1. Introduction
The current era is defined by the term Anthropocene, which refers to the impact that human activities have had and continue to have on the Earth’s balance. It can be argued that the Anthropocene era began in the late 18th century when measurements on polar glaciers revealed increasing concentrations of carbon dioxide and methane [
1]. Human pressures on the environment have significantly increased, causing escalating greenhouse gas emissions; climate change is a global phenomenon that has a profound impact on urban settlements, territories, and oceans [
2,
3,
4,
5,
6]. Mediterranean cities are vulnerable urban settlements facing multiple challenges and risks related to the effects of climate change [
7]. Moreover, their fragility arises from human pressures and additional stresses due to geopolitical and economic dynamics [
8]. We must aim for sustainable and resilient development capable of reducing vulnerability to various stressors acting on the territory. Climate risk assessment should be a tool to provide screening and potentially establish priority interests among all possible criticalities related to ongoing climatic impacts [
9].
Some studies have dealt with climate change and have defined it as “the effects of extreme weather and climate events and climate change on natural and human systems” [
10], generally referring to the effects on people, livelihoods, health, ecosystems, economic, social and cultural goods and resources, services, and infrastructure due to the interaction of climate change or hazardous climate events occurring within a specific time period, with the vulnerability of a society or system exposed to climate change [
11]. However, this set of indicators is very broad, and there is a need to narrow the analysis field to a more limited system of indicators.
The impacts generated by climate change can have an impact on both natural resources and buildings and infrastructure, as well as the established population [
12]. Climate change and urbanization are among the most pervasive and rapidly growing threats to biodiversity worldwide [
13]. Climate change (CC) and urban heat island (UHI) are two recognized risk factors linked to human impacts that can strongly influence the performance of the built environment by introducing new vulnerability characteristics [
14,
15,
16,
17,
18]. The publication of the paper “A method for the definition of local vulnerability domains to climate changed relate mapping. Two case studies in southern Italy”. Ref. [
12] aims at the quantitative definition of domains of local vulnerability to climate change and their mapping. The authors’ method is based on the definition of vulnerability as a function of the type, magnitude, and rate of climate change to which a system is exposed, its sensitivity, and its ability to adapt.
Some of the various national and international studies and methodologies used to assess local climate vulnerability [
19,
20,
21] have been a valuable reference for the methodological approach presented in this paper. In particular, we consider Formulas (2) and (3) and the AHP method used in the research carried out by Francini et al. [
12] to draw a starting point for the formulas used in this article.
A methodology is implemented to create a rule that, through a scale of numerical values, allows us to classify coastal urban areas according to the risks of climate impact. Using multi-criteria techniques AHP [
22,
23,
24] and information from official sources, we chose climate variables that consider the characteristics of urban settlements to create an equation that allows us to calculate the climate vulnerability index.
The newly created equation relates several variables essential for describing the climate vulnerability index. It will provide a numerical value that represents the vulnerability of an urban settlement on a numerical scale. The numerical quantification of the vulnerability index will allow the subsequent classification of the areas into three bands with low, high, and medium vulnerability indexes. This classification can facilitate the decision-making process for developing management, prevention, defense, adaptation, or mitigation plans based on the climatic risk of the examined urban area [
25]. The climate vulnerability index is essential for the settlements examined [
26,
27,
28]. Therefore, factors such as wind, absolute maximum temperatures, precipitation, and the residential density of the urban area have been considered. These factors have been adjusted by a percentage based on regional data concerning tourist flow in Sicily. Finally, the numerical results of the urban vulnerability index and the subsequent drafting of a ranking determine which urban settlement requires more urgent intervention. This climate vulnerability index enables territorial planning to mitigate the risks associated with climate change in the Sicily region.
This extreme climate change could result in decreased tourism in the warmer months. After calculating the value of the climate vulnerability index, it will be necessary to establish the mitigation and combating climate change measures in progress, and the interventions to be adopted will be commensurate with the climate vulnerability index found [
29,
30]. Therefore, it is necessary for cities to adapt to this new climatic scenario [
31]. This adaptation is significant in settlements whose economic engine is tourism, as in the case of cities that are considered in the present study and present a high influx of tourists [
32]. This work aims to create a reproducible methodology for calculating a climate vulnerability index related to urban settlements of a specific region, and this index can be quantified through a number. Subsequently, using the index results of various urban settlements, a timetable can be drawn up to implement projects aimed at combating and mitigating the effects of climate change referring to the urban settlements along the Mediterranean coasts. Therefore, this will allow the urban settlements of a given Sicilian region to be able to carry out interventions with the priorities related to this index and according to the provisions of the classification band in which the cities fall [
33]. In urban settlements with a tourist vocation, such as Sicily, all comforts must be created for citizens and tourists so that they can enjoy the landscape and stay in open places, especially during the summer months coinciding with the period of greatest heat and climatic discomfort [
34].
4. Discussion
The cities that, according to the calculations of the climate vulnerability index, have a vulnerability index above 0.60 are cities with severe climate-related issues, identified as having extremely high temperatures. For these cities with a climatic index above 0.60, urgent interventions must be planned to mitigate the effects of the climate during the summer months, with priority given to those with a CVI above 0.65; these are typically among the most critical, as we can see with the Palermo city’s higher population densities, magnifying the impact and then the needs for adaptation.
The analysis reflects that there is a progressive increase in temperatures in Sicilian cities, most probably due to climate change. This phenomenon is also associated with a reduction in average rainfall (with an increase in intense rainfall of modest duration, which manifests itself as water bombs) and an increase in extreme wind episodes. Precipitation has recently decreased considerably, and Sicily is increasingly becoming a tropical island.
Sicilian cities are, therefore, facing a climate emergency due to these extreme weather conditions. High temperatures mainly affect the well-being and health of the population; the high maximum temperatures in cities determine the phenomenon known as heat islands.
The data from calculating the climate vulnerability index can serve as the basis for future designs for infrastructure and planning of urban settlements, potentially supporting regulations accounting for this vulnerability index [
26,
45,
46]. Currently, in Italy, there is no legislation on adaptation to climate change [
47,
48], and, therefore, there are no specific objectives set or obligations for regions to adopt a planning tool to address this issue [
49,
50]. Although the National Strategy for Adaptation to Climate Change was approved in 2015, the National Plan for Adaptation to Climate Change (PNACC) was definitively approved in December 2023 to implement the National Strategy for Adaptation to Climate Change (SNAC).
If the pace of increasing greenhouse emissions is not significantly reduced, and knowing that the effects of many of those current emissions would last hundreds and even thousands of years, we can inevitably expect an increase in the climate vulnerability index, and it will be increasingly challenging to create climate adaptation plans for Mediterranean cities. At the Cityfutures 2009 Conference, organized in Milan (Italy) by the Italian Society of Architectural Technology (SITdA) and MADE Expo, topics related to the planning of urban spaces and their ability to adapt were discussed. One of the key takeaways is the role of cities as catalysts for the transformation taking place and that “the priority of cities that are adapting to change has become that of attention to the global climate condition in favor of reducing carbon emissions” [
51,
52,
53,
54]. Contextually, this can lead to increased potential climate impacts, resulting in increased vulnerability of people and cities [
55,
56,
57]. For example, we will see diseases due to the increase in bacteria resulting from adapting these bacteria to climate change in urban settlements. This study provides critical information on how to influence other urban planning processes. The climate vulnerability index can be used, among other things, for infrastructure planning and territorial guidance [
58,
59].
In light of the climate data in the ten cities analyzed, since they all have a climate vulnerability index greater than 0.5, interventions must be carried out to counteract the effects of high temperatures. Therefore, numerous green areas of considerable extension should be provided within Sicilian cities and around their perimeter. Strategies are needed to increase the current green space in cities, as the cities examined have a high index of construction density (available data) and little index of green areas [
60,
61]. Existing buildings should be transformed into elements that integrate with the natural context [
62,
63].
Based on many interventions carried out in other European cities to counteract the extreme effects of high temperatures, it would be necessary to provide for the flat roofs of buildings to be covered with plants that can absorb carbon dioxide emissions and reduce the temperature of urban centers [
16,
64,
65,
66,
67]. The interventions carried out in the cities of Milan, ABBPR, and the multifunctional complex of Corso Buenos Ares [
57,
68] can be one good example. So-called “green roofs” should be designed and implemented, contributing to better rainwater management and reducing the effect of urban heat islands, as plants play a cooling role during the hot summer months due to evapotranspiration and light shadowing [
69]. Green roofs are also effective against pollution [
16,
70,
71,
72]. Due to their insulating effect that provides additional protection against solar radiation, green roofs can also reduce the energy needed to regulate building temperatures.
In contrast, conventional roofs lose heat in winter but heat up in summer [
73,
74]. Emilio Ambaz, the father of green architecture, has experimented with the technical limits of combining architecture and vegetation in many projects. In the case of the Prefectural International Hall, Fukuoka, Japan, 1990, the architect dedicated the entire stepped roof entirely open to the public to the vegetal surface [
75,
76,
77]. Therefore, it will be necessary to plan adequately for choosing plantings that adapt to the Mediterranean climate and have a greater capacity to absorb carbon dioxide. Vertical gardens can be envisaged to be inserted into the balconies of existing buildings [
78,
79,
80]. So, to implement disaster mitigation or prevention measures, prevention plans against possible extreme temperatures must be developed in cities with a high climate vulnerability index.
5. Conclusions
Through this study, we can calculate a numerical value for the climate vulnerability index, which provides inputs for more specific assessments. Therefore, this allows us to objectively determine the climate vulnerability of cities within a given region and establish a ranking (value scale). Therefore, knowledge of the climate vulnerability index gives managers and politicians a solid basis for making decisions that balance economic and environmental objectives [
81,
82,
83].
In fact, they could create a timetable using the data obtained from calculating the climate vulnerability index of Sicilian cities [
61,
84], thus establishing which cities’ interventions need to be carried out more urgently and, therefore, with greater priority [
85,
86].
Improving the perception of the risk associated with overheating allows us to plan all the measures necessary to stop climate change, halt the loss of natural ecosystems, and protect cities. It also contains the spread of emerging diseases due to new distributions of parasites due to the complex ecological relationships that link pathologies with climate change.
Therefore, if we were to make a timetable of interventions in Sicily to mitigate and counteract the risks deriving from climate change, the following sequence should be envisaged [
26,
82].
The city of Palermo was first, followed by Catania, Messina, Acireale, and Trapani. The climate vulnerability index can be used for emergency planning and as additional information for governments to manage [
87,
88].