Sea Level Rise and Coastal Impacts: Innovation and Improvement of the Local Urban Plan for a Climate-Proof Adaptation Strategy

: In recent years, the territorial impacts connected to sea level rise have prompted a reﬂection on the responsibilities of policy makers in transposing these issues into urban agendas. The need also emerged to both broaden and update the skills of urban planners and to improve territorial governance tools, with the aim of developing feasible regeneration and resilience strategies to face climate change. In this paper, a methodology for the production of Flood Risk Maps is presented, as applied to the Municipality of Ravenna, Italy, by only considering the static component of inundation hazard, i.e., the projected Mean Sea Level Rise, as a ﬁrst step towards increased preparedness. The resulting Flood Risk Maps represent, in fact, an innovation with respect to the current cognitive framework that supports local urban planning, by providing information on a potential risk that has so far been overlooked. The method combines sea level rise projections under the pessimistic RCP8.5 scenario with georeferenced territorial data, aiming to identify the physical consistency of the urban-structure components which are potentially at risk. For successive time horizons (2030, 2050 and 2100), our results show the progressive impairment and potential degradation of extensive urban areas that are disregarded in the urban planning regulations currently in force. This preliminary evaluation phase is aimed at prompting and supporting the necessary updating of the planning tools and regulations adopted by the public bodies responsible for territorial governance, by identifying priority areas for intervention, and helping deﬁne mitigation and adaptation actions.


Climate Change and Urban Regeneration Strategies
The increasing frequency of climate change-related extreme events observed in recent decades is nowadays at the center of the scientific debate and represents one of the key issues of urban planning research. These changes undoubtedly represent one of the major challenges that the global risk society [1] will have to face, both for their expected impact on cities and territories, and for the consequent economic, social and environmental damages already highlighted by empirical evidences.
As widely recognized in the reports of the International Panel for Climate Change (IPPC), due to their higher population density, urban and metropolitan areas are, at the same time, liable to be the most exposed and vulnerable to multiple risks [2] and the most responsible for excessive CO 2 emissions from anthropogenic activities (mobility, residence, production activities, etc.), a condition that is further worsened by the frequent absence or ineffectiveness of urban planning [3,4]. The relevance of the topic and the need to identify new paradigms for the sustainable transformation of the threatened territories are also

•
The strategic dimension, i.e., promoting the development of local agendas, that provide the definition of short, medium and long-term strategic plans according to the vision of the administration, also in terms of adaptation to climate change; relevant examples, in the international context, can be found in Vejle's Resilient Strategy (2013) [39], Rotterdam Climate Change Adaptation Strategy (2013) [40], One NYC 2050. Building a strong and fair city (2019) [41]; • The experimental dimension, i.e., implementing participated pilot actions and programs, validating their effectiveness, incorporating best practices into local regulations and exporting solutions to broader/different contexts.
These two complementary directions originate from the well-known dichotomy between the traditional top-down/prediction-first approach, where measured design and implementation is preceded by a multi-criteria analysis of cost-effectiveness, and the innovative bottom-up/policy-driven/experience-based approach, which inverts the traditional top-down framework, by assessing the robustness of policy options under a broader range of future scenarios than that predicted by a limited set of mathematical models, thus shifting from the design of optimal solutions, to the identification of measures that satisfactorily perform under different conditions and assumptions, allowing for considerable uncertainty and variety in the external constraints [42][43][44][45][46][47][48][49][50][51][52].
In the Italian national context, however, these issues have been only marginally addressed, and few isolated pilot experiments so far undertook the difficult task of accounting for the projected SLR in spatial planning tools and design techniques, also due to the complex regulative framework prescribed by the national rules.
From the administrative and regulative point of view, the Local Urban Plan (Piano Urbanistico Locale) constitutes the main reference for any intervention on the territory, so that the implementation of any new approach to territorial management can exclusively stem from its foresighted redaction. The possibility of implementing climate change mitigation and adaptation measures is therefore directly linked to the willingness of public authorities to incorporate new perspectives into the update process, broadening their knowledge basis as to potential climate change impacts, and to identify the exposed areas, assess their vulnerability and finally, provide actionable guidelines and directives for risk reduction [53,54]. Increased public awareness plays a crucial role in determining such a paradigm shift [55,56].
Nevertheless, a few instances of preliminary efforts can be found as to both the strategic and experimental dimension: The Strategic Metropolitan Plans of Genoa [57], Venice [58] and Milan [59], issued in 2017, 2018 and 2019, respectively, and the case study of the Project LIFE16 Veneto Adapt [60]; • Test-case verification of Local Urban Plans, aiming to provide fact-based information for their objective update, with particular reference to feasible and effective adaptation to climate change impacts. The Resilient Padua (Padova Resiliente) and Resilient Mantua (Mantova Resiliente) experiences, in particular, allowed to deliver the Guide for Climate Adaptation, 2016 [61] and 2018 [62], which were coordinated by the Planning Climate Change Lab of the IUAV University of Venice.
On the other hand, SLR impacts have been addressed at the national level by sectorial instruments such as the PAI (Piano di Assetto Idrogeologico-Hydrogeological Stability Plan) and the PGRA (Piano di Gestione del Rischio Alluvioni-Flood Risk Management Plan) [63]. The former aims to regulate new settlements in areas exposed to hydrogeological risk with the specific scope of supporting urban planning, while the latter is more strictly related to the safety of the territory and to civil protection activities [64].
This work, albeit preliminary and still in progress, therefore represents an innovative attempt to identify methodologies and operational frameworks that can effectively enable Italian public administrations to soundly respond to SLR-induced threats to coastal cities, and to better adhere to the principle of climate-proof planning, by implementing innovative management tools [65]. In particular, we will present the first results of the pilot study conducted on the municipality of Ravenna, together with the flood risk maps produced for its seafront, as a first step towards an improved appreciation of the complexity that needs to inspire future municipal planning instruments, and guide the selection of the most suitable interventions. Our approach follows the traditional top-down prediction-first strategy, yet it still represents an improvement with respect to the planning tools that have so far been developed for the city.

Definition of Risk Components
According to the UNDRR Report "Living with risk: a global review of disaster reduction initiatives" (2004) [66], risk is defined as the probability of harmful consequences, or expected loss (of lives, people injured, property, livelihoods, economic activity disrupted or environment damaged) resulting from interactions between natural or human-induced hazards and vulnerable/capable conditions. The reliability of any risk assessment, as well as the effectiveness of adaptation planning, are therefore critically dependent on our ability to project future hazards, to account for the social, economic and environmental vulnerabilities that jointly determine the susceptibility of the exposed elements, and to react to adverse impacts.
In the traditional disaster risk reduction (DRR) framework, risk increases whenever our (often limited) knowledge of the hazard is not translated into effective mitigation or adaptation, or into significant exposure reduction, especially when low-frequency yet high-impact events are considered. Such conceptual understanding is represented by the traditional pseudo-equation for risk, or by any of its variations: Risk = Hazard × Exposure × Vulnerability, or Risk = Probability × Consequence.
Recent research, however, has highlighted the need for a more complex appreciation of the nature of risk, as the overall risk has been recognized to be mainly determined by the coupling of systemic elements, rather than by their accidental superposition [67]. In this new context, while natural hazards can, in principle, be rigorously measured, other components of risk are still the object of extensive trans-disciplinary discussion among a variety of research fields, including social and political sciences, history, economics and engineering [68,69]. It is worth noting that this lively debate in the risk assessment community indeed mirrors the above-mentioned discussion that animates the policy community, and that alternative approaches are being constantly re-designed in a more and more intertwined framework, as they all originate from the growing awareness that idealized decision frameworks clash against the actual capacity and political constraints of the real world and that risk is largely a social construct, depending not only on measurable hazard/exposure/vulnerability components but also on a wide variety of public and private factors that can only be qualitatively appreciated [24,70].
On the other hand, in the context of climate studies, a broad definition of vulnerability was early recognized to be a key element to describe climate change impacts more aptly as the result of a variety of complex interacting processes, rather than as the mere consequences of natural phenomena impacting social communities and systems. Indeed, the 4th IPCC Assessment Report already referred to vulnerability as to the synthesis of multiple inter-connections and feedbacks between traditional risk components [71]. For the sake of transparency and clarity, however, such terminology was then reviewed and harmonized in the Fifth IPCC Assessment Report [6] where the term vulnerability was in fact replaced by the phrase risk of climate change impacts, borrowed from the DRR community, together with the definitions of hazard, vulnerability and exposure which will be used in the following.
Our approach combines the evaluation of the physical hazard and the static assessment of the vulnerability (sensitivity and adaptive capacity) and exposure of the town under study, which, in general, depend on its peculiar geological, environmental and socio-economic characteristics, and on the nature of the exposed elements. The city of Ravenna was selected for our application as it was included among the 33 coastal plains at risk of inundation in [22], and its vulnerability and exposure have been recognized in [30], as part of their analysis of the effects of scale and input data for the Emilia-Romagna Coast. For the selected area, we aim to produce informative maps that allow drawing a systemic, qualitative and quantitative picture of the urban elements at risk. The following analysis is conducted in the classical DRR framework, where exposure is measured by the elevation over current mean sea level and vulnerability by the nature of the elements potentially affected (e.g., beaches, dunes, buildings), while the magnitude of the hazard is given by the expected SLR alone (i.e., not considering subsidence and transient processes/phenomena). The layer corresponding to the three risk components are then overlapped to produce preliminary risk maps, disregarding for the moment any non-linear coupling between risk components, which would, in principle, imply non-null risks also for the inner areas, both physical (e.g., they would no longer be sheltered from extreme storms and/or waves) and socio-economical (e.g., loss of attractiveness due to the degradation of adjacent buildings). As a matter of fact, a thorough analysis of the overall risk implied for the entire urban settlement would require sustained interaction with all the involved stakeholders, including knowledge sharing and continuous verifications of needs and expectations, so as to determine the weights of alternative combinations of risk components [72]. This would only be possible if comprehensive databases were available to design complex vulnerability and exposure indicators, accounting for a variety of factors, such as economic conditions and development, social interdependences, adaptive capacity and technological options. In general, such facilities are neither easily available, when existing, nor even conceivable in most cases for the time being, with further development having therefore to rely on a step-by-step approach in selected pilots. Our effort is in fact intended as an outset along this path.

Climate Change-Induced Hazard Associated to SLR
The extreme sea levels that threaten the coastal environment and economies arise from the superposition of transient extreme events, such as waves and storm surge, and tides onto the relative sea level, thus demanding a comprehensive risk assessment across a range of spatial and temporal scales that demand complex and differentiated approaches [31]. Vousdoukas et al. (2017) [32], in particular, lament the lack of comprehensive projections of extreme sea levels that consistently include sea level, tides, waves, and storm surges. This work, however, only focuses on the sea level rise component, whose quantitative estimate in the Mediterranean Sea already constitutes a scientific challenge, due to the inherent diversity of the geological history of the basin and to the complex features of its marine circulation. In addition, the local sea level is also constrained by the water exchanges across the Strait of Gibraltar, which determine the hydraulic jump between the Mediterranean and the adjacent Atlantic Ocean, while the connection with the Black Sea, through the Dardanelles, Sea of Marmara and the Bosphorus, couples the basin hydrology to the land-based hydrological cycle of a vast portion of continental Europe.
If the contributions from continental glaciers and geologic processes are neglected, RSL is the result of a steric component (i.e., expansion/contraction of the water column due to density variations) and of mass variations arising from convergence/divergence of the mean horizontal velocity, horizontal density advection, and surface freshwater budget. The complexity of the calculation of all these terms is thoroughly described in Jordà and Gomis (2013) [73], with particular reference to the Mediterranean Sea as a paradigmatic example of a semi-enclosed basin where sea level components need to be carefully interpreted. Such difficulties led to a variety of sea level estimates and attribution of changes even under current climate, whose divergence is further enlarged under future scenarios, due to the inherent spread of model projections.
The Mediterranean mean sea level has in fact been observed to deviate from the global values at decadal time scales, exhibiting a decrease in the period 1960-1990, due to a persistent positive anomaly of sea level pressure, then accelerating its increase with respect to the global value, and ending with a stationary period from 2002 onwards [74][75][76][77]. Model simulations show that mass addition has generally been larger than the steric component, yet the thermosteric trend estimated from observations is still affected by large uncertainties, even as to its sign, while consensus has been reached as to the decrease in the halosteric term, despite apparent inconsistencies between available hydrographic datasets [17,73,78,79].
As for future projections of RSL (expansion/contraction of the water column plus the effects of ocean dynamics), even recent works still rely on atmosphere and ocean general circulation model (AOGCMs) outcomes from the CMIP5 Coupled Model Inter-comparison Project (CMIP5), at 1 • × 1 • resolution, to which additional global and regional contributions are added offline [22,31,32]. Although some estimates may choose to neglect the lower order terms, the latter are: (i) the barystatic sea level change, (ii) the GRD-induced sea level change, and (iii) the GIA-induced sea level change. The barystatic sea level rise accounts for water mass transfer from the land to the ocean and has a global effect, while GRD represents the local and instantaneous changes in the geoid and has regional effects, although globally widespread. The GRD includes changes in Earth Gravity, Earth Rotation and viscoelastic solid Earth Deformation. GIA is the Glacial Isostatic Adjustment deriving from the deformation of the Earth's crust in response to changes in ice mass distribution. A considerable spread between model projections characterizes RLS estimates, which by the end of the century and for the area of the North Atlantic in proximity of the Gibraltar Strait (often used to constrain the Mediterranean sterodynamic sea level, as in Thiéblemont et al.  [22] refer to the SLR range of 530-970 mm reported in the IPCC AR5, and to Rahmstorf's semi-empirical estimate of about 1.400 mm for the maximum level reached by 2100 [80], while also presenting a table summarizing possible alternative ranges. As already mentioned, estimates derived from AOGCMs for the interior of the Mediterranean basin are, in general, unreliable due to the insufficient model resolution that impairs the correct representation of the hydraulic control across the Gibraltar Strait and of the local dynamics [81]. In view of the peculiarities of the local sea level response to global warming, for the present study, an alternative approach has been followed and SLR estimates have been derived from a high-resolution regional simulation of the Mediterranean circulation, based on a configuration of the MITgcm that was specifically adapted for the Mediterranean basin [82]. The simulation was driven by the dynamically downscaled regional atmospheric fields produced by the Rossby Centre regional atmospheric model RCA4 [83]. In particular, we used the RCA4 downscaling (0.11-degree resolution, i.e., approx. 12.5 km grid spacing) of the atmospheric component of the CMIP5 global model HadGEM2-ES [84]. The atmospheric downscale was performed over the European domain defined by the Coordinated Regional Downscaling Experiment [85] for the HISTORICAL (1970-2005), RCP-8.5 scenario (2006-2100) and the ERA-INTERIM reanalysis . In the current study, only the RCP-8.5 scenario was considered. The MITgcm model has also been laterally constrained by the conditions applied at the Atlantic Ocean's open boundary. To guarantee consistency with the atmospheric forcing, de-drifted sea level, temperature and salinity fields from the HadGEM2-ES projections were used. Future projected (RCP-8.5) mean values for surface mass balance and dynamic ice sheet from Greenland and Antarctica, and the glacier and land water storage contributions were also added to the sea level variable. In particular, we used data from the Integrated Climate Data Center (ICDC) at Hamburg University. For the pessimistic RCP 8.5 climate change scenario, SLR values (including the local Mediterranean thermosteric component) of 2 cm, 17 cm, and 68 cm were projected for the three time horizons, 2030, 2050, 2100, respectively. Such estimates generally agree with the median values obtained from the GCM-based ensembles, yet they can significantly rise if alternative high-end climate change scenarios are used to drive the regional model.

Presentation of the Case Study
The Emilia-Romagna Region is in the process of defining a regional strategy for climate change mitigation and adaptation, by implementing effective policies for the reduction of greenhouse gas emissions, and by fostering the adoption of effective counter-measures to limit and control the adverse impacts of future climate scenarios. The regional strategy aims to coordinate all the envisaged measures, from the regional to the municipal level, into a unitary, organic, multisectoral and multiscalar vision, which can only be achieved by the homogeneous planning of all the administrative instruments in force, such as the Local Climate Plans, the PAES (i.e., the Regional Landscape Plan) and the Local Adaptation Plans. The latest regional planning law (Disciplina regionale sulla tutela e l'uso del territorio, n. 24 of 21 December 2017) therefore urged local administrations to update their local planning tools in accordance with the overall regional strategy, by acknowledging scientific evidences and best practices, as well as the specific local characteristics.
In the context of the lively interest manifested by regional institutions, the Municipality of Ravenna was then identified as a relevant case study for our analysis, all the more as it has already been included among the Italian areas most exposed to future SLR [22]. Ravenna has 157.731 inhabitants with a population density of 241.25 inhabitants/km 2 , and it is the second largest municipality in Italy by area [86].
The Municipality of Ravenna has started drafting the PUG (General Urban Plan), through a broad and in-depth discussion with all institutional, social and economic actors, after having issued a reference strategic document, Il piano delle azioni consapevoli e integrate (Plan for Conscious and Integrated Action) in 2019 [87]. The latter recommends the construction of Integrated Risks Maps that allow to overlap different informational layers indicating five main goals, in compliance with the two dimensions (strategic and experimental) of the local governance of climate change adaptation: Strategic guidelines and design actions are defined for each goal. SLR is specifically, addressed in Goal 1-Strategic outline LS1, Consolidating and redeveloping the Ravenna coast as a maritime park, which recommends the AP1 Design action, Promoting protection interventions and beach nourishment to respond to the risks of subsidence, liquefaction of the soils, sea level rise and coastal erosion, favoring naturalistic engineering techniques.
Adding to the above mentioned specific issue, the National Guidelines for the defense of coasts from erosion and from the effects of climate change (Linee Guida Nazionali per la difesa della costa dai fenomeni di erosione e dagli effetti dei cambiamenti climatici) [88], constitutes the reference instrument for local intervention planning, which underlines the importance of classifying the areas historically affected by coastal erosion and/or by marine flooding. To this end, the construction of a database of historical storms is indicated as a necessary support instrument for the assessments of current vulnerabilities and their possible evolution, allowing the prevention and management of coastal risks.
For our study, however, we can only refer to the calamitous storm which affected the city of Ravenna in 1979 and caused the first ecological strike in Italy, prompting the birth of the special law against subsidence (10 December 1980, n. 845), finally recognized as a critical local amplifier of relative sea level rise.
On 22 December 1979, the Adriatic Sea flooded the Ravenna waterfront as well as the neighboring towns, particularly in the areas of Marina di Ravenna ( Figure 1) and Lido Adriano. The damage was estimated at around 100 billion of lire in Ravenna alone, which immediately demanded the Government to declare a state of emergency. Bathing facilities, hotels, industries, pine forests and houses were severely damaged [89].

Geodatabase Preparation
In order to produce future potential risk maps, the pessimistic RCP 8.5 scenario was considered, which only allows for a low decrease in greenhouse gas emissions; specifically, reference is made to the first Antarctic scenario, yielding the following values (in cm) for the local sea level rise, in correspondence to the three targeted time horizons (Table 1). In addition, the following territorial information layers were used for the construction of the Flood Risk Maps:  Figure S1), but no reference is made to the contribution of an increasing sea level. It is therefore evident that the intended realization of the maritime park must rely on updated tools that support specific adaptation solutions.

Geodatabase Preparation
In order to produce future potential risk maps, the pessimistic RCP 8.5 scenario was considered, which only allows for a low decrease in greenhouse gas emissions; specifically, reference is made to the first Antarctic scenario, yielding the following values (in cm) for the local sea level rise, in correspondence to the three targeted time horizons (Table 1).  [92]. Table 2 illustrates the additional georeferenced data from the Ravenna OpenData portal [93] that were used for the development of a basic technical cartography of the municipal area, as the first step for the elaboration of the Flood Risk Maps using the Q-GIS 3.10.2 software. The layer describing the coastline was then overlapped, as well as the DEM (Digital Elevation Model) of the analyzed area. The levels corresponding to terrain elevations equal to the SLR projection for each time horizon (2030/2 cm, 2050/17 cm and 2100/68 cm) were then extracted in order to highlight the areas exposed to inundation for the whole extension of Ravenna Municipality. However, only results for the target areas of Marina di Ravenna and Lido Adriano are shown.
Thanks to the Ravenna Urban Planning Service [94], it was possible to export the GEOTIFF file of "Elaborato 3-Spazi e Sistemi del PSC" (Chart 3-Spaces and Systems of Municipal Structural Plan) [95], which allowed to further highlight the systemic components of the urban structure in the target areas ( Figure 2).
Municipality. However, only results for the target areas of Marina di Ravenna and Lido Adriano are shown.
Thanks to the Ravenna Urban Planning Service [94], it was possible to export the GEOTIFF file of "Elaborato 3-Spazi e Sistemi del PSC" (Chart 3-Spaces and Systems of Municipal Structural Plan) [95], which allowed to further highlight the systemic components of the urban structure in the target areas ( Figure 2).

Figures 3 and 4 show the resulting maps for the target areas Marina di Ravenna and
Lido Adriano, respectively, as arising from the superposition of the expected hazard and the ground elevation above current mean sea level (i.e., exposure). At this stage, the information on areas at risk that can be inferred is inherently binary, that is: (a) the area is expected to be submerged under the selected scenario, or (b) it is expected not to.

Figures 3 and 4 show the resulting maps for the target areas Marina di Ravenna and Lido
Adriano, respectively, as arising from the superposition of the expected hazard and the ground elevation above current mean sea level (i.e., exposure). At this stage, the information on areas at risk that can be inferred is inherently binary, that is: (a) the area is expected to be submerged under the selected scenario, or (b) it is expected not to.  [94], it was possible to export the GEOTIFF file of "Elaborato 3-Spazi e Sistemi del PSC" (Chart 3-Spaces and Systems of Municipal Structural Plan) [95], which allowed to further highlight the systemic components of the urban structure in the target areas ( Figure 2).

Figures 3 and 4 show the resulting maps for the target areas Marina di Ravenna and
Lido Adriano, respectively, as arising from the superposition of the expected hazard and the ground elevation above current mean sea level (i.e., exposure). At this stage, the information on areas at risk that can be inferred is inherently binary, that is: (a) the area is expected to be submerged under the selected scenario, or (b) it is expected not to.   The progressive involvement of the two main area types classified in the Ravenna OpenData portal (i.e., Urbanized Areas and Uncovered Areas) can be observed, which is quantified in Table 3 for Marina di Ravenna only. The two different coverage characteristics allow a first evaluation of vulnerability on a qualitative basis. The percentage of flooded area increases from 4% by 2030 to 8% in 2050, up to 25% in 2100, for The progressive involvement of the two main area types classified in the Ravenna OpenData portal (i.e., Urbanized Areas and Uncovered Areas) can be observed, which is quantified in Table 3 for Marina di Ravenna only. The two different coverage characteristics allow a first evaluation of vulnerability on a qualitative basis. The percentage of flooded area increases from 4% by 2030 to 8% in 2050, up to 25% in 2100, for the first coverage type. For the second, it grows from 4% in 2030, to 27% in 2050 up to 43% in 2100. From now on, detailed analysis will focus on Marina di Ravenna only, due to its strategic position and for its crucial role as a tourist port.
By overlapping the polygons obtained with the GEOTIFF from "Elaborate 3-Spaces and Systems of the PSC" (Graph 3-Spaces and Systems of the Municipal Structural Plan), it has been possible to further detail the nature of the urban elements at risk and verify the ability of current urban planning instruments to consistently account for future risks, so as to more effectively support public administrative bodies in implementing cost-effective mitigation/adaptation actions, and in prioritizing intervention according to an objective science-based ranking. For the three time horizons considered, Tables 4-6 report a first classification of urban areas in Marina di Ravenna, together with the correspondent size (mq) of each class, and the absolute and relative (%) extent of the portion that is projected to be submerged. With reference to the bodies responsible for territorial governance, this evaluation phase is aimed at a possible updating of the planning tool forecasts, and is preliminary to the subsequent identification of priority areas of intervention, and to the definition of mitigation and adaptation actions.   Table 6. Urban planning instrument forecasts, in relation to the physical consistency of the areas at risk of flooding by 2100.

Target Area Nomenclature in Legend (PSC Elaborato 3-Spazi e Sistemi)
Total Area (mq)    In Table 7, the affected urban elements were further classified according to three standard systems for territorial analysis: the Environment and Landscape System, the Settlement and Urban Morphology System, and the Infrastructure Endowment and Public Services System. By being more general than the local classification presented in the preceding tables, which depends on the specific nomenclature adopted by each municipality, such aggregation is expected to allow the portability of our approach to different contexts, and help better identify common issues and priorities that should guide national planning choices. The consistent characterization of the whole national territory is indeed dictated by the necessity to concentrate resources on the macro areas that exhibit higher risk scores after objective intercomparison.  Figure 6. Relation between areas exposed to SLR risk by 2050 and prescriptions from the Local Plan. Target area: Marina di Ravenna. Figure 6. Relation between areas exposed to SLR risk by 2050 and prescriptions from the Local Plan. Target area: Marina di Ravenna. For the Ravenna pilot, the components that the local PSC classifies as Natural Area, Rural Area and Environment and Landscape System ("Spazio naturalistico", "Spazio Rurale", "Sistema Paesaggistico Ambientale") were all aggregated and named Environment and Landscape System; the components that fall within the classification of Urban Areas ("Spazio Urbano") were all aggregated as Settlement and Urban Morphology System; the components that fall within the classification of Mobility Systems and Infrastructure Endowments System ("Sistema della mobilità" e "Sistema delle Dotazioni Territoriali") were all aggregated as Infrastructure Endowment and Public Services. Sustainability 2021, 13, x FOR PEER REVIEW 16 of 23 Figure 7. Relation between areas exposed to SLR risk by 2100 and prescriptions from the Local Plan. Target area: Marina di Ravenna. In Table 7, the affected urban elements were further classified according to three standard systems for territorial analysis: the Environment and Landscape System, the Settlement and Urban Morphology System, and the Infrastructure Endowment and Public Services System. By being more general than the local classification presented in the preceding tables, which depends on the specific nomenclature adopted by each municipality, such aggregation is expected to allow the portability of our approach to different contexts, and help better identify common issues and priorities that should guide national planning choices. The consistent characterization of the whole national territory is indeed dictated by the necessity to concentrate resources on the macro areas that exhibit higher risk scores after objective intercomparison.
For the Ravenna pilot, the components that the local PSC classifies as Natural Area, Rural Area and Environment and Landscape System ("Spazio naturalistico", "Spazio Rurale", "Sistema Paesaggistico Ambientale") were all aggregated and named With reference to the 2030 scenario (expected SLR = 2 cm), the aggregated results in Table 7 show that all the areas exposed to flood risk fall within the Environmental and Landscape System, albeit only for a small percentage of the total (7%), mainly represented by the beach belt and random settlements in agricultural areas.
As regards to the 2050 scenario (expected SLR = 17 cm), the areas exposed to flood risk fall within the Environmental and Landscape System and the Settlement and Urban Morphology System, with a percentage of the total area of 24% and 3%, respectively. The first also includes wooded areas and some historical and architectural heritage specimens, while the second covers part of the buildings of the consolidated city intended for residence and mixed activities. Table 7. Summary of data referring to the territorial systems exposed to the risk of flooding. Target area: Marina di Ravenna (2030Ravenna ( , 2050Ravenna ( , 2100.

System
Total Area (mq) Finally, with reference to the 2100 scenario (expected SLR = 68 cm), the areas at risk fall within all three territorial systems (Environmental and Landscape System, Settlement and Urban Morphology System, Infrastructure Endowments and Public Services System), with percentages of each total area of 47%, 35% and 100%. For this scenario, settlements for tourist activities, road infrastructures and part of the port services are also affected, and potential economic losses are expected to significantly increase.
As urban planning regulations mainly govern the Environmental and Landscape System and the Settlement and Urban Morphology System in the short to medium term, this evaluation method can be useful for a first assessment of necessary interventions for the 2030 and 2050 time horizons, helping prioritize site-specific strategies, from the softest mitigation/adaptation measures to the hardest alternative of permanently relocating property, infrastructures and services away from the coast.

Conclusions
This work aims to propose a method for locating, quantifying and characterizing coastal urban areas at risk under the projected sea level rise, that is sufficiently general to be exportable to different contexts, and yet informative and useful for the subsequent steps of the urban planning process. When combined with more detailed information on current land use and on the development strategies envisaged by Local Urban Plans, our preliminary analysis allows to smoothly progress to the planning phase on the score of a fact-based classification and priority ranking, and then to further proceed to design climate change adaptation measures that are best suited for each class of urban elements.
An innovative feature of this work is indeed the choice of the municipality scale as the field of application for climate modeling results, as this scale is the only that can effectively describe the overall physical consistency of the elements of the urban structure, and account for their homogeneity or inhomogeneity. Although the described exercise only constitutes a very preliminary step towards a thorough assessment of SLR-induced risks in the urban environment, the explicit treatment of climate change as a main driver of local adverse impacts itself constitutes a step forward in the evolution of urban planning. For zero-order applications, the results can be linearly combined with complementary assessments of other hazards of natural origin, to yield multi-hazard integrated maps and a wider knowledge base for municipal management.
In the selected test case, the Municipality of Ravenna, the resulting Flood Risk Maps indeed represent an objective innovation with respect to the current PSC cognitive frame-work, by providing information on a potential risk that has so far been overlooked, and by allowing the construction of state-of-the-art, constantly updatable maps that complement those already available, which only account for coastal erosion and subsidence. A first obvious step is to overlap the obtained Flood Risk Maps and the Ravenna PSC.
Future developments include the identification of different intervention categories as a function of the urban components at risk, articulated according to three macro strategies, i.e., defense, adaptation and relocation, with the ambition to set up a reference methodological framework for the implementation of the regulative apparatus of the Local Plan (Norme Tecniche di Attuazione). Such macro strategies are conceptualized through an inductive methodological path, starting from the examination of the best practices in urban design and planning implemented in Italy and Europe, with the aim to merge the top-down approach followed in this work with bottom-up perspectives in a hybrid, highly flexible and collaborative management framework.
In the Ravenna case, as in several other instances over the Italian territory, the everincreasing awareness that new strategies must be designed, and innovative actions implemented, to tackle climate change impacts at the regional and local scale, has often been neutralized by the inertia of administrative bodies in translating such indication into operative urban planning instruments. This is also due to a chronic lack of shared public data in support to territorial management, that from now on must also account for the newly recognized threats in the traditional risk assessment frameworks. It is therefore highly advisable that public authorities supported the construction of comprehensive and exhaustive databases for future risk assessment, so as to release and constantly update as many informative layers as possible, also accounting for more complex dynamic indicators of exposure and vulnerability, as well as for a sizable ensemble of alternative climate and impact projections. The latter, in particular, is essential for an accurate quantification of hazard uncertainty, while the former are crucial for the constant verification of the implemented measures and for robust and dynamic risk assessment. It has in fact been observed that improved climate data often produce wider rather than smaller ranges of uncertainty in their predictions, while local impacts appear to depend more on the sensitivity and relative resilience of a given community than on the magnitude of environmental change. For this reason, a key catalyzer of future urban resilience will definitely be the ability of city managers, economists, sociologists, climatologists and urban planners to multiplicate their mutually re-enforcing efforts in creating a common ground for participative joint programs and projects. The need to blend quantitative and qualitative information, and to root risk assessment in the robust appraisal of complex phenomena, compels experts to overcome the limits of technical information, and to freely build and exploit a wider knowledge platform based on both inter-disciplinary scientific literature and experience, in order to achieve a balanced picture of the challenges posed to urban planning. This effort is not guaranteed to always provide absolute risk quantification, yet it significantly contributes to research advancement by accelerating knowledge exchange, setting the basis for improved future evaluations.