Abstract
The Venice lagoon—the largest Mediterranean coastal lagoon—is characterized by the presence at its edges of 31 “valli da pesca”, types of artificial ecosystems that mime the ecological processes of a transitional aquatic ecosystem. Constituted by a series of regulated lakes bounded by artificial embankments, the valli da pesca were established centuries ago to maximize provisioning Ecosystem Services (ESs), such as fishing and hunting. As time passed, the valli da pesca underwent an intentional isolation process leading to private management. Nonetheless, the valli da pesca are still exchanging energy and matter with the “open’ lagoon and today represent an essential element within the context of lagoon conservation. This study aimed to analyze the possible effects of artificial management on both ESs supply and landscape arrangements by assessing 9 ESs (climate regulation, water purification, lifecycle support, aquaculture, waterfowl hunting, wild food, tourism, information for cognitive development, and birdwatching), along with eight landscape indicators. Obtained results suggested that the valli da pesca are today ruled under five different management strategies, according to the maximized ES. Management conditions influence the landscape pattern and achieve a series of “side effects” on the other ESs. The comparison between the managed and abandoned valli da pesca highlights the importance of anthropogenic interventions for conserving these ecosystems, as the abandoned valli da pesca show a loss of ecological gradients, landscape heterogeneity, and provisioning ESs. Nevertheless, the persistence of intrinsic geographical and morphological characteristics still prevails regardless of intentional landscape molding. The result is that the provisioning ESs capacity per unit area is higher in the abandoned valli da pesca than in the open lagoon, emphasizing the importance of these confined areas of the lagoon ecosystem. Considering the spatial distribution of multiple ESs, the provisioning ESs flow that does not occur in the abandoned valli da pesca seems to be replaced by the flow of cultural ESs. Thus, the ESs spatial pattern highlights a balancing effect between different ESs categories. The results are discussed considering the trade-offs generated by private land conservation, anthropogenic interventions, and their relevance for the ecosystem-based management of Venice lagoon.
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Introduction
Traditionally recognized as highly productive ecosystems1,2,3, coastal lagoons and deltas have always experienced the effects of multiple interactions between humans and the environment4,5,6,7,8,9,10,11,12. Among the coastal lagoons of the Mediterranean Sea, the Venice lagoon represents a good example of a complex social-ecological system subjected to a long co-evolution process of such interactions. The peculiar lagoon environment, synchronized with the daily tidal regime and seasonal biological cycles, played a key role in shaping human settlements, which occurred in different areas depending on the activity to be delivered. While residential safety was sought on the islands through ground consolidation techniques13, other modifications to the landscape were devoted to facilitating food provisioning14,15,16.
Since remote times16,17 in Italy as well as elsewhere17,18,19,20,21,22, people have observed fish and waterbird migrations and identified the areas at the interface between land and water as the places where these species naturally concentrate15,23. These areas, where land, rivers, and lagoon water meet, have been seen as forefronts where fishing and hunting can be carried out more easily and effectively24,25,26,27. Therefore, people have begun to exploit them by adopting temporary closures and entrapment systems19,28,29,30.
In the Venice lagoon, local ecological knowledge and empirical observations have inspired the use of nets and temporary reed fences to facilitate fish trapping in the most confined part of the lagoon ecosystem. This gave origin to the Italian “valli da pesca” 31, where capture-based extensive aquaculture and hunting reserves were established (Fig. 1).
Over the decades, permanent dikes have replaced the temporary boundaries and separated the valli da pesca from the main part of the Venice lagoon31,32,33, leading the valli da pesca to become artificially managed as if they were productive areas. On the one hand, such a change drove the valli da pesca to rely on men’s efforts for their functioning and maintenance, especially for water flow and fish recruitment. On the other hand, implementing artificial management in the valli da pesca allowed for conserving these areas through empirical nature-based solutions, namely saltmarshes restoration, channel dredging, fence planting, levees reinforcement with ripraps. This allows them to maintain their capability to preserve, within their reinforced boundaries, the typical elements of a transitional water ecosystem, such as saltmarshes and salinity gradients, as well as the related ecological processes. Consequently, the valli da pesca continue to represent important wintering and nesting areas34,35,36,37 making a noticeable contribution in terms of Ecosystem Services38,39 (ESs) to the entire lagoon ecosystem, even if they have been privately managed and subjected to anthropogenic interventions for a long time.
Indeed, the valli da pesca today contribute to the lagoon ESs supply, representing 38% of the total potential to provide ESs and ensure 24% of the total flow to the local community, although they cover only 17% of the lagoon surface40.
Considering the great importance of these confined and overlooked areas of the lagoon, we focused on analyzing the ESs supply pattern under different human management condition of the 31 valli da pesca in the Venice lagoon. Our principal aim was to verify whether and how different management conditions in the valli da pesca imply distinctive anthropogenic modifications, capable of influencing their ecosystems’ structure and so their ESs.
To do so, we assessed nine ESs belonging to the “regulating and maintenance”, “provisioning”, and “cultural” ESs categories41 by evaluating their capacity and flow42. This approach allows us to investigate whether different management strategies influence the potential of these ecosystems to deliver multiple ESs (capacity), the amount of ESs that reaches society (the flow), or both 42,43.
We classified the valli da pesca into five groups that indicate the management strategies in terms of ESs maximization. Indeed, the most important ES at which the management aims was identified according to the managers’ statements and validated with data regarding fish production, hunting catches, and hosted tourists and excursionists.
In addition, we described the landscape features that characterize each of the valli da pesca through landscape indicators. Multivariate statistical analyses allowed us to detect, on the one hand, whether different artificial management strategies led to significant peculiarities in landscape arrangement and, on the other hand, how such changes can have consequences on the ESs.
We hypothesized that the maximization of one category of ESs, changing both the landscape features and the processes in the valli da pesca through anthropogenic interventions, could have consequences for other ESs categories that need to be assessed to avoid imbalances or sustainability issues. Furthermore, such an assessment could provide a valuable framework to describe which anthropogenic modifications are effective in allowing the exploitation of a transitional aquatic ecosystem for provisioning or cultural ESs while avoiding affecting its regulating ESs capacity.
Results
Classification of the valli da pesca as managed ecosystems
The ESs assessment and interviews showed that the valli da pesca managers usually maximize only one or a few ESs. Consequently, the 31 valli da pesca can be classified into five groups according to the adopted management strategy and maximized ESs (Table 1).
Group “F” is composed of the valli da pesca that adopted the strategy to prioritize the maximization of fish production from extensive aquaculture. Group “M” is composed of the valli da pesca that are managed to exploit aquaculture and hunting, sometimes adding tourist opportunities. Group “H” identifies the valli da pesca that enhance hunting activity. The valli da pesca that no longer rely on provisioning ESs and base their management on maximizing cultural ESs represent the group “R”. Group “N” includes valli da pesca that are no longer managed.
Ecosystem services indicators analyses
Analyses of the aggregated ESs indicators show that the valli da pesca of groups F, M, and H have higher values of regulating and maintenance ESs than those of groups R and N, both for capacity and flow. Group F significantly differed from R and N in terms of capacity (p-value 0.007 and 0.009, respectively) and R and N flow (p-value 0.007 and 0.006, respectively). Group M showed a similar pattern to R and N capacity (p-value 0.004 and 0.006, respectively) and R and N flow (p-value 0.006 and 0.009, respectively), as shown in Fig. 2a,b.
The capacity indicator of provisioning ESs did not show statistically significant differences among the groups (Fig. 2c), even though groups F, M, and H showed higher values than R and N. In contrast, the flow indicator of group M had a significantly higher value than those of groups R and N (p-value 0.00070, 0.00074), as shown in Fig. 2d.
The cultural ESs capacity resulted in a lower value in group N when compared to the capacity of the managed valli da pesca of groups F, M, H, and R (Fig. 2e). Among the managed groups, the cultural ESs capacity reached its highest value in group R, for which the flow was consistently higher than the flow in F (p-value 0.004), H (p-value 0.001), and N (p-value 0.046). In particular, groups F and H had no flow, whereas limited flow was observed in group M (Fig. 2f).
On average, all groups had a capacity-flow difference higher than zero (Fig. 3). However, group M showed a low capacity-flow difference (Fig. 3b) due to provisioning ESs flow higher than capacity in two valli da pesca. This can be noticed, as well, considering the ESs capacity and flow values in each of the areas through the stellar charts available in the Supplementary Information section (S1).
The results of the spatially explicit ESs assessment and the ESs aggregate indicators analyses suggested the presence of interactions between different ESs categories. Groups that maximize provisioning ESs do not sustain cultural ESs, and vice versa. Regulating ESs seemed to be associated more with provisioning ESs maximization than with cultural ESs maximization. The exploratory correlation analysis among ESs aggregated indicators detected a significant positive correlation between the capacity and flow of regulating ESs (Spearman’s rho = 0.95, p-value = 2.2e−16, Fig. 4). In contrast, no linear correlation arises between provisioning ESs capacity and flow, nor between cultural ESs capacity and flow. Regarding the relationships between different categories of ESs, we detected a positive Spearman’s correlation between provisioning ESs capacity and regulating ESs capacity (ρ = 0.62, p-value = 0.0002), as well as between provisioning ESs capacity and regulating ESs flow (ρ = 0.57, p-value = 0.001).
Instead, a negative correlation arises between the capacity of provisioning ESs and the flow of cultural ESs (ρ = − 0.41, p-value = 0.024).
Landscape characteristics analysis
Seven out of eight landscape indicators showed significant differences among the groups. As shown in Fig. 5a, group F had the highest ratio between the water-covered surface and the total area; groups M and H followed along with group N; only group R had a low water area/total area ratio, which significantly differed from all the other groups (R vs. F: p-value 0.0002; R vs. M: p-value 0.017; R vs. H: p-value 0.031; R vs. N: p-value 0.032). Most of the water-covered area is represented by brackish basins that only in some groups are interspersed with freshwater lakes. As a result, a freshwater/brackish water ratio results in a significant difference between groups N and H (M vs. N: p-value 0.006; H vs. N: p-value 0.006) (Fig. 5b).
In the valli da pesca of group R, terrestrial land represented most of the surface (Fig. 5c), driving the ratio between land and saltmarshes to the highest value (Fig. 5d). A peculiar pattern can be noticed focusing on saltmarshes geometry: even if saltmarshes cover similar surfaces in all groups (Fig. 5e), their geometry varies considerably under different management strategies. As shown in Fig. 5f, the edge length of saltmarshes per unit area was higher in groups M and H.
All these features make a significant difference also in the landscape heterogeneity. Figure 5g shows that the average Shannon’s diversity index for groups M and H is considerably higher than F and N index values, and slightly higher than the value of group R (F vs. M: p-value = 0.018, F vs. H p-value = 0.023, M vs. N: p-value = 0.025, H vs. N: p-value = 0.031).
F and N also presented Shannon’s landscape evenness similar to the other groups; however, no significant differences were observed among groups in terms of evenness or richness in M and H (Fig. 5h).
Aerial images of the ground-truth landscape elements considered for calculating the landscape indicators are available in Supplementary Material (S2, Figs. S2.1–S2.5).
Discussion
Coastal areas have always provided a plethora of ESs for human well-being. Among coastal ecosystems, coastal lagoons and transitional aquatic ecosystems have been exploited for aquaculture purposes since ancient times18,20,21,22,33,44,45,46,47.
In Italy, traditional ecological knowledge about the migratory behavior of fish that migrate from the sea to shallow brackish waters 36,37,48,49,50 has driven the development of particular enclosures to entrap juvenile fish and hold them until they reach commercial size32,51,52,53,54. The Venice lagoon made no exception, and today is home to the most emblematic examples of this type of extensive capture-based aquaculture, which often integrates with waterfowl hunting20,31,33. These systems, called valli da pesca, initially presented thin mobile barriers, but permanent dikes and boundaries were soon built to protect them. However, the decision to isolate these portions of the lagoon ecosystem implied the necessity of artificially maintaining their functional elements by ensuring the exchange of freshwater and saltwater on the landside and the lagoon side, respectively. Thus, the valli da pesca started to be managed as artificial ecosystems, where the maintenance of water fluxes, salinity gradients, and landscape elements became dependent on human work.
The valli da pesca, being artificially managed, have been excluded from most of the studies concerning the lagoon of Venice; therefore, their conditions and environmental characteristics are poorly known. Nevertheless, they represent examples of how anthropogenic modifications in an ecosystem can have several effects on both the ESs supply and landscape.
To understand the effects of anthropogenic management of ecosystems using nature-based practical interventions, we adopted a combined approach using ESs and landscape indicators.
The highlighted relationship between ESs, landscape arrangement, and anthropogenic interventions confirms that analyses of ESs are essential to frame the actual value of a managed ecosystem. Moreover, ESs assessments inform the sustainable use of services and resources, especially when managing highly modified ecosystems with a prominent role in a complex social-ecological system.
Our analyses highlighted that managing the valli da pesca allows for a higher ESs capacity than in the absence of management. The valli da pesca that are no longer managed (group N) show a provisioning ESs capacity that, despite being the lowest among the five groups, still tends to be 3.77 times higher than the capacity per unit area in the open lagoon. The main reason for the potential to provide ESs could be, apart from the persistence of morphological and geographical factors that make the confined lagoon areas attractive for fish and birds, the remnants of the structures of the valli da pesca. Such structures are estimated to be still capable of influencing the hydrodynamics of the area55 and probably offer some resilience both in slowing the loss of environmental heterogeneity and in preventing excessive pressures, even after the end of human work. The management of these confined areas in the lagoon, even if applied for a period and then discontinued, could thus have an interesting effect on increasing the natural capacity for provisioning ESs through anthropogenic interventions, which maintain some features that imitate the “original” lagoon processes.
A side effect of this outcome is that, in managed valli da pesca, the capacity to offer cultural ESs is high because of the maintenance of those characteristics that work as attractive features. However, because of their closed-access regime, this high cultural ESs capacity does not translate into flow in the valli da pesca dedicated to aquaculture and hunting (groups F and H). Such comparison sheds light on a trade-off between the willingness to maintain high provisioning ESs capacity and flow and the subsequent necessity to lower the flow for cultural ESs to avoid disturbance due to widespread human presence.
In contrast, the valli da pesca that are not managed are broadly frequented by visitors and register a considerable flow, quite as much as the valli da pesca that are purposely managed to offer recreational opportunities.
The difficulty in maintaining high capacities in all three categories of ESs in the attempt to maximize multiple ESs was evident in the M group. Indeed, when considering the relationship between capacity and flow, it turns out that some of the valli da pesca belonging to group M had a flow that exceeded the capacity of provisioning ESs. Moreover, in group M the difference between capacity and flow was lower than in the valli da pesca that focus on one category of ESs.
This result may be related to the necessity to subdivide interventions to maintain the capacity for different categories of ESs simultaneously, resulting in less effective maximization of provisioning ESs capacity.
Because of this contrasting relationship, a negative correlation was also found between the capacity of provisioning ESs and the flow of cultural ESs, explained by the fact that the maximization of provisioning ESs hampers tourists’ access and vice versa. The negative correlation also suggests that building structures and consolidating land to pander for tourist enjoyment can affect the interest in maintaining the characteristics needed to ensure the capacity for provisioning ESs, namely aquaculture, hunting, and harvesting of edible plants and honey. Consequently, when a valle da pesca is managed to maximize recreational activities, regulating services are lost along with the important landscape elements that allow the imitation of natural lagoon functioning. This dynamic probably arises because only the sight of a few natural elements are sufficient to enhance the attractiveness and psycho-physical restorativeness56,57,58,59. Nevertheless, the necessity to ensure a satisfactory flow of paying visitors has pushed managers to add artificial elements, such as piers, buildings, visitors’ centers, and pools, within a landscape arrangement that does not care much about the actual ecological role of saltmarshes and landscape gradients. This also ignores the necessity of ensuring connectivity between the valli da pesca and the lagoon.
This disconnection from the requirement to maintain ecological processes is reflected in the landscape indicators in other groups. On the one hand, the lack of management in group N has led to a preponderance of saltwater over freshwater pools and saltmarshes, which are instead preserved in the managed valli da pesca (groups F, M, H, R). On the other hand, among the valli da pesca still under management, the most detrimental anthropogenic effect on aquatic habitats seems to be related to the neglect of provisioning ESs to maximize cultural ESs.
The correlation analyses confirmed a relationship between the capacity and flow of the same ESs category and between capacities and flows of different ESs categories, likely due to anthropogenic interventions on the landscape with their effects on the ecosystem structure and functioning.
This result suggests that in managed aquatic ecosystems, such as those considered in this study, a concordance between ESs and ecosystem characteristics occurs. Their relationship can be controlled through anthropogenic modifications, as argued by other authors, both in aquatic60,61,62,63,64 and terrestrial ecosystems65.
Indeed, to maintain adequate provision of ESs over time, managers must ensure that they do not exploit a flow that is too high compared to the capacity. In addition, they must be aware not to put at risk the capacity of a category of ESs because of the implementation of interventions that maximize the supply of another specific category of ESs. Overlooking the links and feedback loops between different landscape features, and between different ESs, can prove harmful to the valli da pesca system. In contrast, understanding them can represent an impactful outcome, especially when attempting to infer the role of anthropogenic interventions in coupling productive activities and conservation practices.
The choice to lower or even abandon provisioning ESs in the artificially managed ecosystems of the valli da pesca could even prove counterproductive, as it could push regulating ESs in the same direction, according to our results. This can be an unexpected outcome because it is often argued that provisioning ESs should provoke detrimental trade-offs with regulating and maintenance services66,67. In addition, other authors have reported that implementing other systems to enhance aquaculture ES capacity often leads to environmental issues, such as deforestation and water eutrophication, as well as competition for space21,28,68,69. However, this study shed new light on the relationship between regulating and provisioning ESs in artificially managed ecosystems, fostering a new perspective on the side effects of anthropogenic management through empirical nature-based solutions aimed to enhance ESs capacity.
According to this perspective, the need to grant a high capacity for provisioning ESs in the valli da pesca through anthropogenic interventions boosts the conservation of some habitats and processes.
As an example, the valli da pesca devoted to aquaculture are managed to ensure the persistence of both the presence of fingerlings and salinity gradients. In contrast, the valli da pesca that maximize hunting implement a series of landscape modifications to maintain suitable wintering and nesting habitats, despite the main water body of the lagoon having lost several of such natural characteristics34,36,37,70. Besides enhancing provisioning ESs, those efforts can also maintain the presence of some species and support their lifecycles in the long run, confirming the observation of other authors34,50.
Consequently, the strategy of implementing measures to imitate the natural processes of lagoon ecosystems to ensure a high provisioning ESs capacity brings up also other ESs, belonging to both regulating and maintenance and cultural ESs categories. Revenues from provisioning ESs flow, in turn, allow managers to implement nature-based solutions and anthropogenic interventions again to sustain the high ESs capacity on which they rely, as if the management was a continuous attempt to conserve and restore the original functioning of the natural ecosystem. In contrast, other management strategies that neglect aquaculture and hunting to focus on enhancement for recreational activities tend to forget the conservation of some critical functions of these areas and, in the long run, might be detrimental to ESs relevant for the entire lagoon.
Therefore, a broad set of ESs may be sought in the valli da pesca, probably including more than the nine evaluated in this study. However, to harness these ecosystems, maximizing the provisioning ESs for which they were born is preferable. Indeed, as long as extensive aquaculture and hunting are considered important, the valle da pesca is arranged to maintain the peculiarities of a transitional water ecosystem’s landscape and ecological processes. In contrast, when a new kind of profitable management distorts the necessity for such high maintenance, the valli da pesca not only lose the capacity and flow of provisioning ESs, but also lose the landscape characteristics on which the regulating ESs rely, resulting in a lower contribution to the entire lagoon ESs.
In light of these considerations, we must consider that all the challenging and unceasing anthropic interventions aimed at conserving the best condition for the valli da pesca require high intellectual and financial effort.
This poses a long-standing dilemma within Venice lagoon71,72 regarding the legitimacy of the valli da pesca remaining under private management73. If these areas are let under public management, we ensure free and fair public access but may risk losing vital lagoon habitats and, consequently, their regulating and provisioning ESs. On the other hand, allowing private people to maintain them for aquaculture and hunting purposes means ensuring the conservation of regulating and maintenance ESs, along with other ESs, but with the trade-off of a restricted access regime and with the economic advantages that benefit only a few people. Nonetheless, as this work suggests, it is probably because the valli da pesca are under private management that they have maintained the natural ecological processes, along with the landscape features, that make them capable of providing regulating and maintenance ESs.
Therefore, a paradox arises considering that the Venice lagoon ecosystem strongly needs human intervention, mainly privately funded, to conserve its most natural environments and important habitats.
Moreover, in the forecast of ruling the Venice lagoon using mobile barriers to face climate change effects74,75, great attention should be paid to hydrodynamic changes resulting from MOSE barrier functioning. Since the artificially managed ecosystems of the valli da pesca exchange matter and energy with the main water body of the lagoon, they could be affected by reduced tidal energy and lowered quality of their waterfront75,76,77,78,79.
In conclusion, we highlight that not only do the management strategies affect the ESs in the valli da pesca, but also the Venice lagoon governance does. Thus, we suggest that the decision-makers seek an ecosystem-based management approach that considers all parts of the lagoon, including these managed areas, because they provide several ESs to the entire lagoon system and play an important role within the context of the lagoon conservation.
Furthermore, the valli da pesca clearly show the effect of the anthropogenic modifications that have successfully maximized a specific ES while ensuring sustainability and minimizing the trade-offs between exploitation and environment conservation. The knowledge of these study cases80 could inspire the future management of the valli da pesca and can be applied to other similar areas that are part of transitional aquatic ecosystems.
Methods
The valli da pesca of the Venice lagoon deliver several Ecosystem Services (ESs). In this study, we focused on “regulating & maintenance”, “provisioning”, and “cultural” ESs categories, as defined by the CICES framework nomenclature41. The analysis was based on the update of the first spatially explicit assessment of 9 Ecosystem Services: climate regulation, water purification, and lifecycle support (regulating and maintenance ESs); aquaculture production, waterfowl hunting, and wild food and honey (provisioning ESs); tourism, information for cognitive development, and birdwatching (cultural ESs). ESs indicators are reported in Table 2.
The ESs assessment was conducted quantifying both “capacity” and “flow”, to evaluate simultaneously the capability of these artificial ecosystems to provide ESs andhe actual amount of ESs they provide to the society42.
The spatially explicit evaluation of the capacity and flow of ESs required collecting and processing data from the literature, official harvest and sales records, and quantitative information on the presence of visitors, according to the methods already implemented by Rova et al.81 and Stocco et al.40, as detailed in the following paragraphs.
Ecosystem Services assessment methods
Regulating and maintenance ESs
The estimation of sequestered carbon in the valli da pesca was considered a proxy for the climate regulation ES. We referred to the annual carbon sequestration by common reed stands82,83, vegetated saltmarshes accretion84,85, and seagrass meadows86,87,88,89.
The geographical location of these elements was first determined in 2019 through field surveys in 6 valli da pesca (within areas n. 1, n. 5, n. 10, n. 11, n. 20, n. 21). Then, using regression models, we identified the predictive reflectance values in the R, G, B bands to infer the filtering threshold for the aerial photograms granted by Regione Veneto. The resulting raster maps, with 25 × 25 m resolution, allowed for the detection of saltmarshes, reed stands, and seagrass meadows in the other valli da pesca, where a field survey was not achievable. Each patch extension in m2 was associated with its carbon sequestration value, according to the literature 82,83. For seagrass meadows, the additional contribution to carbon immobilization due to carbon deposition from microcalcareous epiphytic seaweeds90 was considered.
According to the literature, the capacity and flow indicators of climate regulation ESs are considered equivalent because they occur at the same location91,92.
To assess the water purification ES, we considered nitrogen removal potential67,93,94. We evaluated nitrogen removal in the brackish water basins of the valli da pesca, based on the chemical monitoring of Italian valli da pesca reported by Ravagnan32. The capacity and flow were considered equivalent according to the literature91,92.
To assess lifecycle support capacity, we focused on the migration patterns of both fish and waterbirds because of the well-known role of the valli da pesca in fish and waterbird migration34,35,36,37,95,96,97. The capacity indicator is expressed on a 0–1 normalized scale, where 0 stands for “no potential support” and 1 stands for “maximum potential support”.
To evaluate the support for fish lifecycle, areas with suitable characteristics for effective fish migration were detected based on the result of an Ecosim-Ecopath with Ecospace food-web model, recently spatialized for the Venice lagoon98.
To evaluate the support for migratory waterbirds, we mapped the factors that foster the attractiveness of resting and molt changes by adding the positive contribution of saltmarshes, freshwater, shrubs, and herbaceous vegetation99,100,101. Both support contributions were aggregated with map-algebra operations and normalized to a 0–1 scale.
The lifecycle support ES flow for fish refers to the actual fish biomass sown per hectare (kg/ha/y), as declared by each manager, who decides which species and how much fish to seed based on the potential amount of biomass sustained by the valle da pesca, the availability of fry, and economic factors. The lifecycle support ES flow for waterbird was estimated by calculating the average number of migratory waterbirds that regularly winter within the valli da pesca, calculated from the waterbird annual censuses performed from 2010 to 202097. Resulting lifecycle support flow indicators were normalized to a 0–1 scale and summed to represent an aggregated indicator.
Provisioning ecosystem services
The aquaculture ES capacity was estimated as the potential biomass density that can be grown (kg/ha/y) according to the food web model of the Venice lagoon98. The flow was expressed as average fish catches per hectare of brackish water surfaces per year (kg/ha/y), according to 2010–2019 official data (granted by Regione Veneto).
The capacity of waterfowl hunting ES was evaluated from the geospatial interpolation of the presence of huntable waterfowl, extracted from the annual waterbird censuses from 2010 to 202097. The hunting flow is the actual waterbird catch per hectare per year, as recorded in the hunting registers of each valle da pesca from 2010 to 2020.
Wild food ES takes into consideration the edible wild plants of the genus Salicornia and the honey that can be obtained from the flowers of sea lavender (a halophytic plant of the genus Limonium).
To locate halophytic vegetation patches, we filtered a series of Worldview-2A satellite images of the study area through a range of annual NDVI averages. The goodness of fit of the detection algorithm was assessed by comparison with vegetational patches, geolocated and analyzed using the visual census method in two different valli da pesca (areas 1 and 8). The spatialized patches were associated with the expected kilograms of Salicornia biomass that could potentially be harvested in the valli da pesca per year102. Potential honey production was estimated by considering grams of honey potentially produced per unit area covered by sea lavender flowers103.
Wild food ES flow refers to the kilograms of harvested plants and honey: edible plants harvesting data were obtained by local market data and interviews to 14 food & beverage companies, while the amount of the produced sea-lavender honey was quantified through interviews to 6 beekeepers.
Cultural ecosystem services
The tourism ES capacity is expressed in terms tourists’ attractiveness. To evaluate it with the spatially explicit approach, we mapped the attractiveness factors witnessed by tourists during a survey conducted in 2019. The most important elements that were ranked were saltmarshes presence, fauna occurrence, good water quality, and visual proximity of natural terrestrial habitats. Each element was weighted to depict the interests declared by the people and normalized to a 0–1 scale index.
Tourism flow is the number of people who, during a year, have spent at least one night in one of the accommodation facilities within the valli da pesca.
The assessment of the capacity for information for cognitive development ES made use of the natural factors that enhance touristic attractiveness, mapped along with inclusivity for people with disabilities. The resulting map was normalized to a 0–1 scale. The flow indicator is the number of persons that attend outdoor educational activities or guided one-day trips annually, as reported by 2 touristic guides and 4 associations (ATN Laguna Sud, Cooperativa Limosa, Ente di promozione turistica di Cavallino Treporti, Oasi WWF Valle Averto).
Birdwatching ES capacity was expressed as birdwatching attractiveness evaluated by 30 interviewed birdwatchers. Spatialization was obtained by mapping the factors that are considered important by birdwatchers, namely the presence of pedestrian paths, saltmarshes presence, nesting areas within the visual field, and the probability of observing birds. The birdwatching flow indicator is the mean number of active birdwatchers retrieved from the 2010–2020 activity trends recorded in the Italian birdwatchers’ database104.
Identification of management groups and classification
The manager of each valle da pesca manages it as his (or her) own enterprise and makes decisions about rules, business, and maintenance interventions to be implemented in the valle da pesca73. Hence, managers were the main source of information and data about aquaculture, hunting, and touristic activities carried out in the privately managed valli da pesca, which were retrieved through 54 interviews. During the interviews, we collected information about the principal ES on which the management relied, the periodic anthropogenic interventions, and the rules regarding access in the valle da pesca. Data on fish seeding, fish production, hunting catches, herbs and honey harvesting, and tourist and excursionists hosted per year in the valle da pesca were also collected.
For data regarding the valli da pesca that are no longer managed, we reviewed the available literature31,105 and asked the Veneto Region, local police, and ecotourism guides through 12 interviews.
ESs aggregated indicators and landscape indicators
The obtained ESs indicators were normalized through min–max value-based normalization106,107 on a 0–1 scale, to allow algebraic operations within each category. We then calculated the aggregated capacity indicators as a sum of the normalized capacity indicators and the aggregated flow as the sum of normalized flow indicators within each ESs category.
To explore whether a relationship exists between landscape and ESs delivery, a highly detailed land cover map was created to identify the landscape arrangement. To obtain this, we applied the European Space Agency restricted access data program asking for very high-resolution satellite scenes, collected by Worldview-02, Worldview-03, and GeoEye-01 satellite constellation. A scalable-boosting decision tree algorithm108 was applied to classify the multi-spectral images, considering 4 land cover classes: terrestrial land, saltmarshes, brackish water, and freshwater.
The area covered by the classes in each valle da pesca was retrieved through map algebra analyses. Then we calculated several landscape indicators, as reported in Table 3, to mathematically describe the landscape features that characterize the valli da pesca. As ratios, the indicators are dimensionless quantities, except for the saltmarshes perimeter/total area ratio, which is expressed in km/km2.
We tested our data for normality using the Shapiro–Wilk test and for homoscedasticity using Bartlett’s test. Because the data were distributed differently from a normal distribution, we chose to perform the Kruskal–Wallis H test on ranks to explore whether at least one group was stochastically dominated by other groups109. For significant Kruskal–Wallis test results (p < 0.05), pairwise multiple comparisons among group means were performed using the post-hoc Dunn test110,111. This pointed out the significant pairwise difference in the delivery of ESs categories between different groups of valli da pesca.112.
The same statistical workflow was used to assess the differences between the groups in terms of landscape indicators.
A unique exception to this statistical approach was represented by the cultural ESs capacity indicator, in which data approximated a normal distribution according to the Shapiro–Wilk test; in this case, an ANOVA test with post-hoc exploratory Tukey pairwise test was preferred.
The analyses were performed using the raster113 and fmsb114 packages for the open-source software R 4.1.2115 in RStudio 2021.09.2 environment116. Land cover classification and spatial analyses were performed using R115 integrated with QGIS 3.16.14 Hannover117. To test for correlation between capacity and flow in the same ESs category, and between different categories, we calculated Spearman’s rank correlations between ESs indicators to identify mathematical relationship supporting the hypothesis of finding a link between ESs and landscape arrangements under different artificial management conditions.
Data availability
The datasets generated and analyzed in this study are not publicly available because they contain personal and business data and thus require special conditions to be given to third parties. However, these are available from the corresponding author upon reasonable request.
References
Pérez-Ruzafa, A. et al. Coastal lagoons: “transitional ecosystems” between transitional and coastal waters. J. Coast Conserv. 15, 369–392. https://doi.org/10.1007/s11852-010-0095-2 (2011).
Hopkinson, C. S., Wolanski, E., Cahoon, D. R., Perillo, G. M. E. & Brinson, M. M. Coastal wetlands: A synthesis. In Coastal Wetlands: An Integrated Ecosystem Approach 1–75 (2018). https://doi.org/10.1016/B978-0-444-63893-9.00001-0.
Basso, L., Hendriks, I. & Duarte, C. E. Biological mechanisms supporting adaptation to ocean acidification in coastal ecosystems. Coast. Shelf Sci. 152, A1–A8 (2015).
Barbier, E. B. et al. The value of estuarine and coastal ecosystem services. Ecol. Monogr. 81, 169–193 (2011).
Barbier, E. B. et al. The valuation of ecosystem services. In Biodiversity, Ecosystem Functioning, and Human Wellbeing: An Ecological and Economic Perspective (2009). https://doi.org/10.1093/acprof:oso/9780199547951.003.0018.
Cohen, J. E., Small, C., Mellinger, A., Gallup, J. & Sachs, J. Estimates of coastal populations. Science (1979) 278, 1209–1213. https://doi.org/10.1126/science.278.5341.1209c (1997).
Duarte, C. M., Dennison, W. C., Orth, R. J. W. & Carruthers, T. J. B. The charisma of coastal ecosystems: Addressing the imbalance. Estuaries Coasts 31, 233–238. https://doi.org/10.1007/S12237-008-9038-7 (2008).
You, S., Kim, M., Lee, J. & Chon, J. Coastal landscape planning for improving the value of ecosystem services in coastal areas: Using system dynamics model. Environ. Pollut. 242, 2040–2050. (2018).
Reyers, B. et al. Getting the measure of ecosystem services: A social–ecological approach. Front. Ecol. Environ. 11, 268–273. https://doi.org/10.1890/120144 (2013).
Ledoux, L. & Turner, R. K. Valuing ocean and coastal resources: A review of practical examples and issues for further action. Ocean Coast. Manag. 45, 583–616. https://doi.org/10.1016/S0964-5691(02)00088-1 (2002).
Nobre, A. M. An Ecological and economic assessment methodology for coastal ecosystem management. Environ. Manag. 44, 185–204. https://doi.org/10.1007/s00267-009-9291-y (2009).
Clark, J. R. Coastal Ecosystem Management (Conservation Foundation, 1977).
Housley, R. A., Ammerman, A. J. & McClennen, C. E. That Sinking Feeling: Wetland Investigations of the Origins of Venice, Vol. 4 139–153 (2013). https://doi.org/10.1179/jwa.2004.4.1.139.
Macintosh, D. J. Aquaculture in coastal lagoons. In Elsevier Oceanography Series, Vol. 60 401–442 (1994).
Pauly, D. & Yáñez-Arancibia, A. Chapter 13 Fisheries in Coastal Lagoons. In Elsevier Oceanography Series, vol. 60 377–399 (1994).
Marzano, A. Aquaculture. In Harvesting the Sea 198–233 (2013). https://doi.org/10.1093/ACPROF:OSO/9780199675623.003.0008.
Costa-Pierce, B. A. Aquaculture in Ancient Hawaii. Bioscience 37, 320–331. https://doi.org/10.2307/1310688 (1987).
Cataudella, S., Crosetti, D. & Massa, F. Studies and Reviews No. 95 General Fisheries Commission for the Mediterranean. Mediterranean Coastal Lagoons: Sustainable Management and Interactions Among Aquaculture, Capture Fisheries and the Environment (2015).
Emiroglu, D. & Tolon, T. Fish production and marketing in the Mediterranean Coastal lagoons. New Medit 4 (2003).
Ardizzone, G. D., Cataudella, S. & Rossi, R. Management of Coastal Lagoon-Fisheries and Aquaculture in Italy. FAO Fisheries Technical Paper 293. FAO Fisheries Technical Paper 293. ISBN 92-5-10266-8 293 (1988).
Saleh, M. Capture-based aquaculture of mullets in Egypt. In Capture-Based Aquaculture. Global Overview. FAO Fisheries Technical Paper. No. 508. 109–126 (2008).
Hem, S. & Avit, J. L. B. First results on “Acadja-Enclos” as an extensive aquaculture system (West Africa). Bull. Mar. Sci. 55, 1038–1049 (1994).
Yáñez-Arancibia, A., Lara Domínguez, A. L. & Pauly, D. Coastal lagoons as fish habitats. Elsevier Oceanogr. Ser. 60, 363–376. https://doi.org/10.1016/S0422-9894(08)70017-5 (1994).
Bevilacqua, P. Venezia e le acque: una metafora planetaria (1998).
Granzotto, A., Franzoi, P., Longo, A., Pranovi, F. & Torricelli, P. La pesca nella laguna di Venezia: un percorso di sostenibilità nel recupero delle tradizioni. Lo stato dell’arte. [Fishing in the Lagoon of Venice: a path of sustainability to recover traditions. State of the art.]. Rapporto sullo sviluppo sostenibile, vol. 2 (2001).
Pérez-Ruzafa, A. & Marcos, C. Fisheries in coastal lagoons: An assumed but poorly researched aspect of the ecology and functioning of coastal lagoons. Estuar. Coast. Shelf Sci. 110, 15–31. https://doi.org/10.1016/J.ECSS.2012.05.025 (2012).
Pérez-Ruzafa, A., Pérez-Marcos, M. & Marcos, C. Coastal lagoons in focus: Their environmental and socioeconomic importance. J. Nat. Conserv. 57, 125886. https://doi.org/10.1016/j.jnc.2020.125886 (2020).
Kouassi, A. M. Acadja-enclos: A new improved aquaculture system for a sustainable development in developing world. In Conference: ECOSET 95, 29 octobre-2 novembre 1995, Tokyo (Japon). Japan International Marine Science and Technology Federation-Proceedings (1995).
Arabatzis, G. D. & Kokkinakis, A. K. Typology of the lagoons of Northern Greece according to their environmental characteristics and fisheries production. Oper. Res. 5(1), 21–34 (2005).
Tsihrintzis, V. A., Sylaios, G. K., Sidiropoulou, M. & Koutrakis, E. T. Hydrodynamic modeling and management alternatives in a Mediterranean, fishery exploited, coastal lagoon. Aquac. Eng. 36, 310–324 (2007).
Bullo, G. Le valli salse da pesca e la vallicultura (1940).
Ravagnan, G. Vallicoltura moderna. Proposte operative per la ristrutturazione e lo sviluppo della itticoltura salmastra italiana. Edagricole (1982).
Lumare, F. Italian valliculture and its future development. In CIESM Congress. https://ciesm.org/online/archives/abstracts/pdf/28/CIESM_Congress_1982_Cannes_article_0258.pdf (1982).
Scarton, F. Long-term trend of the waterbird community breeding in a heavily man-modified coastal lagoon: The case of the important bird area “Lagoon of Venice”. J. Coast. Conserv. 21, 35–45. https://doi.org/10.1016/j.jnc.2020.125886 (2017).
Scarton, F. & Bon, M. Gli uccelli acquatici svernanti nella laguna di Venezia nel periodo 1993–2007: analisi delle dinamiche temporali e spaziali. Avocetta (2009).
Cavraro, F., Zucchetta, M., Malavasi, S. & Franzoi, P. Small creeks in a big lagoon: The importance of marginal habitats for fish populations. Ecol. Eng. 99, 228–237. https://doi.org/10.1016/j.ecoleng.2016.11.045 (2017).
Zucchetta, M., Capoccioni, F., Franzoi, P., Ciccotti, E. & Leone, C. Fish response to multiple anthropogenic stressors in Mediterranean coastal lagoons: A comparative study of the role of different management strategies. Water (Basel) 13, 130 (2021).
Costanza, R. et al. The value of the world’s ecosystem services and natural capital. Nature 387, 253–260. https://doi.org/10.1038/387253a0 (1997).
Müller, F., Fohrer, N. & Chicharo, L. The basic ideas of the ecosystem service concept. In Ecosystem Services and River Basin Ecohydrology 7–33 (2015). https://doi.org/10.1007/978-94-017-9846-4_2.
Stocco, A. et al. Like Little Lagoons: The Contribution of Valli da Pesca to the Ecosystem Services Supply of the Venice Lagoon. Estuaries and Coasts. 46, 616–629. https://doi.org/10.1007/s12237-023-01168-z (2023).
CICES. Applications of CICES. https://cices.eu/applications-of-cices/ (2018).
Villamagna, A. M., Angermeier, P. L. & Bennett, E. M. Capacity, pressure, demand, and flow: A conceptual framework for analyzing ecosystem service provision and delivery. Ecol. Complex. 15, 114–121. https://doi.org/10.1016/j.ecoleng.2016.11.045 (2013).
Rova, S., Müller, F., Meire, P. & Pranovi, F. Sustainability perspectives and spatial patterns of multiple ecosystem services in the Venice lagoon: Possible roles in the implementation of the EU Water Framework Directive. Ecol. Indic. 98, 556–567 (2019).
Cataudella, S. & Bronzi, P. Acquacoltura responsabile. Verso le produzioni acquatiche del terzo millennio. 1–42 (2001).
Brummett, R. E. & Costa-Pierce, B. A. Village-based aquaculture ecosystems as a model for sustainable aquaculture development in Sub-Saharan Africa. In Ecological Aquaculture 143–160 (2007). https://doi.org/10.1002/9780470995051.CH7.
Costa Pierce, B. A. Ecological aquaculture. Ecol. Aquac. https://doi.org/10.1002/9780470995051 (2002).
Cross, D. Reclaiming saline soils using aquaculture: a new approach to an old problem. Appropr. Technol. 8, 4–6 (1981).
Fortibuoni, T., Gertwagen, R., Giovanardi, O. & Raicevich, S. The progressive deregulation of fishery management in the Venetian lagoon after the fall of the Repubblica Serenissima: Food for thought on sustainability. Global Bioethics 25(1), 42–55. https://doi.org/10.1080/11287462.2014.894707 (2014).
Gaglio, M. et al. Ecosystem services approach for sustainable governance in a brackish water lagoon used for aquaculture. J. Environ. Plan. Manage. 62, 1501–1524. https://doi.org/10.1080/09640568.2019.1581602 (2019).
Lanzoni, M., Gaglio, M., Gavioli, A., Fano, E. A. & Castaldelli, G. Seasonal variation of functional traits in the fish community in a Brackish lagoon of the Po River Delta (Northern Italy). Water 13(5), 679. https://doi.org/10.3390/w13050679 (2021).
Avault, J. W. Fundamentals of aquaculture: A step-by-step guide to commercial aquaculture. 889 (1996).
Anras, L. et al. The current status of extensive and semi-intensive aquaculture practices in Southern Europe. Aquac. Europe 35, 12–16 (2010).
Aschonitis, V. G. et al. Land use change effects on ecosystem services of river deltas and coastal wetlands: Case study in Volano–Mesola–Goro in Po river delta (Italy). Wetl. Ecol. Manag. https://doi.org/10.1007/s11273-016-9503-1 (2016).
Ravagnan, G. Vallicoltura Integrata (Edagricole, 2001).
D’Alpaos, L. Evoluzione dei rapporti idraulici tra la laguna di Venezia e le sue valli da pesca. Istituto Veneto di Scienze, Lettere ed Arti (2011).
Barbiero, G. & Berto, R. From biophilia to naturalist intelligence passing through perceived restorativeness and connection to nature. Ann. Rev. Res. https://doi.org/10.19080/ARR.2018.03.555604 (2018).
The, D., Bai, X., Li, X. & Yan, D. The perceived restorativeness of outdoor spatial characteristics for high school adolescents: A case study from China. Int. J. Environ. Res. Public Health 19, 7156 (2022).
Qi, Y., Fang, X., Gao, T. & Qiu, L. The effects of artificial lake space on satisfaction and restorativeness of the overall environment and soundscape in Urban parks. Front. Built. Environ. 7, 56. https://doi.org/10.3389/fbuil.2021.664442 (2021).
White, M. et al. Blue space: The importance of water for preference, affect, and restorativeness ratings of natural and built scenes. J. Environ. Psychol. 30, 482–493. https://doi.org/10.1016/j.jenvp.2010.04.004 (2010).
Froehlich, H. E., Gentry, R. R. & Halpern, B. S. Conservation aquaculture: Shifting the narrative and paradigm of aquaculture’s role in resource management. Biol. Conserv. 215, 162–168. https://doi.org/10.1016/j.biocon.2017.09.012 (2017).
Walton, M. E. M. et al. A model for the future: Ecosystem services provided by the aquaculture activities of Veta la Palma Southern Spain. Aquaculture 448, 382–390. https://doi.org/10.1016/j.aquaculture.2015.06.017 (2015).
Walton, M. E. M. et al. The effect of water management on extensive aquaculture food webs in the reconstructed wetlands of the Doñana Natural Park, Southern Spain. Aquaculture 448, 451–463. https://doi.org/10.1016/j.aquaculture.2015.06.011 (2015).
Gamito, S. Sustainable management of a coastal lagoonal system (Ria Formosa, Portugal): An ecological model for extensive aquaculture. Int. J. Salt Lake Res. 6(2), 145–173. https://doi.org/10.1007/BF02441891 (1997).
Campagne, C. S., Roche, P. K. & Salles, J. M. Looking into Pandora’s Box: Ecosystem disservices assessment and correlations with ecosystem services. Ecosyst. Serv. 30, 126–136. https://doi.org/10.1016/j.ecoser.2018.02.005 (2018).
Smith, A. C. et al. How natural capital delivers ecosystem services: A typology derived from a systematic review. Ecosyst. Serv. 26, 111–126. https://doi.org/10.1016/j.ecoser.2017.06.006 (2017).
Lee, H. & Lautenbach, S. A quantitative review of relationships between ecosystem services. Ecol. Indic. 66, 340–351. https://doi.org/10.1016/j.ecolind.2016.02.004 (2016).
Grizzetti, B. et al. Relationship between ecological condition and ecosystem services in European rivers, lakes and coastal waters. Sci. Total Environ. 671, 452–465. https://doi.org/10.1016/j.scitotenv.2019.03.155 (2019).
Sorokin, Y. I., Sorokin, P. Y. & Ravagnan, G. Analysis of lagoonal ecosystems in the Po River Delta associated with intensive aquaculture. Estuar. Coast. Shelf Sci. 48, 325–341. https://doi.org/10.1006/ecss.1998.0423 (1999).
Sorokin, Y. I., Sorokin, P. Y. & Ravagnan, G. Hypereutrophication events in the Ca’Pisani lagoons associated with intensive aquaculture. Hydrobiologia 571, 1–15. https://doi.org/10.1007/s10750-006-0250-9 (2006).
Day, J. W., Scarton, F., Rismondo, A. & Are, D. Rapid deterioration of a salt marsh in Venice Lagoon, Italy. Source J. Coast. Res. 14, 583–590 (1998).
Crismani, A. Property Functional to Community Interest: the Case of the Venice Lagoon and its Fish Farms. In Rivista del Diritto della Navigazione 23–49 (2011).
Longhin, elvi. Le valli della Laguna di Venezia: da pubblico demanio a privato dominio? (Provincia di Venezia, Settore Politiche Ambientali, Venezia, 2004).
Laffaille, F. Biens publics, biens communs, fonction sociale de l’État. La lagune de Venise et le statut des Valli salse di pesca. Revue internationale de droit comparé 68, 681–698 (2016).
Chapman, P. M. Management of coastal lagoons under climate change. Estuar. Coast. Shelf Sci. 110, 32–35. https://doi.org/10.1016/j.ecss.2012.01.010 (2012).
Ghezzo, M., Guerzoni, S., Cucco, A. & Umgiesser, G. Changes in Venice Lagoon dynamics due to construction of mobile barriers. Coast. Eng. 57, 694–708. https://doi.org/10.5194/nhess-21-2633-2021 (2010).
Umgiesser, G. The impact of operating the mobile barriers in Venice (MOSE) under climate change. J. Nat. Conserv. 54, 125783. https://doi.org/10.1016/j.jnc.2019.125783 (2020).
Umgiesser, G. & Matticchio, B. Simulating the mobile barrier (MOSE) operation in the Venice Lagoon, Italy: Global sea level rise and its implication for navigation. Ocean Dyn. 56, 320–332. https://doi.org/10.1007/s10236-006-0071-4 (2006).
Lionello, P., Nicholls, R. J., Umgiesser, G. & Zanchettin, D. Venice flooding and sea level: Past evolution, present issues, and future projections (introduction to the special issue). Nat. Hazard. 21, 2633–2641. https://doi.org/10.5194/nhess-21-2633-2021 (2021).
Zanchettin, D. et al. Sea-level rise in Venice: Historic and future trends (review article). Nat. Hazard. 21, 2643–2678. https://doi.org/10.2307/1352509 (2021).
Sarabi, S., Han, Q., de Vries, B. & Romme, A. G. L. Methodology for development of an expert system to derive knowledge from existing nature-based solutions experiences. MethodsX https://doi.org/10.1016/J.MEX.2022.101978 (2022).
Rova, S., Stocco, A. & Pranovi, F. Ecosystem services’ capacity and flow in the Venice Lagoon and the relationship with ecological status. One Ecosyst. 7, e79715. https://doi.org/10.1016/S0304-3770(98)00064-3 (2022).
Soetaert, K. et al. Modeling growth and carbon allocation in two reed beds (Phragmites australis) in the Scheldt estuary. Aquat. Bot. 3, 211–234. https://doi.org/10.1016/j.aquabot.2004.02.001 (2004).
Zhou, L., Zhou, G. & Jia, Q. Annual cycle of CO2 exchange over a reed (Phragmites australis) wetland in Northeast China. Aquat. Bot. 91, 91–98 (2009).
Boumans, R. M. J. & Day, J. W. High precision measurements of sediment elevation in shallow coastal areas using a sedimentation-erosion table. Estuaries 16, 375–380. https://doi.org/10.2307/1352509 (1993).
Day, J. W., Rismondo, A., Scarton, F., Are, D. & Cecconi, G. Relative sea level rise and Venice lagoon wetlands. J. Coast. Conserv. 4, 27–34. https://doi.org/10.1007/BF02806486 (1998).
Sfriso, A. & Francesco Ghetti, P. Seasonal variation in biomass, morphometric parameters and production of seagrasses in the lagoon of Venice. Aquat. Bot. 61, 207–223. https://doi.org/10.1016/S0304-3770(98)00064-3 (1998).
Sfriso, A. & Marcomini, A. Macrophyte production in a shallow coastal lagoon. Part II: Coupling with sediment, SPM and tissue carbon, nitrogen and phosphorus concentrations. Mar. Environ. Res. https://doi.org/10.1016/S0141-1136(98)00122-6 (1999).
Sfriso, A., Facca, C. & Ceoldo, S. Growth and net production of the seagrass Nanozostera noltii (Hornemman) Tomlinson et Posluzny in Venice lagoon. Sci. Res. Safeguard. Venice 2007(1), 281–291 (2007).
Sfriso, A. & Facca, C. Nanozostera noltii growth and production in the lagoon of Venice. Biol. Mar. Mediterr. 14, 326–327 (2007).
Sfriso, A. et al. Microcalcareous seaweeds as sentinels of trophic changes and CO2 trapping in transitional water systems. Ecol. Indic. 118, 106692. https://doi.org/10.1016/j.ecolind.2020.106692 (2020).
Schröter, M., Barton, D. N., Remme, R. P. & Hein, L. Accounting for capacity and flow of ecosystem services: A conceptual model and a case study for Telemark, Norway. Ecol. Indic. 36, 539–551. https://doi.org/10.1016/j.ecolind.2013.09.018 (2014).
Schröter, M., Remme, R. P., Sumarga, E., Barton, D. N. & Hein, L. Lessons learned for spatial modelling of ecosystem services in support of ecosystem accounting. Ecosyst. Serv. 13, 64–69. https://doi.org/10.1016/j.ecoser.2014.07.003 (2015).
Sousa, A. I., Lillebø, A. I., Risgaard-Petersen, N., Pardal, M. A. & Caçador, I. Denitrification: An ecosystem service provided by salt marshes. Mar. Ecol. Prog. Ser. 448, 79–92. https://doi.org/10.3354/meps09526 (2012).
Soana, E., Gavioli, A., Tamburini, E., Fano, E. A. & Castaldelli, G. To mow or not to mow: Reed biofilms as denitrification hotspots in drainage canals. Ecol. Eng. 113, 1–10. https://doi.org/10.1016/j.ecoleng.2017.12.029 (2018).
Zucchetta, M., Franco, A., Torricelli, P. & Franzoi, P. Habitat distribution model for European flounder juveniles in the Venice lagoon. J. Sea Res. 64, 133–144. https://doi.org/10.1016/j.seares.2009.12.003 (2010).
Scapin, L., Zucchetta, M., Pranovi, F. & Franzoi, P. Influence of seascape on coastal lagoon fisheries: The role of habitat mosaic in the Venice lagoon. Estuaries Coasts 45, 793–811. https://doi.org/10.1007/s12237-021-00986-3 (2022).
Associazione Faunisti Veneti As.Fa.Ve. A.P.S. Censimento Degli Uccelli Acquatici Svernanti in Provincia Di Venezia. https://www.faunistiveneti.it/ (2020).
Anelli Monti, M. et al. Ecosystem functioning and ecological status in the Venice lagoon, which relationships?. Ecol. Indic. 133, 108461. https://doi.org/10.1016/j.ecolind.2021.108461 (2021).
Korschgen, C., George, L. & Green, W. L. Disturbance of diving ducks by boaters on a migrational staging area. Wildl. Soc. Bull. (1973-2006) 13(3), 290–296 (1985).
Arzel, C. & Guillemain, M. Ecology of spring-migrating Anatidae: A review. J. Ornithol. https://doi.org/10.1007/s10336-006-0054-8 (2006).
Hatziiordanou, L. et al. Indicators for mapping and assessment of ecosystem condition and of the ecosystem service habitat maintenance in support of the EU biodiversity strategy to 2020. One Ecosyst. 4, e32704. https://doi.org/10.1126/science.278.5341.1209c (2019).
Scarton, F., Day, J. W. & Rismondo, A. Primary production and decomposition of Sarcocornia fruticosa (L.) Scott and Phragmites australis Trin. Ex Steudel in the Po Delta, Italy. Estuaries 25, 325–336. https://doi.org/10.1007/BF02695977 (2002).
Fantinato, E. & Buffa, G. Animal-mediated interactions for pollination in saltmarsh communities. Plant Sociol. 56, 35–42 (2019).
CISO, LIPU & EBN Italia. www.ornitho.it. https://www.ornitho.it/.
D’Alpaos, L. L’evoluzione Morfologica Della Laguna di Venezia Attraverso la Lettura di Alcune Mappe Storiche e Delle Sue Carte Idrografiche (Comune di Venezia, 2010).
Singh, D. & Singh, B. Investigating the impact of data normalization on classification performance. Appl. Soft. Comput. 97, 105524 (2020).
Han, J., Pei, J. & Kamber, M. Data mining: Concepts and techniques (2011).
Chen, T. & Guestrin, C. XGBoost. In Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining vols 13-17-Augu 785–794 (ACM, 2016).
Kruskal, W. H. & Wallis, W. A. Use of ranks in one-criterion variance analysis. J. Am. Stat. Assoc. 47, 583–621 (1952).
Dunn, O. J. Multiple comparisons among means. J. Am. Stat. Assoc. 56, 52–64 (1961).
Dunn, O. J. Multiple comparisons using rank sums. Technometrics 6, 241–252 (1964).
Egoh, B. et al. Mapping ecosystem services for planning and management. Agric. Ecosyst. Environ. 127, 135–140. https://doi.org/10.3389/fbuil.2021.664442 (2008).
Hijmans, R. J. raster: Geographic Data Analysis and Modeling. R package version 3.5-15. https://CRAN.R-project.org/package=raster. Preprint at (2022).
Nakazawa, M. fmsb: Functions for Medical Statistics Book with some Demographic Data. R package version 0.7.3. https://CRAN.R-project.org/package=fmsb. Preprint at (2022).
R Core team. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. https://www.r-project.org/ (2022).
RStudio Team. RStudio. (2021).
QGIS Association: QGIS Geographic Information System. QGIS. http://www.qgis.org (2022).
Acknowledgements
This scientific work has been developed in the context of the “Venezia 2021” project, with the contribution of Provveditorato Interregionale Opere Pubbliche per il Veneto, Trentino Alto Adige, and Friuli Venezia Giulia through the Consorzio Venezia Nuova and coordinated by CORILA.
The authors thank Prof. Davide Zanchettin for his helpful suggestions.
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A.S. and F.P. conceived and designed the study and methodology; A.S. collected the data, performed the analysis, wrote and reviewed the original draft; F.P. supervised writing and editing the final draft.
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Stocco, A., Pranovi, F. The paradoxical need for human intervention in the conservation of natural environments in Venice lagoon. Sci Rep 13, 6798 (2023). https://doi.org/10.1038/s41598-023-33754-3
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DOI: https://doi.org/10.1038/s41598-023-33754-3
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