the Centre for Environmental Research and Impact Studies. His experience with freshwaters ecosystems focuses on the analysis of human-nature connections in natural and transformed ecosystems, including urban areas. One of his major research topics is on green-blue infrastructure, and includes studies about land use and land cover changes, environmental conflict analysis and assessment of ecosystem services.

Cristian Mihai Adamescu

(Ph.D.) is Professor and Head of the Research Center in Systems Ecology and Sustainability, University of Bucharest and Coordinator of Braila Research Facility, also promoting different research infrastructures in Romania from the Long-Term Socio Ecological Research Network to Lifewatch and ICOS. His professional interests are mainly focused on the ecology of large rivers, development of sensor networks and high frequency monitoring for complex systems, studying the dynamics and productivity of freshwater ecosystems, eutrophication and its impact but also the functional role of wetlands and the related ecosystem services.

Almut Gerhardt

(Ph.D.) is founder and CEO of LimCo International GmbH, an SME focussing on scientific research, development of innovative technology and consulting in the field of freshwater ecology and ecotoxicology. LimCo performs water quality assessments of streams according to the European Water Framework Directive and monitors both emissions of point pollution sources and immissions into streams with a Multispecies Freshwater Biomonitor. LimCo forwards the implementation of both ES-concept and ecotoxicological assessment to be integrated as valuable components into the WFD.

Tamás Gruber

is the Programme Manager of WWF Hungary’s Freshwater Programme focusing on restoration and policy work for improving the ecological and hydromorphological status of Hungarian rivers. He has been using the ecosystem services framework for eliciting stakeholder views at the river Drava and in several other projects, (e.g. oxbow restoration) where next to implementing hydrological restoration the benefits of river and wetland restoration works for society have been assessed.

Anita Dedić

(Ph.D.) is an Assistant Professor at the University of Mostar, Faculty of Science and Education, and focuses on research, teaching and consulting in the field of freshwater ecology, specifically freshwater algology with emphasis on diatoms and karstic waters. She performs water quality and biomonitoring assessments according to the European Water Framework Directive, while she strives to promote the importance of ES-concepts within her expertise.

Miloš Ćirić

(Ph.D.) is a research associate at the University of Belgrade, Institute of Chemistry, Technology and Metallurgy. His fields of interest include algology (phytoplankton ecology), as well as algal response to nutrient enrichment using diatom indices and phytoplankton functional groups. He participated in several national and international projects related to the research and conservation of freshwater ecosystems. He was coordinator of the Sino-Serbian research project related to the restoration of hypertrophic freshwater shallow lakes.

Bojan Gavrilović

(Ph.D.) works as a research associate at the Geographical Institute “Jovan Cvijić”, Serbian Academy of Sciences and Arts, Department of Physical Geography. As part of the research group for Biodiversity, Macroecology and Biogeography his research focuses on various aspects of freshwater ecology. He has been involved in biomonitoring and water quality assessment of different lentic and lotic water ecosystems in Serbia. His field of interest includes taxonomy, systematics and biodiversity of invertebrate taxa and how anthropogenic factors affect it.

András Báldi

(D.Sc.) is scientific advisor and leader of the Lendület Ecosystem Services Group at the Centre for Ecological Research, Hungary. His main research interest is to understand and maintain patterns and processes of biological diversity, with special emphasis on ecosystem services in terrestrial and aquatic systems. He also co-chaired the Hungarian Water Science Program of the Hungarian Academy of Sciences. Beyond research, he contributes to the application of evidence in practice and policy and the development of the science-policy interface (IPBES).

Author contributions

ÁV: Conceptualization, Investigation, Writing—Original Draft, Visualization. SAP: Conceptualization, Investigation, Writing—Original Draft, Visualization. TE: Conceptualization, Investigation, Writing—Original Draft. TH: Investigation, Writing—Review & Editing. BP, I-CI, CMA, TG, AD, MĆ, BG: Investigation, Writing—Review & Editing. AG: Investigation, Writing—Review & Editing, Funding acquisition. AB: Conceptualization, Investigation, Writing—Original Draft, Funding acquisition

Funding

Open access funding provided by ELKH Centre for Ecological Research.

Footnotes

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Contributor Information

Ágnes Vári, Email: vari.agnes@ecolres.hu.

Simone A. Podschun, Email: podschun@igb-berlin.de

Tibor Erős, Email: eros.tibor@blki.hu.

Thomas Hein, Email: thomas.hein@boku.ac.at.

Beáta Pataki, Email: pataki.bea@eng.unideb.hu.

Ioan-Cristian Iojă, Email: cristian.ioja@geo.unibuc.ro.

Cristian Mihai Adamescu, Email: adacri@gmail.com.

Almut Gerhardt, Email: AlmutG@web.de.

Tamás Gruber, Email: tamas.gruber@wwf.hu.

Anita Dedić, Email: dedic.anita@gmail.com.

Miloš Ćirić, Email: ciricmilosh@yahoo.com.

Bojan Gavrilović, Email: bojangav@yahoo.com.

András Báldi, Email: baldi.andras@ecolres.hu.

References

  1. Albert C, Schröter B, Haase D, Brillinger M, Henze J, Herrmann S, Gottwald S, Guerrero P, et al. Addressing societal challenges through nature-based solutions: How can landscape planning and governance research contribute? Landscape and Urban Planning. 2019;182:12–21. doi: 10.1016/j.landurbplan.2018.10.003. [DOI] [Google Scholar]
  2. Aldous A, Fitzsimons J, Richter B, Bach L. Droughts, floods and freshwater ecosystems: Evaluating climate change impacts and developing adaptation strategies. Marine & Freshwater Research. 2011;62:223. doi: 10.1071/MF09285. [DOI] [Google Scholar]
  3. Ames DP, Horsburgh JS, Cao Y, Kadlec J, Whiteaker T, Valentine D. HydroDesktop: Web services-based software for hydrologic data discovery, download, visualization, and analysis. Environmental Modelling & Software. 2012;37:146–156. doi: 10.1016/j.envsoft.2012.03.013. [DOI] [Google Scholar]
  4. Andersson E, Langemeyer J, Borgström S, McPhearson T, Haase D, Kronenberg J, Barton DN, Davis M, et al. Enabling green and blue infrastructure to improve contributions to human well-being and equity in urban systems. BioScience. 2019;69:566–574. doi: 10.1093/biosci/biz058. [DOI] [PMC free article] [PubMed] [Google Scholar]
  5. Anzaldua G, Gerner NV, Lago M, Abhold K, Hinzmann M, Beyer S, Winking C, Riegels N, et al. Getting into the water with the Ecosystem Services Approach: The DESSIN ESS evaluation framework. Ecosystem Services. 2018;30:318–326. doi: 10.1016/j.ecoser.2017.12.004. [DOI] [Google Scholar]
  6. Arany I, Vári Á, Kalóczkai Á, Aszalós R, Blik P, Kelemen K, Kelemen M, Bóné G, et al. Diversity of flower rich habitats can provide persistent source of healthy diet for honey bees. European Journal of Geography. 2019;10:89–106. [Google Scholar]
  7. Bateman IJ, Mace GM, Fezzi C, Atkinson G, Turner K. Economic analysis for ecosystem service assessments. Environmental & Resource Economics. 2011;48:177–218. doi: 10.1007/s10640-010-9418-x. [DOI] [Google Scholar]
  8. Bennett EM, Peterson GD, Gordon LJ. Understanding relationships among multiple ecosystem services. Ecology Letters. 2009;12:1394–1404. doi: 10.1111/j.1461-0248.2009.01387.x. [DOI] [PubMed] [Google Scholar]
  9. Biró, M. 2009. Floodplain hay meadows along the river Tisza in Hungary. Grasslands in Europe. KNNV Publishing. 10.1163/9789004278103_027.
  10. Blackstock, K.L., J. Martin-Ortega, and C.J. Spray. 2015. Implementation of the European Water Framework Directive: what does taking an ecosystem services-based approach add? In Water Ecosystem Services: A Global Perspective, 57–64. In: Julia Martin-Ortega, Robert C. Ferrier, Iain J. Gordon, Shahbaz Khan, (Eds.) United Nations Educational, Scientific and Cultural Organization (UNESCO), France; Cambridge: Cambridge University Press. 10.1017/cbo9781316178904.008.
  11. Blicharska M, Smithers RJ, Kuchler M, Agrawal GK, Gutiérrez JM, Hassanali A, Huq S, Koller SH, et al. Steps to overcome the North-South divide in research relevant to climate change policy and practice. Nature Climate Change. 2017;7:21–27. doi: 10.1038/nclimate3163. [DOI] [Google Scholar]
  12. Boerema A, Van Passel S, Meire P. Cost-effectiveness analysis of ecosystem management with ecosystem services: From theory to practice. Ecological Economics. 2018;152:207–218. doi: 10.1016/j.ecolecon.2018.06.005. [DOI] [Google Scholar]
  13. Borgwardt F, Robinson L, Trauner D, Teixeira H, Nogueira AJA, Lillebø AI, Piet G, Kuemmerlen M, et al. Exploring variability in environmental impact risk from human activities across aquatic ecosystems. Science of the Total Environment. 2019;652:1396–1408. doi: 10.1016/j.scitotenv.2018.10.339. [DOI] [PubMed] [Google Scholar]
  14. Bouwma I, Schleyer C, Primmer E, Winkler KJ, Berry P, Young J, Carmen E, Špulerová J, et al. Adoption of the ecosystem services concept in EU policies. Ecosystem Services. 2018;29:213–222. doi: 10.1016/j.ecoser.2017.02.014. [DOI] [Google Scholar]
  15. Brauman KA, Daily GC, Duarte TK, Mooney HA. The nature and value of ecosystem services: An overview highlighting hydrologic services. Annual Review of Environment and Resources. 2007;32:67–98. doi: 10.1146/annurev.energy.32.031306.102758. [DOI] [Google Scholar]
  16. Bullock A, Acreman M. The role of wetlands in the hydrological cycle. Hydrology and Earth System Sciences Discussions. 2003;7:358–389. doi: 10.5194/hess-7-358-2003. [DOI] [Google Scholar]
  17. Burkhard B, Kroll F, Müller F. Landscapes’ capacities to provide ecosystem services: A concept for land-cover based assessments. Landscape Online. 2009 doi: 10.3097/LO.200915. [DOI] [Google Scholar]
  18. Campagne CS, Roche P, Müller F, Burkhard B. Ten years of ecosystem services matrix: Review of a (r)evolution. One Ecosystem. 2020;5:e51103. doi: 10.3897/oneeco.5.e51103. [DOI] [Google Scholar]
  19. Colloff MJ, Doody TM, Overton IC, Dalton J, Welling R. Re-framing the decision context over trade-offs among ecosystem services and wellbeing in a major river basin where water resources are highly contested. Sustainability Science. 2019;14:713–731. doi: 10.1007/s11625-018-0630-x. [DOI] [Google Scholar]
  20. Corral-Verdugo, V., M. Frías-Armenta, C. Tapia-Fonllem, and B. Fraijo-Sing. 2015. The psychological dimension of water ecosystem services. In Water Ecosystem Services: A Global Perspective. In: Julia Martin-Ortega, Robert C. Ferrier, Iain J. Gordon, Shahbaz Khan, (Eds.) United Nations Educational, Scientific and Cultural Organization (UNESCO), France. Cambridge: Cambridge University Press. 10.1017/cbo9781316178904.011.
  21. Costanza R, d’Arge R, de Groot R, Farber S, Grasso M, Hannon B, Limburg K, Naeem S, et al. The value of the world’s ecosystem services and natural capital. Nature. 1997;387:253–260. doi: 10.1038/387253a0. [DOI] [Google Scholar]
  22. Costanza R, de Groot R, Sutton P, van der Ploeg S, Anderson SJ, Kubiszewski I, Farber S, Turner RK. Changes in the global value of ecosystem services. Global Environmental Change. 2014;26:152–158. doi: 10.1016/j.gloenvcha.2014.04.002. [DOI] [Google Scholar]
  23. Council Directive 2007/60/EC of the European Parliament and of the Council of 23 October 2007 on the assessment and management of flood risks.
  24. Council Directive 2012/27/EU of the European Parliament and of the Council of 25 October 2012 on energy efficiency, amending Directives 2009/125/EC and 2010/30/EU and repealing Directives 2004/8/EC and 2006/32/EC.
  25. Council Directive 91/676/EEC of 12 December 1991 concerning the protection of waters against pollution caused by nitrates from agricultural sources.
  26. Council Directive 92/43/EEC of 21 May 1992 on the conservation of natural habitats and of wild fauna and flora.
  27. Council Directive 98/83/EC of 3 November 1998 on the quality of water intended for human consumption.
  28. Crossman, N.D., S. Nedkov, and L. Brander. 2019. Water flow regulation for mitigatingriver and coastalflooding. Paper submitted to the Expert Meeting on Advancing the Measurement of Ecosystem Services for Ecosystem Accounting, New York, 22-24 January 2019 and subsequently revised. Version of 1 April 2019.
  29. Czúcz B, Kalóczkai Á, Arany I, Kelemen K, Papp J, Havadtői K, Campbell K, Kelemen M, et al. How to design a transdisciplinary regional ecosystem service assessment: A case study from Romania, Eastern Europe. One Ecosystem. 2018 doi: 10.3897/oneeco.3.e26363. [DOI] [Google Scholar]
  30. Decsi B, Vári Á, Kozma Z. The effect of future land use changes on hydrologic ecosystem services: A case study from the Zala catchment. Hungary: Biologia Futura; 2020. [DOI] [PubMed] [Google Scholar]
  31. Derts Z, Koncsos L. Ecosystem services and land use zonation in the Hungarian Tisza deep floodplains. Pollack Periodica. 2012;7:79–90. doi: 10.1556/Pollack.7.2012.3.8. [DOI] [Google Scholar]
  32. Díaz S, Demissew S, Carabias J, Joly C, Lonsdale M, Ash N, Larigauderie A, Adhikari JR, et al. The IPBES Conceptual Framework: Connecting nature and people. Current Opinion in Environmental Sustainability. 2015;14:1–16. doi: 10.1016/j.cosust.2014.11.002. [DOI] [Google Scholar]
  33. EC. 2003. Directorate-General for the Environment, 2003. Common Implementation Strategy for theWater Framework Directive (2000/60/EC)—Overall approach to the classification of ecological status and ecological potential.
  34. EC. 2020. EU Biodiversity Strategy for 2030—Bringing nature back into our lives. COM/2020/380.
  35. EC. 2013 An EU Strategy on adaptation to climate change. COM/2013/0216.
  36. EC. 2013. Green Infrastructure (GI). Enhancing Europe’s natural capital. COM(2013) 249.
  37. Engloner A, Vargha M, Báldi A, Józsa J, editors. Hungarian water research programme: Challenges and resesarch tasks. Tihany: Centre for Ecological Research; 2019. [Google Scholar]
  38. Erős T, Grant EHC. Unifying research on the fragmentation of terrestrial and aquatic habitats: Patches, connectivity and the matrix in riverscapes. Freshwater Biology. 2015;60:1487–1501. doi: 10.1111/fwb.12596. [DOI] [Google Scholar]
  39. Erős T, Lowe WH. The landscape ecology of rivers: From patch-based to spatial network analyses. Current Landscape Ecology Reports. 2019 doi: 10.1007/s40823-019-00044-6. [DOI] [Google Scholar]
  40. Erős T, O’Hanley JR, Czeglédi I. A unified model for optimizing riverscape conservation. Journal of Applied Ecology. 2018;55:1871–1883. doi: 10.1111/1365-2664.13142. [DOI] [Google Scholar]
  41. Erős T, Kuehne L, Dolezsai A, Sommerwerk N, Wolter C. A systematic review of assessment and conservation management in large floodplain rivers: Actions postponed. Ecological Indicators. 2019;98:453–461. doi: 10.1016/j.ecolind.2018.11.026. [DOI] [Google Scholar]
  42. European Environment Agency (EEA) The European Environment State and Outlook 2020. Luxembourg: Publications Office of the European Union; 2019. [Google Scholar]
  43. Everard M. Community-based groundwater and ecosystem restoration in semi-arid north Rajasthan (1): Socio-economic progress and lessons for groundwater-dependent areas. Ecosystem Services. 2015;16:125–135. doi: 10.1016/j.ecoser.2015.10.011. [DOI] [Google Scholar]
  44. Friberg N, Buijse T, Carter C, Hering D, Spears BM, Verdonschot P, Moe TF. Effective restoration of aquatic ecosystems: Scaling the barriers. WIREs Water. 2017;4:e1190. doi: 10.1002/wat2.1190. [DOI] [Google Scholar]
  45. Funk, A., M. Tschikof, B. Grüner, K. Böck, T. Hein, and E. Bondar‐Kunze. 2020. Analysing the potential to restore the multi-functionality of floodplain systems by considering ecosystem service quality, quantity and trade-offs. River Research and Applications n/a: rra.3662. 10.1002/rra.3662.
  46. Ghermandi A, Sinclair M. Passive crowdsourcing of social media in environmental research: A systematic map. Global Environmental Change. 2019;55:36–47. doi: 10.1016/j.gloenvcha.2019.02.003. [DOI] [Google Scholar]
  47. Gómez-Baggethun E, Barton D, Berry P, Dunford R, Harrison P. Concepts and methods in ecosystem services valuation. Routledge Handbook of Ecosystem Services. London: Routledge; 2016. pp. 99–111. [Google Scholar]
  48. Gozlan RE, Karimov BK, Zadereev E, Kuznetsova D, Brucet S. Status, trends, and future dynamics of freshwater ecosystems in Europe and Central Asia. Inland Waters. 2019;9:78–94. doi: 10.1080/20442041.2018.1510271. [DOI] [Google Scholar]
  49. Grêt-Regamey A, Weibel B, Kienast F, Rabe S-E, Zulian G. A tiered approach for mapping ecosystem services. Ecosystem Services. 2015;13:16–27. doi: 10.1016/j.ecoser.2014.10.008. [DOI] [Google Scholar]
  50. Griebler C, Avramov M. Groundwater ecosystem services: A review. Freshwater Science. 2015;34:355–367. doi: 10.1086/679903. [DOI] [Google Scholar]
  51. Grizzetti B, Liquete C, Pistocchi A, Vigiak O, Zulian G, Bouraoui F, De Roo A, Cardoso AC. Relationship between ecological condition and ecosystem services in European rivers, lakes and coastal waters. Science of the Total Environment. 2019;671:452–465. doi: 10.1016/j.scitotenv.2019.03.155. [DOI] [PMC free article] [PubMed] [Google Scholar]
  52. Grizzetti B, Liquete C, Antunes P, Carvalho L, Geamănă N, Giucă R, Leone M, McConnell S, et al. Ecosystem services for water policy: Insights across Europe. Environmental Science & Policy. 2016;66:179–190. doi: 10.1016/j.envsci.2016.09.006. [DOI] [Google Scholar]
  53. Grizzetti B, Lanzanova D, Liquete C, Reynaud A, Cardoso AC. Assessing water ecosystem services for water resource management. Environmental Science & Policy. 2016;61:194–203. doi: 10.1016/j.envsci.2016.04.008. [DOI] [Google Scholar]
  54. Guida RJ, Swanson TL, Remo JWF, Kiss T. Strategic floodplain reconnection for the Lower Tisza River, Hungary: Opportunities for flood-height reduction and floodplain-wetland reconnection. Journal of Hydrology. 2015;521:274–285. doi: 10.1016/j.jhydrol.2014.11.080. [DOI] [Google Scholar]
  55. Haines-Young, R., and M. Potschin. 2010. The links between biodiversity, ecosystem services and human well-being. In: D.G. Raffaelli and C.L.J. Frid, eds., Ecosystem ecology, pp. 110–139. Cambridge: Cambridge University Press. 10.1017/cbo9780511750458.007.
  56. Hallouin T, Bruen M, Christie M, Bullock C, Kelly-Quinn M. Challenges in using hydrology and water quality models for assessing freshwater ecosystem services: A review. Geosciences. 2018;8:45. doi: 10.3390/geosciences8020045. [DOI] [Google Scholar]
  57. Hanna DEL, Tomscha SA, Ouellet Dallaire C, Bennett EM. A review of riverine ecosystem service quantification: Research gaps and recommendations. Edited by Danny Hooftman. Journal of Applied Ecology. 2018;55:1299–1311. doi: 10.1111/1365-2664.13045. [DOI] [Google Scholar]
  58. Hettiarachchi M, Morrison T, McAlpine C. Forty-three years of Ramsar and urban wetlands. 2015 doi: 10.1016/J.GLOENVCHA.2015.02.009. [DOI] [Google Scholar]
  59. Hornung LK, Podschun SA, Pusch M. Linking ecosystem services and measures in river and floodplain management. Ecosystems and People. 2019;15:214–231. doi: 10.1080/26395916.2019.1656287. [DOI] [Google Scholar]
  60. Hossu CA, Iojă I-C, Onose DA, Nită MR, Popa A-M, Talabă O, Inostroza L. Ecosystem services appreciation of urban lakes in Romania Synergies and trade-offs between multiple users. Ecosystem Services. 2019;37:100937. doi: 10.1016/j.ecoser.2019.100937. [DOI] [Google Scholar]
  61. IPBES . IPBES Guide on the production of assessments. Bonn, Germany: Secretariat of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services; 2018. [Google Scholar]
  62. IPBES. 2018b. The regional assessment report on Biodiversity and Ecosystem Services for Europe and Central Asia—Summary for Policymakers.
  63. Jacobs S, Burkhard B, Van Daele T, Staes J, Schneiders A. ‘The Matrix Reloaded’: A review of expert knowledge use for mapping ecosystem services. Ecological Modelling. 2015;295:21–30. doi: 10.1016/j.ecolmodel.2014.08.024. [DOI] [Google Scholar]
  64. Jeffery R. Authorship in multi-disciplinary, multi-national North-South research projects: issues of equity, capacity and accountability. Compare: A Journal of Comparative and International Education. 2014;44:208–229. doi: 10.1080/03057925.2013.829300. [DOI] [Google Scholar]
  65. Junk WJ, Bayley PB, Sparks RE. The flood pulse concept in river-floodplain systems. Canadian Special Publication of Fisheries and Aquatic Sciences. 1989;106:110–127. [Google Scholar]
  66. Karlsson S, Srebotnjak T, Gonzales P. Understanding the North-South knowledge divide and its implications for policy: A quantitative analysis of the generation of scientific knowledge in the environmental sciences. Environmental Science & Policy. 2007;10:668–684. doi: 10.1016/j.envsci.2007.04.001. [DOI] [Google Scholar]
  67. Kaval P. Integrated catchment management and ecosystem services: A twenty-five year overview. Ecosystem Services. 2019;37:100912. doi: 10.1016/j.ecoser.2019.100912. [DOI] [Google Scholar]
  68. Keeler BL, Polasky S, Brauman KA, Johnson KA, Finlay JC, O’Neill A, Kovacs K, Dalzell B. Linking water quality and well-being for improved assessment and valuation of ecosystem services. Proceedings of the National Academy of Sciences. 2012;109:18619–18624. doi: 10.1073/pnas.1215991109. [DOI] [PMC free article] [PubMed] [Google Scholar]
  69. Keller PS, Catalán N, von Schiller D, Grossart H-P, Koschorreck M, Obrador B, Frassl MA, Karakaya N, et al. Global CO2 emissions from dry inland waters share common drivers across ecosystems. Nature Communications. 2020;11:2126. doi: 10.1038/s41467-020-15929-y. [DOI] [PMC free article] [PubMed] [Google Scholar]
  70. Kienast F, Bolliger J, Potschin M, de Groot RS, Verburg PH, Heller I, Wascher D, Haines-Young R. Assessing landscape functions with broad-scale environmental data: Insights gained from a prototype development for Europe. Environmental Management. 2009;44:1099–1120. doi: 10.1007/s00267-009-9384-7. [DOI] [PubMed] [Google Scholar]
  71. Kistenkas FH, Bouwma IM. Barriers for the ecosystem services concept in European water and nature conservation law. Ecosystem Services. 2018;29:223–227. doi: 10.1016/j.ecoser.2017.02.013. [DOI] [Google Scholar]
  72. Langhans SD, Reichert P, Schuwirth N. The method matters: A guide for indicator aggregation in ecological assessments. Ecological Indicators. 2014;45:494–507. doi: 10.1016/j.ecolind.2014.05.014. [DOI] [Google Scholar]
  73. Langhans SD, Jähnig SC, Lago M, Schmidt-Kloiber A, Hein T. The potential of ecosystem-based management to integrate biodiversity conservation and ecosystem service provision in aquatic ecosystems. Science of the Total Environment. 2019;672:1017–1020. doi: 10.1016/j.scitotenv.2019.04.025. [DOI] [PubMed] [Google Scholar]
  74. Lindenmayer D. Improving restoration programs through greater connection with ecological theory and better monitoring. Frontiers in Ecology and Evolution. 2020 doi: 10.3389/fevo.2020.00050. [DOI] [Google Scholar]
  75. Maes, J., A. Teller, M. Erhard, S. Condé, S. Vallecillo, J.I. Barredo, M.L. Paracchini, D. Abdul Malak, et al. 2020. Mapping and Assessment of Ecosystems and their Services: An EU ecosystem assessment. Publications Office of the European Union EUR 30161 EN. ISBN 978-92-76-17833-0, 10.2760/757183, JRC120383. Ispra.
  76. Martin DM, Mazzotta M. Non-monetary valuation using Multi-Criteria Decision Analysis: Using a strength-of-evidence approach to inform choices among alternatives. Ecosystem Services. 2018;33:124–133. doi: 10.1016/j.ecoser.2018.06.001. [DOI] [PMC free article] [PubMed] [Google Scholar]
  77. Martín-López B, Iniesta-Arandia I, García-Llorente M, Palomo I, Casado-Arzuaga I, Amo DGD, Gómez-Baggethun E, Oteros-Rozas E, et al. Uncovering ecosystem service bundles through social preferences. PLoS ONE. 2012;7:e38970. doi: 10.1371/journal.pone.0038970. [DOI] [PMC free article] [PubMed] [Google Scholar]
  78. Martin-Ortega J, Ferrier RC, Gordon IJ, Khan S, editors. Water ecosystem services, A global perspective. International hydrology series. Cambridge: Cambridge University Press; 2015. [Google Scholar]
  79. Mastrángelo ME, Pérez-Harguindeguy N, Enrico L, Bennett E, Lavorel S, Cumming GS, Abeygunawardane D, Amarilla LD, et al. Key knowledge gaps to achieve global sustainability goals. Nature Sustainability. 2019 doi: 10.1038/s41893-019-0412-1. [DOI] [Google Scholar]
  80. Maynard, S., D. James, S. Hoverman, A. Davidson, and S. Mooney. 2015. An ecosystem services-based approach to integrated regional catchment management: the South East Queensland experience. In Water Ecosystem Services: A Global Perspective, 90–98. In: Julia Martin-Ortega, Robert C. Ferrier, Iain J. Gordon, Shahbaz Khan, (Eds.) United Nations Educational, Scientific and Cultural Organization (UNESCO), France. Cambrdge: Cambridge University Press. 10.1017/cbo9781316178904.012.
  81. McDonough K, Hutchinson S, Moore T, Hutchinson JMS. Analysis of publication trends in ecosystem services research. Ecosystem Services. 2017;25:82–88. doi: 10.1016/j.ecoser.2017.03.022. [DOI] [Google Scholar]
  82. Mihók B, Biró M, Molnár Z, Kovács E, Bölöni J, Erős T, Standovár T, Török P, et al. Biodiversity on the waves of history: Conservation in a changing social and institutional environment in Hungary, a post-soviet EU member state. Biological Conservation. 2017;211:67–75. doi: 10.1016/j.biocon.2017.05.005. [DOI] [Google Scholar]
  83. Molnár Zs, Berkes F. Role of traditional ecological knowledge in linking cultural and natural capital in cultural landscapes. In: Paracchini ML, Zingari P, editors. Reconnecting natural and cultural capital: Contributions from science and policy. Brussels: Office of Publications of the European Union; 2018. pp. 183–194. [Google Scholar]
  84. Moomaw WR, Chmura GL, Davies GT, Finlayson CM, Middleton BA, Natali SM, Perry JE, Roulet N, et al. Wetlands in a changing climate: Science, policy and management. Wetlands. 2018;38:183–205. doi: 10.1007/s13157-018-1023-8. [DOI] [Google Scholar]
  85. Naumann, S., G. Anzaldua, P. Berry, S. Burch, M. Davis, A. Frelih-Larsen, H. Gerdes, and M. Sanders. 2011. Assessment of the potential of ecosystem-based approaches to climate change adaptation and mitigation. Final report to the European Commission, DG Environment. Ecologic institute and Environmental Change Institute, Oxford University Centre for the Environment.
  86. Nedkov S, Burkhard B. Flood regulating ecosystem services: Mapping supply and demand, in the Etropole municipality, Bulgaria. Ecological Indicators. 2012;21:67–79. doi: 10.1016/j.ecolind.2011.06.022. [DOI] [Google Scholar]
  87. Pascual U, Balvanera P, Díaz S, Pataki G, Roth E, Stenseke M, Watson RT, Başak Dessane E, et al. Valuing nature’s contributions to people: the IPBES approach. Current Opinion in Environmental Sustainability 26–27. Open Issue, Part II. 7-16. 2017 doi: 10.1016/j.cosust.2016.12.006. [DOI] [Google Scholar]
  88. Paudyal K, Baral H, Keenan RJ. Assessing social values of ecosystem services in the Phewa Lake Watershed, Nepal. Forest Policy and Economics. 2018;90:67–81. doi: 10.1016/j.forpol.2018.01.011. [DOI] [Google Scholar]
  89. Pinke Z, Decsi B, Kozma Z, Vári Á, Lövei GL. A spatially explicit analysis of wheat and maize yield sensitivity to changing groundwater levels in Hungary, 1961–2010. Science of the Total Environment. 2020;715:136555. doi: 10.1016/j.scitotenv.2020.136555. [DOI] [PubMed] [Google Scholar]
  90. Podschun SA, Albert C, Costea G, Damm C, Dehnhardt A, Fischer C, Fischer H, Foeckler F, et al. RESI—Anwendungshandbuch. Berlin: Leibniz-Institut für Gewässerökologie und Binnenfischerei; 2018. [Google Scholar]
  91. Poff NL, Olden JD, Merritt DM, Pepin DM. Homogenization of regional river dynamics by dams and global biodiversity implications. Proceedings of the National Academy of Sciences United States of America. 2007;104:5732–5737. doi: 10.1073/pnas.0609812104. [DOI] [PMC free article] [PubMed] [Google Scholar]
  92. Poikane S, Zampoukas N, Borja A, Davies SP, van de Bund W, Birk S. Intercalibration of aquatic ecological assessment methods in the European Union: Lessons learned and way forward. Environmental Science & Policy. 2014;44:237–246. doi: 10.1016/j.envsci.2014.08.006. [DOI] [Google Scholar]
  93. Qiu J, Turner MG. Spatial interactions among ecosystem services in an urbanizing agricultural watershed. Proceedings of the National Academy of Sciences United States of America. 2013;110:12149–12154. doi: 10.1073/pnas.1310539110. [DOI] [PMC free article] [PubMed] [Google Scholar]
  94. Reynaud A, Lanzanova D. A global meta-analysis of the value of ecosystem services provided by lakes. Ecological Economics. 2017;137:184–194. doi: 10.1016/j.ecolecon.2017.03.001. [DOI] [PMC free article] [PubMed] [Google Scholar]
  95. Saarela S-R, Rinne J. Knowledge brokering and boundary work for ecosystem service indicators. An urban case study in Finland. Ecological Indicators. 2016;61:49–62. doi: 10.1016/j.ecolind.2015.07.016. [DOI] [Google Scholar]
  96. Sanon S, Hein T, Douven W, Winkler P. Quantifying ecosystem service trade-offs: The case of an urban floodplain in Vienna, Austria. Journal of Environmental Management. 2012;111:159–172. doi: 10.1016/j.jenvman.2012.06.008. [DOI] [PubMed] [Google Scholar]
  97. Schaafsma, M., S. Ferrini, A.R. Harwood, and I.J. Bateman. 2015. The first United Kingdom’s National Ecosystem Assessment and beyond. In Water Ecosystem Services: A Global Perspective, 73–81. In: Julia Martin-Ortega, Robert C. Ferrier, Iain J. Gordon, Shahbaz Khan, (Eds.) United Nations Educational, Scientific and Cultural Organization (UNESCO), France. Cambridge: Cambridge University Press. 10.1017/cbo9781316178904.010.
  98. Scheffer M. Multiplicity of stable states in freshwater systems. Hydrobiologia. 1990;200:475–486. doi: 10.1007/BF02530365. [DOI] [Google Scholar]
  99. Schindler S, O’Neill FH, Biró M, Damm C, Gasso V, Kanka R, van der Sluis T, Krug A, et al. Multifunctional floodplain management and biodiversity effects: A knowledge synthesis for six European countries. Biodiversity and Conservation. 2016;25:1349–1382. doi: 10.1007/s10531-016-1129-3. [DOI] [Google Scholar]
  100. Schindler S, Sebesvari Z, Damm C, Euller K, Mauerhofer V, Schneidergruber A, Biró M, Essl F, et al. Multifunctionality of floodplain landscapes: Relating management options to ecosystem services. Landscape Ecology. 2014;29:229–244. doi: 10.1007/s10980-014-9989-y. [DOI] [Google Scholar]
  101. Schröter M, van der Zanden EH, van Oudenhoven APE, Remme RP, Serna-Chavez HM, de Groot RS, Opdam P. Ecosystem services as a contested concept: A synthesis of critique and counter-arguments. Conservation Letters. 2014;7:514–523. doi: 10.1111/conl.12091. [DOI] [Google Scholar]
  102. Schulp CJE, Thuiller W, Verburg PH. Wild food in Europe: A synthesis of knowledge and data of terrestrial wild food as an ecosystem service. Ecological Economics. 2014;105:292–305. doi: 10.1016/j.ecolecon.2014.06.018. [DOI] [Google Scholar]
  103. Shackleton RT, Biggs R, Richardson DM, Larson BMH. Social-ecological drivers and impacts of invasion-related regime shifts: Consequences for ecosystem services and human wellbeing. Environmental Science & Policy. 2018;89:300–314. doi: 10.1016/j.envsci.2018.08.005. [DOI] [Google Scholar]
  104. Stammel B, Fischer C, Cyffka B, Albert C, Damm C, Dehnhardt A, Fischer H, Foeckler F, et al. Assessing land use and flood management impacts on ecosystem services in a river landscape (Upper Danube, Germany) River Research and Applications. 2020 doi: 10.1002/rra.3669. [DOI] [Google Scholar]
  105. Syrbe R-U, Walz U. Spatial indicators for the assessment of ecosystem services: Providing, benefiting and connecting areas and landscape metrics. Ecological Indicators. 2012;21:80–88. doi: 10.1016/j.ecolind.2012.02.013. [DOI] [Google Scholar]
  106. Thiele J, Albert C, Hermes J, von Haaren C. Assessing and quantifying offered cultural ecosystem services of German river landscapes. Ecosystem Services. 2020;42:101080. doi: 10.1016/j.ecoser.2020.101080. [DOI] [Google Scholar]
  107. Thorp JH, Flotemersch JE, Delong MD, Casper AF, Thoms MC, Ballantyne F, Williams BS, O’Neill BJ, et al. Linking Ecosystem services, rehabilitation, and river hydrogeomorphology. BioScience. 2010;60:67–74. doi: 10.1525/bio.2010.60.1.11. [DOI] [Google Scholar]
  108. Thorp JH, Thoms MC, Delong MD. The riverine ecosystem synthesis: Biocomplexity in river networks across space and time. River Research and Applications. 2006;22:123–147. doi: 10.1002/rra.901. [DOI] [Google Scholar]
  109. Thorp KR, French AN, Rango A. Effect of image spatial and spectral characteristics on mapping semi-arid rangeland vegetation using multiple endmember spectral mixture analysis (MESMA) Remote Sensing of Environment. 2013;132:120–130. doi: 10.1016/j.rse.2013.01.008. [DOI] [Google Scholar]
  110. Tomscha SA, Gergel SE, Tomlinson MJ. The spatial organization of ecosystem services in river-floodplains. Ecosphere. 2017;8:e01728. doi: 10.1002/ecs2.1728. [DOI] [Google Scholar]
  111. Vallecillo S, La Notte A, Ferrini S, Maes J. How ecosystem services are changing: An accounting application at the EU level. Ecosystem Services. 2019;40:101044. doi: 10.1016/j.ecoser.2019.101044. [DOI] [PMC free article] [PubMed] [Google Scholar]
  112. Vallet A, Locatelli B, Levrel H, Wunder S, Seppelt R, Scholes RJ, Oszwald J. Relationships between ecosystem services: Comparing methods for assessing tradeoffs and synergies. Ecological Economics. 2018;150:96–106. doi: 10.1016/j.ecolecon.2018.04.002. [DOI] [Google Scholar]
  113. Vannote RL, Minshall GW, Cummins KW, Sedell JR, Cushing CE. The river continuum concept. Canadian Journal of Fisheries and Aquatic Sciences. 1980;37:130–137. doi: 10.1139/f80-017. [DOI] [Google Scholar]
  114. Vermaat JE, Immerzeel B, Pouta E, Juutinen A. Applying ecosystem services as a framework to analyze the effects of alternative bio-economy scenarios in Nordic catchments. Ambio. 2020;49:1784–1796. doi: 10.1007/s13280-020-01348-2. [DOI] [PMC free article] [PubMed] [Google Scholar]
  115. Wantzen KM, Ballouche A, Longuet I, Bao I, Bocoum H, Cissé L, Chauhan M, Girard P, et al. River culture: An eco-social approach to mitigate the biological and cultural diversity crisis in riverscapes. Ecohydrology & Hydrobiology. 2016;16:7–18. doi: 10.1016/j.ecohyd.2015.12.003. [DOI] [Google Scholar]
  116. Werners SE, Flachner Z, Matczak P, Falaleeva M, Leemans R. Exploring earth system governance: A case study of floodplain management along the Tisza river in Hungary. Global Environmental Change. 2009;19:503–511. doi: 10.1016/j.gloenvcha.2009.07.003. [DOI] [Google Scholar]
  117. Wu J, Huang J, Han X, Xie Z, Gao X. Three-Gorges Dam: Experiment in habitat fragmentation? Science. 2003;300:1239–1240. doi: 10.1126/science.1083312. [DOI] [PubMed] [Google Scholar]
  118. Xu X, Jiang B, Tan Y, Costanza R, Yang G. Lake-wetland ecosystem services modeling and valuation: Progress, gaps and future directions. Ecosystem Services. 2018;33:19–28. doi: 10.1016/j.ecoser.2018.08.001. [DOI] [Google Scholar]

Articles from Ambio are provided here courtesy of Springer

RESOURCES