Relationship between Quarry Activity and Municipal Spatial Planning: a Possible Mediation for the Case of Sardinia, Italy

Despite its economic importance, quarrying activity for the production of natural aggregates (sand, gravel, and crushed stone) can result in overexploitation of the natural environment. This paper investigates the current state of natural and recycled aggregates in Sardinia Italy and how to limit the production of natural aggregates (NA) and increase the use of recycled aggregates (RA). The municipalities of Cagliari, Sant'Antioco and Tortolì of Sardinia, Italy, were chosen as case studies because they fall within a particular territorial context. Owing to its geographic condition, the island of Sardinia must produce its own raw materials. The results of this research show how the combined use of NA and RA can help meet local and regional demand for aggregates. This proposal is derived from a needs assessment of NA based on urban masterplans for each municipality. Possible strategies for limiting the consumption of NA, as well as the use of RA, are also described.


Introduction
Designing with industrial and recyclable materials leads to more sustainable buildings.Most certificates for green building recommend such practices; two of the best-known certification systems are the US Green Building Council's Leadership in Energy and Environmental Design (LEED) rating system and the Green Globes Green Building Initiative.The introduction of these systems encourages the incorporation of many environmentally friendly programs in urban masterplans (UMPs).With this work, we intend to introduce a methodology processes of transition that addresses both certification systems.
Natural resources, which are inherently non-renewable, have been overexploited for centuries.Mining and quarrying are industrial activities that can cause irreversible changes to the earth's surface, leading to the degradation of the environment [1][2][3].Improper management of these activities, particularly in the industrial processing and waste management stages, can result in dangerous consequences for the environment.Despite its economic importance, quarrying activity for the production of natural aggregates (NA) (sand, gravel and crushed stone) is a significant source of environmental degradation.
Aggregates are used primarily in the construction sector, both without being laboriously processed (road or railway ballast), and in the production of other high-quality materials such as concrete, asphalt or pre-cast products.The European Union produces approximately two billion cubic meters of aggregates per year in order to meet the demand for this material [4].Since 2007, the per capita production of construction aggregates in Europe increased from approximately 6 tons/inhabitant [5].One possible solution to the environmental costs of aggregate production is to satisfy a part of the demand for construction aggregates with construction and demolition waste (CDW), as determined by Directive 2008/98/EC of the European Union (19 November 2008) and international research [6][7][8].
Recycled aggregates (RA) can be produced from CDW and reused in the construction sector.This practice tends to be common in those countries where high residential density and a shortage of raw materials reduce the opportunity for new quarry sites.European regulation also strongly recommends using RA to meet natural resource demand [8,9].This regulation states that members states should reach a waste recovery rate of 70% by weight by 2020.Since the regulation was established, the recycling of aggregates increased in some European countries.In fact, some States, including Denmark, the Netherlands, and Germany, have been able to recycle more than 70% of their CDW since the mid-nineties [8].Germany, for example, had a recycling rate of 89.2% in 2007 [10], and Denmark recently adopted a landfill tax to further encourage the recycling of CDW.However, in some other countries, such as Italy, this practice is still so little diffused that it is very difficult to determine the amount of RA obtained from the recycling of CDW.Furthermore, the use of RA in concrete is virtually non-existent.
This paper analyses the use of CDW as RA in the Sardinia region, where CDW amounted to approximately 1,127,644 tons in 2008 [11].The Sardinia region must supply the demand for aggregates with the extraction of its own raw materials because of its particular insular geographic condition.Therefore, the Sardinia region can be considered a "closed system" in regard to the supply of NA and RA.
This work is a part of an extensive research project on the recovery of inert waste [12], in which the use of recycled aggregates is integrated into the urban masterplans (UMPs) [13], inspired by international literature, in particular a new approach to waste management demolition in China [14].In addition, this paper attempts to innovate the urban masterplan (UMP) [13] to create more sustainable development strategies that utilize the measurement and evaluation of the use of RA.
This study aims to investigate the production and recycling of natural aggregates (NA) using the UMPs [13] of three different urban areas in Sardinia, Italy (Cagliari, Sant'Antioco and Tortolì) as a tool for evaluating demand.These three case studies were chosen because they represent the three major urban typologies of Sardinia.Cagliari is the regional capital of Sardinia and has the densest urban configuration.Tortolì and Sant'Antioco are two different costal municipalities with widespread urban configurations.The authors compared the results of this study with similar municipalities in other countries, but found difficulty comparing data, usingthe diversity evaluation method [15][16][17][18].The proposed methodology provides valuable insights, useful at the local, national, and international levels.In fact, this methodology identifies a correlation between the materials demand and urban planning processes on an international level, through the main planning tool of urban government, the UMP [13].This relationship is especially important in urban contexts with population and economic growth because optimizes the flow of materials in a sustainable environmental lens.
This paper is divided into two parts.In the first part, the CDW streams that can be reused in Sardinia are estimated through a census of recycling facilities in Sardinia and compared by interpreting the demand for aggregates from each municipality's UMP [13].In the second, the authors focus on the definition of the amount of natural aggregates (NA)that can be used in combination with RA to meet the municipal demand for aggregates.This ratio is also derived from each UMP.In all three case studies, the UMP is valid for 10 years.The paper concludes by analysing the study's findings.

Estimation and Comparison of Natural and Recycled Aggregates in Sardinia, Italy
According to the Regional Waste Management Plan (Piano Regionale Gestione Rifiuti (PRGR)), Sardinia has a per capita CDW production rate of approximately 670 kg/inhabitant/year.This production rate is significantly lower than the national average of approximately 900 kg/inhabitant/year [19].The region of Sardinia has proven to be sensitive to the problem of proper management of the materials produced in CDW by adopting the PRGR.However, this policy still does not cover the recycling of materials.Despite lacking means for the import and export of CDW in Sardinia, the use of certified RA for the construction of public and private works, is possible.The Regional Plan of Extractive Activities (Piano Regionale Attività Estrattive (PRAE)) [20] does not identify any initiative aimed at limiting the extraction of NA.Although these plans are closely related, there are no initiatives with a unified and sustainable vision for the territory.As such, the authors intend to outline a proposal for orienting initiatives towards the concept: less quarrying, less landfill.In particular, this proposal optimizes the flow of materials derived from construction activities (RA) to their use as a substitute for NA.

Natural Aggregates and Recycled Aggregates in the Construction Sector. A Comparison between Italy and Other European States
Inert materials [21] are of primary importance for the construction industry.In industrialized countries, inert materials represent 10% of the gross national product (prodotto interno lordo [PIL]).The analysis conducted at the European level reveals that the average quantity of extracted aggregates amounted to 2.95 billion tons/year, which corresponds to approximately 7.9 tons/year per capita [22].
In Italy, 62.2% of mining is inert.Gravel, sand, and limestone for cement make up 27% of the industry.This confirms the close and long-established correlation between mining and construction activity, which from the second post-war characterized the building of the historic Italian city [23].
There was a substantial decline in aggregate production from 142 million cubic meters in 2009, to 89 million cubic meters in 2010, and to approximately 80 million cubic meters in 2012.This decline is likely linked to the economic crisis in the housing market, which has affected Italy in particular.Nevertheless, Italy remains the third largest European producer of aggregates, after Germany and France [24].
In addition, the construction industry and urban architecture are based, as in all national and international cities, on the principle of availability of construction materials: aggregates, ornamental rocks and concrete [25].In Italy, these materials are strictly inert, ornamental rocks and cement.
In 2012, Italy has held the record for the greatest cement consumption per capita, at 4322 kg against the EU average of 314 kg [26].
Although the economic crisis drastically reduced production and consumption (Table 1), demand remained high.In fact, all urban renovation projects generate a strong demand for materials and provide the opportunity to utilize recycled materials in the building process [27].The "extraordinary maintenance" sector plunged in 2011 (Table 1) due to crisis in the international real estate market, then grew to an estimated +21% in 2015.The "extraordinary maintenance" sector is the only sector with a positive trend compared to others in Table 1.In addition, Table 1 shows how the construction sector in Italy is particularly oriented to urban renewal through "extraordinary maintenance" (recovery of existing buildings), which overshadows all other types of building intervention.Meanwhile the European Commission [9] required the recovery of inert materials from CDW to reach 70% by 2020.Governments could take the following initiatives concerning the reuse of products and preparing for reuse of waste to uphold this directive (Legislative Decree of 3 December 2010, n. 205, article 6): (i) Use of economic instruments; (ii) Logistical measures, such as the establishment and support of accredited centres and networks of repair/reuse; or (iii) Adoption of the framework of procedures for granting public contracts.Some member states are close to, or have already met, the minimum target for the recovery of waste from construction and demolition imposed by the CE directive [9].For Italy, however, this is a particularly ambitious target.The trend in Italy is to consider the business of mining and digging easier and more profitable than the business of recovery and reuse.
Lacking a unified building code under the Law of 11 November 2014, n. 164 (also called Unlock Italy-simplification of planning rules), the authors note that many municipalities have introduced specific measures for the use of CDW through zoning laws.Although scattered and uncoordinated, the initiatives suggested by the CE directive listed above assist in the reduction of land consumption [29].In fact, use of recycled aggregates can reduce the amount of land occupied by levy mining and landfills.
In this sense, evaluating the annual demand forNA and RA, asreported to the civil and public construction sector in reference to the UMP, is the first step to identifying possible strategies for an environmental compromise.

CDW Management in Sardinia, Italy
The tool used to analyse CDW management in Sardinia is the Regional Special Waste Plan (il Piano Regionale dei Rifiuti Speciali (PRRS)), approved on 21 December 2012 [30].Thisannual report considers allwaste produced, processed, transported or sent for disposal in the region.According to these data, CDW production amounted to a total of 658,676,965 kg, which accounts for 9% of the total regional production of hazardous waste, and corresponds to 670 kg per capita.It should be noted, however, that this production is considered only part of CDW; this is just the amount that is declared by treatment plants.The production of CDW in Sardinia (approximately 670 kg/individual/year) appears to be under-valuedas compared to the national average (approximately900 kg/inhabitant/year), and by comparison with the data obtained from the Model of the Environmental Declaration (Modello Unico di Dichiarazione Ambientale (MUD) [31]) for other territories in the national context.
Table 2 shows that most of this type of waste in Sardinia is subject to recovery (295,092,875 kg, approximately 53% of the total) and the remaining share, 258,736,682 kg, is destined for disposal.The Regional Special Waste Plan (PRRS) does not include items of import/export for CDW in Sardinia.This plan sets objectives forthe recovery and disposal of this waste as indicated in Table 2.In 2008, material recovery was 53%, 12 percentage points below the 2015 objective goal of 65% (Table 3).The rate of landfilling is still too high to be overlooked.In addition, Table 3 indicates that the percentage of recycling should be distributed, according to the objectives for 2015 and 2020.
Based on Table 3, the authors decided to focus on how to increase the current recovery rates in Sardinia, for material recovery in particular.The authors quantified the demand for aggregate from the UMP, to evaluate the possibility of replacing the use of NA with RA from CDW.However, before doing so, it was necessary to understand Sardinia's situation.

Strategies to Reduce Quarrying Activity in Sardinia
The sustainable cycle of development represents an important part of green building materials, in fact establishes a beneficial reutilization of waste resources.In this context, reducing not only mining activity but also its impact on the landscape is urgent.Data from other European countries demonstrate that it is possible to reduce the amount of material extracted through a policy of reuse of waste from the construction industry.This is, currently, the only possible way to give a future to many areas that may otherwise be condemned to increasingly degraded identities and landscape quality.The countries leading in using RA (United Kingdomand Denmark) demonstratethat it is possible to promote innovative new jobs associated with the mining industry, including green jobs in the recovery of aggregates, that further contributes to the protection of the landscape [24].
The following actions are required in order to reduce quarry activity in Sardinia: (i) Define a maximum threshold of demand.
(ii) Return to legalizing the transfer of inert materials.
(iii) Introduce concession fee for levy mining of aggregates, which is widespread in Sardinia and the main source of aggregates production.
The authors note that the first two points are subject to extensive research and the introduction of a monetary counterpart is completely absent in some Italian regions (Basilicata, Liguria and Sardinia).In this regard, it is important to show the situation in Italy by regions (Table 4).Table 4 shows the different weights that individual regions attributed to royalties, which indicates a lack of unified national vision for aspects of mining, environmental protection and trade.
In the international scenario, similar conditions occur.However, the cases of Denmark and the United Kingdom are interesting [24].Denmark has been struggling with how to reduce quarry extraction and promote the recovery of waste from construction and demolition for over 20 years, while the United Kingdom presents uniform royalties in single regions that are 5-6 times higher than the Italian average.
The fragmented Italian approach distorts the market for aggregates, encouraging higher production and sales in territories not subject to (or subject to modest) royalties.This will inevitably lead to the enlargement of the rays of action between places of origin and destination.

Evaluation of the Demand for Natural and Recycled Aggregates Resulting from Implementation of the Urban Masterplan
Green buildings represent a great market opportunity and, in this sense, that the assessment of the aggregate resulting from the UMP should contribute.In fact, the demand for aggregates in Cagliari, Sant'Antioco and Tortolì was derived from forecasts in the UMP for each municipality by (i) quantitative and qualitative analysis of the CDW flow in the Sardinian Region; and (ii) the amount of RA that may be used to meet the demand.
More specifically, the authors proceeded by following these steps: ‚ analyze flow of the Regional Special Waste Plan of Sardinia (il Piano Regionale dei Rifiuti Speciali (PRRS)) of 2012; ‚ census Sardinian inert material treatment facilities; ‚ interview operators and catalogue plants; ‚ sample the CDW physical and chemical analysis system periodically [34]; ‚ derive the aggregate demand from forecasts in UMP; and ‚ compare quantities produced and estimated demand, derived from the UMP tool.

Assessment of the Demand for Inert Materials in Cagliari, Sant'Antioco and Tortolì
In order to meet the demand for aggregates in a local context, a crucial step is to know the amount of material consumed in the territory of interestduring a specified period.Mining plans use this information to estimate the demand for aggregates of a territory.Recently, these plans play a major role inmeeting demand for natural materials by using aggregates in the construction industry.The primary purpose of these plans is to understand the demand for aggregates and facilitate the use of recycled material from CDW in place of NA.
The demand for aggregates within a territory is destined primarily to private construction and public works, since the construction sector is the primary field of application for aggregates.Badino et al. [35] identified a number of approaches for assessing the demand for aggregates, which include using local planning tools (UMP), the method that was adopted in this paper .This method is based on the estimation of the possible consumption of minerals.In each case study (Cagliari, Sant'Antioco and Tortolì, Figure 1), the hypothesis that land consumption is equivalent to the demand for aggregates, appears to be supported.In fact, Sardinia can only count on its own resources due to the low market value of aggregates and to the high costs of transport to and from the island.Therefore, the market of inert materials is fully represented at the local level in insular regions and, consequently, land consumption appears to be closely linked to the UMP forecast.In Italy, the UMP usually applies to a period of 10 years, which is also the period used to assess demand for aggregates [36].According to the adopted methodology, the demand for aggregates is derived from expected aggregate volumes.In accordance with the regional legislation and to Zoppi et al. [37] the zoning rules of cities' masterplans categorize urban areas (expressed in square meters) using the following abbreviationsin parentheses:

•
Historic centre zone ("A" zone); • Residential completion zone ("B" zone); In Italy, the UMP usually applies to a period of 10 years, which is also the period used to assess demand for aggregates [36].According to the adopted methodology, the demand for aggregates is derived from expected aggregate volumes.In accordance with the regional legislation and to Zoppi et al. [37] the zoning rules of cities' masterplans categorize urban areas (expressed in square meters) using the following abbreviationsin parentheses:

‚
Historic centre zone ("A" zone); ‚ Residential completion zone ("B" zone); ‚ Residential expansion zone ("C" zone); and ‚ Tourism zone ("F" zone) The achievable volumes were calculated for every homogeneous zone (A, B, C and F zones) for each municipality by adding the existing volume to the maximum realized volume (Table 5).Subsequently, the coefficients of use were applied according to Italian and Regional law These coefficients define the relationship betweenhomogeneous areas and the percentage of aggregates required by the corresponding building sector.In this way, the authors deduced the amount of materials required for the execution of works envisaged by the UMP [38].The estimated demand for aggregates (deduced from the indices of use) for the municipalities of Cagliari, Sant'Antioco, and Tortolì are outlined in Table 5.In particular, Table 5 shows for each homogeneous area of each municipality under studied the urban planning volumes, established by the legislation of the UMP, from which we can deduct the amount of aggregates required to realize them (for instance, new construction and maintenance of construction (construction of buildings, public works, private works, etc.) and road infrastructure), The authors determined the results presented in Table 5 using conversion coefficients calibrated to the final function of the building.Because these coefficients are numerous and have a complex application, the table shows only the results in the last two columns [39][40][41].In order to focus on the residential completion ("C" zone) and tourism areas ("F" zone), the authors did not consider the enterprise and industrial areas ("D" zone) and recreational and service areas ("G" zone).In this way, we could compare C and F zones with the remaining residential areas that have a predominantly historic fabric (A and B zones).This analysis allowed us to understand how to contain both the consumption and demand for soil resulting from expansion in these zones.The authors identified that the highest territorial indices (TI) [42] correspond to A and B zones, while the remaining zones (C and F) correspond lower values (Table 6).The values in Table 6 were obtained by total area and maximum achievable volume (extracted from the values declared by each UMP).An average value of TI is thus obtained for each homogeneous zone.This average value can express compactness or spread of the urban configuration of each homogeneous zone in the three municipalities studied.High values of TI correspond to an urban form more compact than those associated with low TI values, which correspond to a dispersed configuration.The building and urban density, which is a measure of building volume per square meter of territorial surface (TS), is determined by the manufacturability of territorial indices (TIs).Land use decisions with compact, dense configurations have greater environmental sustainability in terms of the energy use reduction [43] and building material selection [39].However, these choices are strongly influenced by national and regional legislation [44] that can affect decisions made by the designer and the planner.

Valuation Assumptions for the Maximum Limit of the Demand for Aggregates
The above analysis shows that the only way to limit levy mining aggregates is through an urban design that favours compact configurations over dispersed.This is because it is not possible to encourage the use of CDW when the distance between production centres and product destinations exceeds (30 km [45]).
Aligning local planning (UMP) forecasts for the reuse of materials with the targets that the region of Sardinia has established for itself in the period 2015-2020 (Table 3) is not possible.The primary obstacle lies in the distance between the places of production and those of potential destination.Therefore, rather than acting only on reuse it is important also to consider limiting the average requirement per capita per year, making an appropriate reduction of 35%, in line with the guidelines restricting land consumption [46].
To allow for reduction in per capita demand on the implementation of the UMP, the authors argue that a specific parameter associated with the UMP should be introduced.This specific parameter expresses the maximum demand for aggregates, that, for simplicity, we will call "Da-max (UMP)".
A generic municipality (n) with a UMP has a demand for aggregates, Da-n (UMP), that can have the following conditions: (1) Da-n (UMP) > Da-max (UMP), implies environmental incompatibility (2) Da-n (UMP) = Da-max (UMP), implies environmental neutrality (3) Da-n (UMP) < Da-max (UMP), implies environmental compatibility The best place for discussion about the definition of the parameter "Da-max (UMP)" is within the Strategic Environmental Assessment (SEA), which delegates the definition of policies for environmental sustainability.Pursuant to Legislative Decree no.152/2006 (Art.6 and subsequent amendments), all plans that can have significant impacts on the environment, including UMPs and mining activities must perform a SEA.
The SEA is a process that accompanies the development and adoption of the UMP in order to ensure the integration of environmental aspects.The SEA requires that from the earliest stages of UMP development both local and regional environmental externalities must be accounted for.
Three possible scenarios are formulated in the UMPs for Sant'Antioco and Tortolì.Cagliari constitutes a special case because it lacks C zones.
All scenarios include a compact configuration of A and B zones for which no reduction is made in relation to the potential levy.Configurations in the remaining zones were considered based on the reduction of the potential levy.A brief description of the three proposed scenarios is shown below.These scenarios represent the unique assets of urban form that are possible in the drafting process of a UMP.
This proposal builds on limiting the use of natural materials.The additional contribution that the authors intend to introduce is a portion of RA use in the implementation of the UMP.The inter-ministerial decree D.M. 203/2003 states that public offices and companies with a majority public capital should cover the annual demand of manufactured goods, and goods with a portion of products made from recycled material in not less than 30% of the same demand.
In regards to the construction industry, the procedures for implementing these prescriptions are contained in the Circular of the Italian Ministry of the Environment No. 5205 of 15/07/2005 [47].This Circular defines the technical and performance criteria that recycled materials should possess, including the frequencies of control.Furthermore, the annexes of Circular specify the values of the technical and environmental characteristics of the products, with respect to its destination.
In this sense, the Green Public Procurement (GPP), as defined by the Action Plan for the environmental sustainability of consumption in the field of public administration (Decree of 10 April 2013), plays an important role.The GPP is defined by the European Commission as "[ . . .] the approach by which Public Bodies integrate environmental criteria into all stages of their procurement process, thus encouraging the spread of environmental technologies and the development of environmentally sound products, by seeking and choosing outcomes and solutions that have the least possible impact on the environment throughout their whole life-cycle" [48].
New construction and maintenance viability can be an important test case for two reasons.First, because these are works for which the literature and recycling technologies are widely used and second because these are works for which it is easier to overcome cultural mistrust.
The imposition in the reuse of RA in UMPs through the GPP, referring to transport structures with a margin of 30% compared to the demand, is an important test case for the pursuit of environmental sustainability for public administrations.
Specifically the three case studies as described in Table 7 would occur.In other words, a saving of NA equal to about 300,000 cubic meters-that would be replaced by RA, not necessarily coming from a local basin-could be experienced, thereby breaking the insularity that has always characterized aggregates.

Conclusions
Resource conservation is a national effort to conserve energy and other resources and reduce greenhouse gas emissions by managing materials more efficiently.Industrial materials recycling (IMR) helps accomplish these goals by conserving natural resources and decreasing energy use and greenhouse gas emissions.The authors estimated and evaluated the demand for natural and recycled aggregates, and focused on the correlation between implementation of the UMP and its demand for building materials, which is little discussed in the literature.
This document reviewed the current literature on the relationship between the aggregate materials demand and urban planning, in order to analyse the Italian situation and, in particular, the Sardinian Region condition, which is a special case due to its insularity.In this regard, this paper shows how the assessment of demand for aggregates, linked to the implementation of the UMP, can provide insight into the definition of the urban form and planning process.In fact, the urban case studies of Cagliari, Sant'Antioco and Tortolì, which are representative of the remaining urban areas in Sardinia, confirmed that the historic areas (A zone) require lower quantities of aggregates, compared to the surroundings residential expansion (C zone) and tourism (F zone).The case study of Cagliari is emblematic of demand in the A zone, equal to about 5522 thousand cubic meters, compared to 31 million cubic meters for the remaining B and C zones.
The authors have shown that compact and dispersed city forms are associated with different per capita demands for aggregates.Low demand per capita is associated with a compact urban form.The relationships identified above show that we have the opportunity to quantitatively orient the urban form, by defining the achievable Da-max (UMP), for every UMP.
Furthermore, the proposed approach allows full control of land use resulting from the municipal development plan, in accordance with international requirements of the Europe 2020 Strategy.
This methodological approach to the evaluation of the demand for natural aggregates associated with the UMP is also consistent in today's national [49] and international [50] debate.The correlation with mining, arising from building activities and the urban planning sector, can no longer be ignored or neglected.Strategic objectives must be pursued to address these issues.Finding the point of balance between the form of the city and the delayed impact-that the same city generates in order to be implemented-is the key to this work.In addition, introducing the compulsory use of RA, at least for minor works, is a realistic possibility.
In addition, the control of the ecological footprint of aggregate mining through urban spatial planning constitutes a new approach to pursuing strategic objectives for environmental sustainability that is repeatable in national and international contexts.

Territorial Indices (TI):
The ratio between the manufacturable volume, expressed in cubic meters, and the land area, measured in square meters.
Territorial Surface (TS): Surface area including the areas earmarked for development in public use sectors.It considers areas of primary and secondary urbanization, including roads.
Urban Masterplan (UMP): A complex planning tool owned by a city that regulates and protects the urban and territorial processes of transformation, in accordance with the Italian National Law no.1942/1150.This tool has a relevance of at least one decade.Every Italian municipality, from small village to sprawling municipality, can have an urban masterplan.Small communities will hire a private planning firm to prepare a plan and submit it to the local government for approval.In larger cities or metropolises, the city administrative planning sector prepares the urban masterplan.

1 Scenario 1 :
Widespread urban form for the residential C zones, and compact urban form for the tourism F zone. 2 Scenario 2: Equivalent urban form between C and F zones. 3 Scenario 3: Compact urban form for C zones and widespread urban form for F zones.

Table 2 .
CDW production in Sardinia.

Table 4 .
[33]nues of royalties and profits from the sale of sand and gravel in Italy[33].

Table 5 .
Estimation of the demand for aggregates in Cagliari, Sant'Antioco and Tortoli based on UMP forecasts (Source: data from UMPs under study).

Table 6 .
TI Distribution for A, B, C and F zones in Cagliari, Sant'Antioco and Tortolì, based on UMP forecasts (Source: data from UMPs under study).

Table 7 .
Optimizing the use of recycled aggregates.