Next Article in Journal
Research on Physically Constrained VMD-CNN-BiLSTM Wind Power Prediction
Next Article in Special Issue
Sustainable Self-Compacting Concrete with Recycled Aggregates, Ground Granulated Blast Slag, and Limestone Filler: A Technical and Environmental Assessment
Previous Article in Journal
Green Transformation in Portfolio: The Role of Sustainable Practices in Investment Decisions
Previous Article in Special Issue
The Use of Plastic Waste as Replacement of Coarse Aggregate in Concrete Industry
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Sustainability
Volume 17
Issue 3
10.3390/su17031057
sustainability-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Circular Economy for Construction and Demolition Waste in the Santiago Metropolitan Region of Chile: A Delphi Analysis

by
Karina D. Véliz
1,
Carolina Busco
1,
Jeffrey P. Walters
2,* and
Catalina Esparza
1
1
Escuela de Ingeniería Civil Industrial, Universidad Diego Portales, Avda. Ejército 441, Santiago 8370191, Chile
2
Civil Engineering, University of Washington Tacoma, 1900 Commerce St, Tacoma, WA 98402, USA
*
Author to whom correspondence should be addressed.
Sustainability 2025, 17(3), 1057; https://doi.org/10.3390/su17031057
Submission received: 10 December 2024 / Revised: 20 January 2025 / Accepted: 24 January 2025 / Published: 27 January 2025
(This article belongs to the Special Issue Construction and Demolition Waste Management for a Sustainable Future)
Browse Figure
Versions Notes

Abstract

:
This study investigates the design and implementation of circular economy (CE) strategies for managing construction and demolition waste (CDW) in the Santiago Metropolitan Region of Chile (SMRC). The research aimed to identify key factors influencing the current and future adoption of CE practices for CDW management related to socio-environmental, technical, financial, and strategic-regulatory aspects, employing the Delphi method to gather expert insights. Findings reveal that the lack of knowledge about sustainable practices and the absence of regulatory frameworks for CDW disposal are the most critical barriers to effective CE implementation. The study recommends enhancing public awareness and environmental education through government and school programs, as well as enacting stricter legislation to combat illegal disposal and encourage sustainable practices and valorization of secondary raw materials within companies. Additionally, it emphasizes the importance of designing projects that prioritize waste avoidance and the development of infrastructure, technology, and processes for efficient material separation and recycling. The research also highlights potential challenges such as stagnation in the adoption of sustainable practices, skilled labor shortages, and limited research and innovation. It underscores the need for a comprehensive approach to CDW management that integrates socio-environmental, technical, financial, and regulatory dimensions to promote sustainability at both regional and global levels.

1. Introduction

The concept of the circular economy (CE) links economic performance with environmental protection [1], presenting opportunities for waste management and innovation that enhance overall welfare [2]. CE is increasingly recognized worldwide [3], as evidenced by national policies within the European Union [4] and legislative efforts in countries like Germany, Japan, and China [5].
Globally, construction and demolition waste (CDW) accounts for approximately 30–40% of solid waste generation [6]. This sector significantly contributes to environmental challenges such as waste accumulation, greenhouse gas emissions, and excessive water consumption [7]. However, CE practices for CDW management can mitigate these impacts, aligning with sustainability principles across economic, social, and environmental dimensions [8,9,10]. For instance, the reduction of CDW minimizes environmental harm, conserves resources, and supports the circularity of the economy by lowering landfill use and carbon emissions. Methods for decreasing CDW include material reuse, recycling, design for deconstruction, and adopting sustainable construction practices and business.
In Chile, CDW management faces similar challenges. An estimated 7 million tons of CDW are generated annually, primarily from residential and commercial construction [11]. The Santiago Metropolitan Region of Chile (SMRC) alone produces 1,151,299 m3 of CDW annually, representing 41% of the national total and leading to 931 unauthorized disposal sites [12]. This makes the SMRC the largest CDW generator in the country. Adopting CE principles in the SMRC’s construction sector offers opportunities to improve productivity, reduce emissions, and enhance resource sustainability, as it is established in the Circular Santiago initiative, which seeks to involve organizations in the reconversion of their business models, incorporating circular criteria into the processes, goods and/or services they produce.
Despite the pressing need for better CDW management policies with the aim of reducing waste, further research is required to identify the factors influencing CE implementation in CDW (CE-CDW) management, both locally and globally, in the socio-environmental, technical, financial, and strategic-regulatory domains. Previous studies have used diverse methodologies, including systematic reviews, meta-analyses [13], surveys, and expert interviews [14]. Some studies have identified and ranked CE-CDW barriers using approaches like TOPSIS [15] or mixed-method analyses [16,17]. Others have focused on waste quantification methods [18] and sustainability assessments through multidisciplinary approaches [8]. However, there is limited understanding of expert perspectives on factors shaping CE-CDW implementation in dense urban areas [19], as it is the SMRC.
This study addresses this gap with a semi-quantitative analysis of key factors influencing CE-CDW implementation, using the SMRC as a case study. While some research has explored sustainable construction materials, such as recycled aggregate concrete [20] and recycled concrete [21], comprehensive studies on CE-CDW factors in the SMRC remain absent. Additionally, recent studies in the Aysén Region have investigated barriers to CE implementation in CDW using alternative methodologies, such as mixed-method approaches [16]. However, given that over 40% of Chile’s population resides in the SMRC [22], understanding the factors’ influence on CE-CDW implementation in this region is essential, as it is stated within the priority guidelines for the Santiago Circular Initiative.
The study aimed to answer the following research questions (RQs):
RQ1:
What are the most relevant factors influencing the adoption of CE-CDW strategies in the SMRC?
RQ2:
Which factors inhibit or enable CE-CDW adoption?
RQ3:
How can identifying these factors inform current and future CE-CDW strategies?
To address these questions, a remote multi-round Delphi survey was conducted with local CDW experts. This study provides critical insights into the key factors influencing the adoption and sustainability of CE-CDW practices in the SMRC, offering a foundation for developing effective strategies that can address pressing urban waste management challenges in Chile and beyond.

2. Methods

The study employed the Delphi methodology, a systematic and controlled approach to asking opinions in order to achieve consensus among a panel of experts on complex issues through iterative rounds of anonymous questionnaires [23,24,25,26]. This method is particularly suitable for multi-dimensional problems, such as identifying and analyzing factors influencing the implementation and sustainability of CE-CDW practices in the SMRC, where empirical data are limited, expert consensus is required, and stakeholder perspectives play a crucial role in decision-making.
The adoption of CE-CDW in the SMRC involves various interrelated factors, including regulatory frameworks, economic incentives, technological constraints, and industry perceptions. Given the diversity of stakeholders—such as policymakers, industry professionals, and researchers—achieving consensus through structured rounds ensures a systematic refinement of expert judgments while minimizing biases from dominant opinions. The Delphi method’s iterative and anonymous nature allows experts from different backgrounds to contribute insights without external influence, enhancing the reliability of the findings.
Consensus in Delphi studies is generally achieved by analyzing the variability in expert responses across rounds, using statistical measures such as absolute deviation [27] or interquartile range (IQR) [28]. For this study, three Delphi rounds were conducted, following recommendations by Keeney et al. (2001) [29] to limit rounds to avoid participant fatigue. Each round engaged experts in evaluating the importance and influence of 16 factors identified in the literature as impacting CE-CDW adoption. These factors, categorized into socio-environmental, technical, financial, and strategic-regulatory dimensions, were informed by Véliz et al. (2023) [16] and presented in Table 1.

2.1. Selection of Expert Participants

The study targeted a diverse range of professionals and experts in Chilean construction and demolition for the expert panel. Participants were selected based on their academic credentials related to the construction industry, affiliations with CDW-related organizations, and involvement in research or practice related to CE to represent the public and private sectors as well as civil society and academia. The search process included the following:
  • A systematic review of LinkedIn profiles using the keyword “circular economy”.
  • Outreach to experts featured on the “Economy Becomes Circular” podcast on Spotify.
  • Recommendations from existing panel members.
  • Identification of contributors to the CE-CDW report [11].
Diversity in expertise and background was prioritized, as heterogeneous panels tend to yield more reliable results in Delphi studies [47]. Table S1 summarizes the qualifications of experts who participated in at least one round, showing that 37% of them belong to the public sector, 26% to the private sector, 16% to civil society, 16% to academia, and 1% to NGOs. While there are no strict rules on the number of participants for a Delphi study [48], a larger initial panel was chosen to account for potential dropouts due to time constraints or other factors [27]. Participants were contacted equitably, without bias regarding demographic factors such as age or gender, to ensure impartiality.
After identifying potential participants, experts were invited via phone or email. Each invitation outlined the research topic, scope, and the requirement for anonymous and confidential participation. Experts who agreed to these terms were included in the Delphi panel. Initially, 39 experts accepted the invitation, demonstrating strong interest in the study. Of these, 19 participated in the first round, 13 in the second, and 7 in the third. Follow-up procedures conducted right after each round included up to three phone calls and emails for non-respondents. The incentives offered to respondents were mugs and pens printed with a logo for the development of circular construction in the country.

2.2. The Delphi Process

The three Delphi rounds were conducted using the online Qualtrics platform [49]. Participants were given two weeks to complete each round’s questionnaire, distributed via email. The first round addressed the following:
  • Factor importance: Experts rated each factor’s importance using Likert-scale questions [50] on a 5-point scale, where 1 indicated “not important”, 2 “somewhat important”, 3 “moderately important”, 4 “very important”, and 5 “extremely important”, addressing RQ1.
  • Factor influence: Experts identified each factor as “enabling”, “neutral”, or “inhibiting” CE-CDW adoption, addressing RQ2.
  • Open-ended questions allowed participants to justify their ratings, suggest additional factors, and provide insights into the anticipated evolution of CE-CDW practices between 2025 and 2035.
In the second round, factors that lacked consensus in Round 1 were re-evaluated. Experts were shown their previous ratings, the group median and mode, and invited to adjust their responses. Consensus was determined using IQR and absolute deviation, with thresholds of ≤1 [26]. These statistical metrics were employed to not only evaluate consensus but, more broadly, the variability and uncertainty in responses, in order to draw conclusions about the relative importance of different factors. A comment field was provided for participants to explain their decision to maintain or revise their scores.
The third round focused on factors that still lacked consensus. Experts were asked to provide qualitative insights to better understand the divergence in opinions. This round aimed to capture a more nuanced understanding of factors that did not achieve consensus. Figure 1 provides an overview of the Delphi process across all three rounds.
To evaluate the relative importance of factors (RQ1), a hierarchical ranking was performed using average range—a non-parametric statistical technique that accounts for repeated Likert scores [51,52,53]. This method was chosen for its suitability in capturing the aggregated opinions of multiple experts. Additionally, all qualitative information gathered during the three Delphi rounds was coded according to the identified factors and subsequently used to better explain the results, incorporating direct quotes from the participants.

3. Results

The Delphi process provided valuable insights into the factors influencing the adoption of CE-CDW practices in the SMRC. Across three iterative rounds, expert evaluations highlighted areas of consensus and disagreement, offering a nuanced understanding of the factors’ importance and their roles as enablers or inhibitors. The results reveal key dimensions driving CE-CDW implementation and shed light on unresolved factors requiring further exploration. A summary of the findings is presented below, structured by each round of analysis.
In the first round, 16 factors were evaluated, revealing that nine factors achieved consensus on importance, while seven did not. Among the consensus factors, “Awareness, Knowledge, and Sustainable Actions” had the highest average range score, followed by “Specific Legislation and Regulations” and “Infrastructure, Technology, and Processes”. Factors lacking consensus primarily fell within the socio-environmental and financial dimensions, whereas technical dimension factors exhibited strong agreement (see Table 2).
For influence type, 10 factors reached consensus, of which nine were considered enabling. The sole consensus factor identified as inhibiting CE-CDW adoption was “Production Costs”. Factors that did not achieve consensus on importance or influence type were reevaluated in subsequent rounds (see Table 3).
In the second round, seven non-consensus factors for importance (Table 4) and six for influence (Table 5) type were analyzed. Key factors included “Short-Term Interest”, “Population Density and Urbanization”, “Risks and Natural Disasters”, “Capital Investment Budget”, “Expected Return on Investment”, and “Willingness to Pay for Recycled Materials”.
By the end of Round 2, five factors achieved consensus on importance, with “Political–Strategic Vision” ranked as the most important. However, “Population Density and Urbanization” and “Willingness to Pay for Recycled Materials” remained non-consensus factors. For influence type, only “Population Density” achieved consensus, leaving five factors unresolved.
Table 6 summarizes the rankings of consensus factors by average range scores and their influence type. Notably, factors ranked higher in Round 1 retained their position over those achieving consensus in Round 2, even if their scores were slightly lower (e.g., “Cost of Production of Recycled Materials” outranks “Political–Strategic Vision” due to earlier consensus).
The third round focused on gathering qualitative insights into the two non-consensus factors for importance and five for influence type. Expert responses highlighted underlying disagreements, particularly within the socio-environmental and financial dimensions, which informed the discussion on policy implications and recommendations (addressing RQ3).
The socio-environmental dimension displayed the widest variability in importance rankings, with “Awareness, Knowledge, and Sustainable Actions” ranked highest and “Short-Term Interest” and “Risks and Natural Disasters” ranked lowest. In contrast, the strategic-regulatory dimension demonstrated greater agreement, led by “Specific Legislation and Regulations”.
For influence type, “Cost of Production of Recycled Materials” was the only factor identified as inhibiting CE-CDW adoption. Factors such as “Willingness to Pay for Recycled Products”, “Expected Return on Investment”, and “Short-Term Interest” remained unresolved, with “Willingness to Pay for Recycled Products” failing to achieve consensus on any evaluated aspect.

4. Discussion

This study examines the complex interplay of socio-environmental, technical, financial, and strategic-regulatory dimensions in advancing CE practices for CDW management. The findings, based on a Delphi panel of experts, emphasize the critical factors influencing sustainable outcomes in this domain.

4.1. Socio-Environmental Dimension

The socio-environmental dimension is vital for circular construction and has a high potential for workability as it fosters awareness and knowledge, enabling stakeholders to understand the benefits of resource efficiency and waste minimization. By promoting sustainable actions and engaging communities, it builds a culture of shared responsibility, encouraging practical implementation. This collective approach ensures long-term workability and progress toward circularity in the construction sector. The findings highlight this dimension as the most outstanding given that “Awareness, Knowledge, and Sustainable Actions” is the most significant factor among all dimensions, achieving consensus among experts. This factor’s prominence reflects its centrality in strategic decision-making processes for advancing CE practices globally [54]. Diverse strategies aimed at conserving material and waste value chains often emerge from shared cultural and legal contexts, offering valuable insights for shaping guidelines in other regions. As one expert observed, “Knowledge of sustainable actions allows for proper planning in a circular economy strategy”. Education forms the foundation for this awareness, serving as both an informational and motivational tool [55]. This dual role bridges the gap between theoretical knowledge and pro-ecological behavior, fostering attitudes conducive to sustainable development. To address this, government awareness campaigns and environmental education from early childhood are recommended to instill sustainable practices.
Panelists consistently emphasized education’s transformative potential, aligning with Sukiennik et al.’s (2021) [55] argument that cultivating pro-ecological attitudes requires long-term, systemic efforts. One expert reinforced this, stating, “One must be educated to be aware of the decisions that are made”. Early childhood education on CE benefits, such as how sustainable practices strengthen communities, was highlighted as pivotal for driving cultural change [56]. Such education promotes ethical reflection and conscientious decision-making across individual, organizational, and policy levels. In addition, the identification of areas in which training is needed to prepare the future workforce for the challenges of circular construction, by establishing the necessary theoretical, practical, regulatory, and technological guidelines for professionals and technicians, as well as the respective training offerings in university and technical education institutions, would be a starting practical measure at the policy level. In contrast, “Short-Term Interests” emerged as a barrier to progress, ranking lower within the socio-environmental dimension. Experts noted that reliance on short-term perspectives hampers the implementation of infrastructure and processes critical for CE-CDW. As one panelist remarked, “A medium- and long-term vision is required”. Short-term approaches like green roofs and CDW recycling plants offer viable, low-risk investments with relatively rapid payback periods [57,58]. However, the broader transition to circularity requires aligning immediate benefits with long-term sustainability goals.
The factor “Risks and Natural Disasters”, which also reached consensus, underscores the vulnerability of CE-CDW initiatives to external shocks such as earthquakes, floods, and fires. These events not only generate substantial amounts of CDW but also amplify the need for proper disposal systems and regulatory frameworks. One expert highlighted that these elements “pose a risk to the population; therefore, when events occur, the importance of proper disposal is highlighted, and with it, a responsibility is given to whoever generates the waste”. This dual focus on immediate response and long-term planning highlights the intricate relationship between disaster resilience and sustainable waste management [59,60].

4.2. Technical Dimension

The technical dimension demonstrates broad consensus across factors, with “Project Design and Execution” leading the ranking. Experts emphasized that incorporating circularity principles from the design phase minimizes waste and optimizes resource use. Effective project execution not only ensures compliance with environmental regulations but also aligns with international sustainable development objectives [4,61,62]. By prioritizing designs that minimize waste generation and incorporate CE principles, the sector can enhance its contribution to sustainability.
Infrastructure, technology, and processes are equally crucial. Adequate facilities and advanced technologies enable proper CDW management and maximize resource utilization [63]. However, the lack of enabling infrastructure in regions like Chile poses significant challenges. Certification of recycled materials also emerged as a critical yet underdeveloped area, with stakeholders expressing concerns about the absence of certifying entities to ensure quality standards [64]. Addressing these gaps, alongside incentivizing CE practices, is essential for fostering market confidence and broader adoption.
Technological knowledge remains a limiting factor, as highlighted by one expert: “Few actors in the industry really know about life cycle or circularity”. Innovations such as building information modeling (BIM) offer promising solutions, reducing costs, time, and waste while driving industry transformation [65]. Continued investment in technological literacy will be pivotal for achieving CE-CDW goals.

4.3. Financial Dimension

The financial dimension reflects a nuanced dynamic, with “Cost of Production of Recycled Materials” being the only factor to achieve consensus in Round 1. High production costs often hinder the adoption of recycled materials, underscoring the necessity for policies that reduce costs while promoting the valorization of CDW [66]. Nonetheless, experts noted the potential for significant economic returns when strategies align with environmental and regional characteristics [63]. As one panelist noted, “Despite the higher cost of producing a product with recycled material, we achieve a higher value of the product itself”. Effective cost management and tailored strategies can help mitigate financial barriers and enhance economic returns [63].
Interestingly, while financial factors are often seen as central to CE-CDW success [67,68,69], the experts placed greater importance on socio-technical, socio-environmental, and socio-political dimensions. This prioritization reflects the multifaceted nature of CE adoption, where financial considerations, though significant, must integrate with broader systemic factors.
Round 2 further emphasized the importance of “Expected Return on Investment” and “Capital Investment Budget”. Although returns often require longer time horizons, they are integral to organizational growth and financial planning. For example, research from Thailand indicated that recycling programs might require up to 17 years to become financially feasible [70]. This extended payback period [43] reflects the broader challenge of aligning long-term sustainability goals with the short-term priorities of investors and businesses. However, the high initial costs and delayed returns make CE-CDW investments less attractive in developing contexts, where municipal solid waste management already strains budgets [71]. Addressing these financial constraints through targeted policies and incentives will be essential for fostering investor confidence and supporting sustainable initiatives.

4.4. Strategic-Regulatory Dimension

The “Specific Legislation and Regulations” factor ranked second in importance within this dimension, highlighting the critical role of clear and enforceable rules in advancing CE-CDW practices. Geels (2019) [72] notes that legislation alone is insufficient without pragmatic guidelines and awareness among stakeholders. For instance, in Chile, 60% of construction professionals are unaware of CDW-related laws, contributing to widespread illegal disposal and associated environmental impacts [11,12,73]. Similar challenges are seen globally, as in China, where CDW-specific legislation failed to achieve its goals due to unclear regulations and a lack of economic incentives [74,75]. Without strong regulations, companies are not compelled to implement sustainable practices, leading to improper waste disposal, such as the prevalence of illegal sites in Chile. Thoughtful and enforceable regulatory frameworks are critical to overcoming this challenge, especially for the valorization of secondary raw materials within companies. These policies have the potential to create markets with economic incentives that provide certainty for the infrastructure investments needed and speed up permit processing. Also, a regulatory framework focused on increasing recovery rates is relevant for significant progress in the proper management of CDW. Furthermore, a regulatory development focused on industrial symbiosis would allow the creation of new business models of design, use, and circular reuse through digital platforms where there are georeferenced records of demand and supply centers of CDW with their respective recovery, along with information on transporters, waste managers, and final disposal centers.
“Stakeholder Collaboration and Coordination”, ranked fifth, emphasizes the need for synergy among key actors, including governments, recyclers, and builders [76]. Effective collaboration fosters local initiatives and a circular construction paradigm, as one expert noted, “local initiatives are being generated thanks to the different stakeholders”.
The Incentives for CE factor, ranked seventh, underscores the importance of financial mechanisms to encourage sustainable practices. Experts stressed the need for incentives to drive investment in recycled materials, enhance compliance, and reduce illegal landfill practices [77,78]. As one panelist observed, “Everyone should have an incentive to invest in recycled materials and, in turn, have certainty and a standard of differentiation”.
Consensus in Round 2 reflects its importance in integrating technical innovation, customer engagement, and regulatory frameworks. International examples such as the EU’s Waste Framework Directive and Vietnam’s Circular 08 demonstrate how political commitment can drive CE-CDW success [43,79]. However, contrasting cases like France reveal that technical progress alone is insufficient without political support and logistical coordination, emphasizing the role of public policies in transforming CDW management practices [80].
Effective CDW management requires comprehensive policies spanning design, reuse, and recycling, as one expert remarked, “Transformation doesn’t happen naturally; it requires public policies”. Addressing these strategic-regulatory dimensions can ensure sustainable practices and drive meaningful change in CE-CDW systems.

4.5. Study Limitations

The study findings were influenced by three key constraints, potentially impacting their accuracy and generalizability. Firstly, the geographic focus on the SMRC and the limited availability of experts in CE or CDW restricted the participant pool. Since the research relied on sector experts’ perceptions, maintaining enough panelists across the three rounds of Delphi surveys was challenging. This limitation in participant numbers may affect the robustness of the study.
Secondly, the dynamic nature of factors influencing CE and CDW, combined with the static nature of the factors discussed during the brief expert engagement period, limits the study’s capacity to derive high-level findings. Extending the timeframe of future research and broadening its geographic scope to include additional regions nationally or globally could provide a more comprehensive understanding of the factors affecting CE implementation. Such an expanded approach could better inform future scenarios for CE-CDW adoption.
Thirdly, participant attrition across the three Delphi rounds posed a challenge to the study. As experts withdrew, the diversity of perspectives may have been reduced, potentially biasing the final consensus. This drop-off could also shift group dynamics, leading to less engagement or a homogenized set of responses, diminishing the richness of the findings. While participant loss is a common issue in Delphi studies, the author Landeta (1999) [81] recommends a panel size of 7 to 30 experts for meaningful results. To mitigate this challenge, we implemented several strategies to encourage sustained participation. We followed up with participants via email (three times within a 10-day period) and phone calls (twice within a 5-day period when the previous method was not effective), offering both in-person visits to their workplace and online meetings to guide them through the questionnaire. Additionally, we provided direct assistance using a tablet to facilitate responses and reduce respondent burden. As an incentive, we offered the respondents mugs and pens printed with a logo for the development of circular construction in the country, and also the commitment to sharing the study’s findings with participants once the paper is published. Despite these efforts, we acknowledge that the length of the instrument, designed to comprehensively assess both importance and influence, may have contributed to participant fatigue and reduced engagement in later rounds. Regardless of these limitations, the study provides a comprehensive discussion of factor importance (RQ1), influence types (RQ2), and actionable recommendations for CE-CDW policy and practice in Chile (RQ3). These insights contribute to future research on applying CE principles in the construction sector.

5. Conclusions

This study employed a multi-round Delphi survey with a diverse panel of experts to identify and characterize key factors influencing the adoption of circular economy (CE) practices in construction and demolition waste (CDW) management within the SMRC. Factors were evaluated across socio-environmental, technical, financial, and strategic-regulatory dimensions. The findings highlight the lack of knowledge about sustainable actions promoting CE in CDW as the most significant barrier to circularity. Additionally, the absence of enforceable laws and regulations governing CDW disposal and the need for comprehensive awareness initiatives emerged as critical challenges.
To advance CE-CDW adoption in the SMRC, public awareness campaigns and environmental education programs, particularly in schools, are strongly recommended. These initiatives can foster a culture of waste reduction and recycling. Equally important is the establishment of robust and enforceable legislation to compel companies to adopt sustainable practices and address issues such as illegal disposal sites.
Effective project design and execution must prioritize waste prevention and adherence to CE principles, while the development of infrastructure, technology, and processes is critical for enabling efficient separation, processing, and reuse of materials. However, challenges such as stagnation in the implementation of sustainable measures, a shortage of skilled labor, and insufficient research and development continue to hinder the adoption of innovative technologies necessary for comprehensive life-cycle management.
In conclusion, this study provides a comprehensive evaluation of socio-environmental, technical, financial, and regulatory factors affecting CE implementation for CDW management. It underscores the need for a balanced approach across these dimensions to achieve reliable and sustainable outcomes. Beyond addressing regional challenges, the findings have broader implications, emphasizing the importance of strategic political commitment to sustainability in CDW management. This commitment is essential for embedding CE principles in metropolitan areas across Chile and beyond, contributing to a more sustainable global framework for CDW management.

Supplementary Materials

The following supporting information can be downloaded at https://www.mdpi.com/article/10.3390/su17031057/s1; Table S1: Profile of Delphi panel experts selected; Table S2: Factor influence results for Round 1; Table S3: Factor importance results from Round 2; Table S4: Factor influence results for Round 2.

Author Contributions

Conceptualization, K.D.V., J.P.W. and C.B.; methodology, J.P.W. and C.B.; software, C.E.; validation, K.D.V., C.E. and J.P.W.; formal analysis, K.D.V., C.E. and C.B.; investigation, K.D.V., C.B. and C.E.; resources, K.D.V.; data curation, C.E.; writing—original draft preparation, K.D.V. and C.E.; writing—review and editing, K.D.V., C.E., C.B. and J.W; visualization, C.E., C.B. and J.P.W.; supervision, K.D.V., C.B. and J.P.W.; project administration, K.D.V.; funding acquisition, K.D.V. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by FONDECYT INICIACION (Grant No. 11230895).

Institutional Review Board Statement

This research was approved by the ethics committee at Universidad Diego Portales, approval number 018-2023, obtained on 29 May 2023.

Informed Consent Statement

Informed consent was obtained from all participants involved in the study.

Data Availability Statement

Some or all data, models, or code that support the findings of this study are available from the corresponding author upon reasonable request.

Acknowledgments

We sincerely thank the stakeholders surveyed for their valuable time. This study would not have been possible without their knowledgeable input.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Canu, M.E. Circular Economy and Sustainability: New Approaches to Value Creation; CreateSpace Independent Publishing Platform: Scotts Valley, CA, USA, 2017. [Google Scholar]
  2. Lakatos, E.S.; Yong, G.; Szilagyi, A.; Clinci, D.S.; Georgescu, L.; Iticescu, C.; Cioca, L.-I. Conceptualizing Core Aspects on Circular Economy in Cities. Sustainability 2021, 13, 7549. [Google Scholar] [CrossRef]
  3. López Ruiz, L.A.; Roca Ramón, X.; Gassó Domingo, S. The circular economy in the construction and demolition waste sector—A review and an integrative model approach. J. Clean. Prod. 2020, 248, 119238. [Google Scholar] [CrossRef]
  4. European Commission. Circular Economy Action Plan. 2020. Available online: https://environment.ec.europa.eu/strategy/circular-economy-action-plan_en (accessed on 18 January 2025).
  5. Merli, R.; Preziosi, M.; Acampora, A. How do scholars approach the circular economy? A systematic literature review. J. Clean. Prod. 2018, 178, 703–722. [Google Scholar] [CrossRef]
  6. Wang, J.; Wu, H.; Tam, V.W.Y.; Zuo, J. Considering life-cycle environmental impacts and society’s willingness for optimizing construction and demolition waste management fee: An empirical study of China. J. Clean. Prod. 2019, 206, 1004–1014. [Google Scholar] [CrossRef]
  7. Boonkanit, P.; Suthiluck, K. Developing a Decision-Making Support System for a Smart Construction and Demolition Waste Transition to a Circular Economy. Sustainability 2023, 15, 9672. [Google Scholar] [CrossRef]
  8. Nadazdi, A.; Naunovic, Z.; Ivanisevic, N. Circular Economy in Construction and Demolition Waste Management in the Western Balkans: A Sustainability Assessment Framework. Sustainability 2022, 14, 871. [Google Scholar] [CrossRef]
  9. Lima, L.; Trindade, E.; Alencar, L.; Alencar, M.; Silva, L. Sustainability in the construction industry: A systematic review of the literature. J. Clean. Prod. 2021, 289, 125730. [Google Scholar] [CrossRef]
  10. Papastamoulis, V.; London, K.; Feng, Y.; Zhang, P.; Crocker, R.; Patias, P. Conceptualising the Circular Economy Potential of Construction and Demolition Waste: An Integrative Literature Review. Recycling 2021, 6, 61. [Google Scholar] [CrossRef]
  11. ME. Roadmap for Circular Economy Adoption in Construction and Demolition Waste by 2025 in Chile. 2020. Available online: https://construye2025.cl/rcd/wp-content/uploads/2020/08/HDR-PAGINA_RCD_200825.pdf (accessed on 18 January 2025).
  12. Ossio, F.; Faundez, J. National Diagnosis of Illegal Waste Disposal Sites. School of Civil Construction, Pontifical Catholic University of Chile. 2021. Available online: https://www.researchgate.net/profile/Felipe-Ossio/publication/348443724_Diagnostico_Nacional_de_Sitios_de_Disposicion_Ilegal_de_Residuos/links/5fffa59f45851553a04182a1/Diagnostico-Nacional-de-Sitios-de-Disposicion-Ilegal-de-Residuos.pdf (accessed on 18 January 2025).
  13. Papamichael, I.; Voukkali, I.; Loizia, P.; Zorpas, A.A. Construction and demolition waste framework of circular economy: A mini review. Waste Manag. Res. 2023, 41, 1728–1740. [Google Scholar] [CrossRef]
  14. Zhang, C.; Hu, M.; Di Maio, F.; Sprecher, B.; Yang, X.; Tukker, A. An overview of the waste hierarchy framework for analyzing the circularity in construction and demolition waste management in Europe. Sci. Total Environ. 2022, 803, 149892. [Google Scholar] [CrossRef]
  15. Mahpour, A. Prioritizing barriers to adopt circular economy in construction and demolition waste management. Resour. Conserv. Recycl. 2018, 134, 216–227. [Google Scholar] [CrossRef]
  16. Véliz, K.D.; Walters, J.P.; Busco, C.; Vargas, M. Modeling barriers to a circular economy for construction demolition waste in the Aysén region of Chile. Resour. Conserv. Recycl. Adv. 2023, 18, 200145. [Google Scholar] [CrossRef]
  17. Walters, J.P.; Véliz, K.; Vargas, M.; Busco, C. A systems-focused assessment of policies for circular economy in construction demolition waste management in the Aysén region of Chile. Sustain. Futures 2024, 7, 100186. [Google Scholar] [CrossRef]
  18. Colorado, H.A.; Muñoz, A.; Neves Monteiro, S. Circular Economy of Construction and Demolition Waste: A Case Study of Colombia. Sustainability 2022, 14, 7225. [Google Scholar] [CrossRef]
  19. Durdyev, S.; Koc, K.; Tleuken, A.; Budayan, C.; Ekmekcioğlu, Ö.; Karaca, F. Barriers to circular economy implementation in the construction industry: Causal assessment model. Environ. Dev. Sustain. 2023, 1–37. [Google Scholar] [CrossRef]
  20. González, M.D.; Plaza Caballero, P.; Fernández, D.B.; Jordán Vidal, M.M.; Del Bosque, I.F.S.; Medina Martínez, C. The Design and Development of Recycled Concretes in a Circular Economy Using Mixed Construction and Demolition Waste. Materials 2021, 14, 4762. [Google Scholar] [CrossRef]
  21. Joseph, H.S.; Pachiappan, T.; Avudaiappan, S.; Flores, E.I.S. A Study on Mechanical and Microstructural Characteristics of Concrete Using Recycled Aggregate. Materials 2022, 15, 7535. [Google Scholar] [CrossRef]
  22. MIPS Ministry of the Interior and Public Security. Intendencia Region Metropolitana de Santiago de Chile. Geographic Information. 2024. Available online: http://www.intendenciametropolitana.gov.cl/informacion-geografica/ (accessed on 18 January 2025).
  23. Dalkey, N.; Helmer, O. An Experimental Application of the Delphi Method to the Use of Experts. The Rand Corporation. 1963. Available online: https://pages.ucsd.edu/~aronatas/project/academic/delphi%20method%20of%20convergence.pdf (accessed on 18 January 2025).
  24. Linstone, H.A. (Ed.) The Delphi Method: Techniques and Applications; 3. pr. Reading; Addison-Wesley: Boston, MA, USA, 1979. [Google Scholar]
  25. Cole, Z.D.; Donohoe, H.M.; Stellefson, M.L. Internet-Based Delphi Research: Case Based Discussion. Environ. Manag. 2013, 51, 511–523. [Google Scholar] [CrossRef]
  26. Von Der Gracht, H.A. Consensus measurement in Delphi studies. Technol. Forecast. Social Chang. 2012, 79, 1525–1536. [Google Scholar] [CrossRef]
  27. Hallowell, M.R.; Gambatese, J.A. Qualitative Research: Application of the Delphi Method to CEM Research. J. Constr. Eng. Manag. 2010, 136, 99–107. [Google Scholar] [CrossRef]
  28. Nelson-Nuñez, J.; Walters, J.P.; Charpentier, D. Exploring the challenges to sustainable rural drinking water services in Chile. Water Policy 2019, 21, 1251–1265. [Google Scholar] [CrossRef]
  29. Keeney, S.; Hasson, F.; McKenna, H.P. A critical review of the Delphi technique as a research methodology for nursing. Int. J. Nurs. Stud. 2001, 38, 195–200. [Google Scholar] [CrossRef] [PubMed]
  30. Kabirifar, K.; Mojtahedi, M.; Changxin Wang, C.; Tam, V.W.Y. Effective construction and demolition waste management assessment through waste management hierarchy; a case of Australian large construction companies. J. Clean. Prod. 2021, 312, 127790. [Google Scholar] [CrossRef]
  31. Tam, V.; Lu, W. Construction Waste Management Profiles, Practices, and Performance: A Cross-Jurisdictional Analysis in Four Countries. Sustainability 2016, 8, 190. [Google Scholar] [CrossRef]
  32. Abarca-Guerrero, L.; Maas, G.; Van Twillert, H. Barriers and Motivations for Construction Waste Reduction Practices in Costa Rica. Resources 2017, 6, 69. [Google Scholar] [CrossRef]
  33. Blaisi, N.I. Construction and demolition waste management in Saudi Arabia: Current practice and roadmap for sustainable management. J. Clean. Prod. 2019, 221, 167–175. [Google Scholar] [CrossRef]
  34. Chen, X.; Lu, W. Identifying factors influencing demolition waste generation in Hong Kong. J. Clean. Prod. 2017, 141, 799–811. [Google Scholar] [CrossRef]
  35. Hart, J.; Adams, K.; Giesekam, J.; Tingley, D.D.; Pomponi, F. Barriers and drivers in a circular economy: The case of the built environment. Procedia CIRP 2019, 80, 619–624. [Google Scholar] [CrossRef]
  36. Menegaki, M.; Damigos, D. A review on current situation and challenges of construction and demolition waste management. Curr. Opin. Green Sustain. Chem. 2018, 13, 8–15. [Google Scholar] [CrossRef]
  37. Wu, H.; Duan, H.; Zheng, L.; Wang, J.; Niu, Y.; Zhang, G. Demolition waste generation and recycling potentials in a rapidly developing flagship megacity of South China: Prospective scenarios and implications. Constr. Build. Mater. 2016, 113, 1007–1016. [Google Scholar] [CrossRef]
  38. Scatolini, F.; Bandeira, R.A.D.M. Desastres como oportunidade de implementação de políticas de gerenciamento de resíduos de construção e demolição no Brasil: Chuvas de Nova Friburgo (RJ). Eng. Sanit. Ambient. 2020, 25, 739–752. [Google Scholar] [CrossRef]
  39. Ajayi, S.O.; Oyedele, L.O.; Bilal, M.; Akinade, O.O.; Alaka, H.A.; Owolabi, H.A. Critical management practices influencing on-site waste minimization in construction projects. Waste Manag. 2017, 59, 330–339. [Google Scholar] [CrossRef] [PubMed]
  40. Aldana, J.C.; Serpell, A. Methodology for the preparation of construction project waste management plans based on innovation and productive thinking processes: A case study in Chile. Constr. Mag. 2016, 15, 32–41. [Google Scholar] [CrossRef]
  41. Chen, J.; Su, Y.; Si, H.; Chen, J. Managerial Areas of Construction and Demolition Waste: A Scientometric Review. Int. J. Environ. Res. Public Health 2018, 15, 2350. [Google Scholar] [CrossRef]
  42. Huang, B.; Wang, X.; Kua, H.; Geng, Y.; Bleischwitz, R.; Ren, J. Construction and demolition waste management in China through the 3R principle. Resour. Conserv. Recycl. 2018, 129, 36–44. [Google Scholar] [CrossRef]
  43. Oliveira Neto, R.; Gastineau, P.; Cazacliu, B.G.; Le Guen, L.; Paranhos, R.S.; Petter, C.O. An economic analysis of the processing technologies in CDW recycling platforms. Waste Manag. 2017, 60, 277–289. [Google Scholar] [CrossRef]
  44. Zhang, A.; Venkatesh, V.G.; Liu, Y.; Wan, M.; Qu, T.; Huisingh, D. Barriers to smart waste management for a circular economy in China. J. Clean. Prod. 2019, 240, 118198. [Google Scholar] [CrossRef]
  45. Yuan, H. Barriers and countermeasures for managing construction and demolition waste: A case of Shenzhen in China. J. Clean. Prod. 2017, 157, 84–93. [Google Scholar] [CrossRef]
  46. Díaz-López, C.; Bonoli, A.; Martín-Morales, M.; Zamorano, M. Analysis of the Scientific Evolution of the Circular Economy Applied to Construction and Demolition Waste. Sustainability 2021, 13, 9416. [Google Scholar] [CrossRef]
  47. Black, N.; Murphy, M.; Lamping, D.; McKee, M.; Sanderson, C.; Askham, J.; Marteau, T. Consensus Development Methods: A Review of Best Practice in Creating Clinical Guidelines. J. Health Serv. Res. Policy 1999, 4, 236–248. [Google Scholar] [CrossRef]
  48. Steurer, J. The Delphi method: An efficient procedure to generate knowledge. Skelet. Radiol. 2011, 40, 959–961. [Google Scholar] [CrossRef] [PubMed]
  49. Version [2023] of Qualtrics. Copyright © Qualtrics. Qualtrics and All Other Qualtrics Product or Service Names Are Registered Trademarks or Trademarks of Qualtrics, Provo, UT, USA. Available online: https://www.qualtrics.com (accessed on 18 January 2025).
  50. Taylor, E. We Agree, Don’t We? The Delphi Method for Health Environments Research. Health Environ. Res. Des. J. 2020, 13, 11–23. [Google Scholar] [CrossRef] [PubMed]
  51. Busco, C.; González, F.; Aránguiz, M. Factors that favor or hinder the acquisition of a digital culture in large organizations in Chile. Front. Psychol. 2023, 14, 115303. [Google Scholar] [CrossRef]
  52. Gordon, T.J. Energy forecasts using a “Roundless” approach to running a Delphi study. Foresight 2007, 9, 27–35. [Google Scholar] [CrossRef]
  53. Del Grande, C.; Kaczorowski, J. Rating versus ranking in a Delphi survey: A randomized controlled trial. Trials 2023, 24, 543. [Google Scholar] [CrossRef]
  54. Ramos, M.; Martinho, G.; Vasconcelos, L.; Ferreira, F. Local scale dynamics to promote the sustainable management of construction and demolition waste. Resour. Conserv. Recycl. Adv. 2023, 17, 200135. [Google Scholar] [CrossRef]
  55. Sukiennik, M.; Zybała, K.; Fuksa, D.; Kęsek, M. The Role of Universities in Sustainable Development and Circular Economy Strategies. Energies 2021, 14, 5365. [Google Scholar] [CrossRef]
  56. Tiippana-Usvasalo, M.; Pajunen, N.; Maria, H. The role of education in promoting circular economy. Int. J. Sustain. Eng. 2023, 16, 92–103. [Google Scholar] [CrossRef]
  57. Bianchini, F.; Hewage, K. Probabilistic social cost-benefit analysis for green roofs: A lifecycle approach. Build. Environ. 2012, 58, 152–162. [Google Scholar] [CrossRef]
  58. Coelho, A.; De Brito, J. Economic viability analysis of a construction and demolition waste recycling plant in Portugal—Part I: Location, materials, technology and economic analysis. J. Clean. Prod. 2013, 39, 338–352. [Google Scholar] [CrossRef]
  59. Brown, C.; Milke, M. Recycling disaster waste: Feasibility, method and effectiveness. Resour. Conserv. Recycl. 2016, 106, 21–32. [Google Scholar] [CrossRef]
  60. Wang, Z.; Zhang, Z.; Liu, J. Exploring spatial heterogeneity and factors influencing construction and demolition waste in China. Environ. Sci. Pollut. Res. 2022, 29, 53269–53292. [Google Scholar] [CrossRef] [PubMed]
  61. Shooshtarian, S.; Caldera, S.; Maqsood, T.; Ryley, T. Using Recycled Construction and Demolition Waste Products: A Review of Stakeholders’ Perceptions, Decisions, and Motivations. Recycling 2020, 5, 31. [Google Scholar] [CrossRef]
  62. Arulrajah, A.; Yaghoubi, E.; Wong, Y.C.; Horpibulsuk, S. Recycled plastic granules and demolition wastes as construction materials: Resilient moduli and strength characteristics. Constr. Build. Mater. 2017, 147, 639–647. [Google Scholar] [CrossRef]
  63. Boateng, S.B.; Banawi, A.A.; Asa, E.; Yu, Y.; Ahiable, C. Environmental and economic outlook of construction and demolition waste management practices in a mid-sized city. J. Mater. Cycles Waste Manag. 2023, 25, 2526–2542. [Google Scholar] [CrossRef]
  64. Silva, R.V.; De Brito, J.; Dhir, R.K. Availability and processing of recycled aggregates within the construction and demolition supply chain: A review. J. Clean. Prod. 2017, 143, 598–614. [Google Scholar] [CrossRef]
  65. Keith, D.A.; Ferrer-Paris, J.R.; Nicholson, E.; Bishop, M.J.; Polidoro, B.A.; Ramirez-Llodra, E.; Tozer, M.G.; Nel, J.L.; Mac Nally, R.; Gregr, E.J.; et al. A function-based typology for Earth’s ecosystems. Nature 2022, 610, 513–588. [Google Scholar] [CrossRef]
  66. Ferronato, N.; Fuentes Sirpa, R.C.; Guisbert Lizarazu, E.G.; Conti, F.; Torretta, V. Construction and demolition waste recycling in developing cities: Management and cost analysis. Environ. Sci. Pollut. Res. 2022, 30, 24377–24397. [Google Scholar] [CrossRef]
  67. Mehmood, A.; Ahmed, S.; Viza, E.; Bogush, A.; Ayyub, R.M. Drivers and barriers towards circular economy in AGRI-FOOD supply chain: A review. Bus. Strat. Dev. 2021, 4, 465–481. [Google Scholar] [CrossRef]
  68. Aranda-Usón, A.; Portillo-Tarragona, P.; Marín-Vinuesa, L.; Scarpellini, S. Financial Resources for the Circular Economy: A Perspective from Businesses. Sustainability 2019, 11, 888. [Google Scholar] [CrossRef]
  69. Saarinen, A.; Aarikka-Stenroos, L. Financing-Related Drivers and Barriers for Circular Economy Business: Developing a Conceptual Model from a Field Study. Circ. Econ. Sustain. 2023, 3, 1187–1211. [Google Scholar] [CrossRef]
  70. Doan, D.T.; Chinda, T. Modeling Construction and Demolition Waste Recycling Program in Bangkok: Benefit and Cost Analysis. J. Constr. Eng. Manag. 2016, 142, 05016015. [Google Scholar] [CrossRef]
  71. Chatterjee, A.K. Water Supply, Waste Disposal and Environmental Engineering, 8th ed.; Khanna Publishers: New Delhi, India, 2010. [Google Scholar]
  72. Geels, F.W. Socio-technical transitions to sustainability: A review of criticisms and elaborations of the Multi-Level Perspective. Curr. Opin. Environ. Sustain. 2019, 39, 187–201. [Google Scholar] [CrossRef]
  73. Véliz, K.D.; Ramírez-Rodríguez, G.; Ossio, F. Willingness to pay for construction and demolition waste from buildings in Chile. Waste Manag. 2022, 137, 222–230. [Google Scholar] [CrossRef]
  74. Hentges, T.I.; Machado Da Motta, E.A.; Valentin De Lima Fantin, T.; Moraes, D.; Fretta, M.A.; Pinto, M.F.; Böes, J.S. Circular economy in Brazilian construction industry: Current scenario, challenges and opportunities. Waste Manag. Res. 2022, 40, 642–653. [Google Scholar] [CrossRef]
  75. Hu, Y.; He, X.; Poustie, M. Can Legislation Promote a Circular Economy? A Material Flow-Based Evaluation of the Circular Degree of the Chinese Economy. Sustainability 2018, 10, 990. [Google Scholar] [CrossRef]
  76. Almeida, F.; Vieira, C.S.; Carneiro, J.R.; Lopes, M.D.L. Drawing a Path towards Circular Construction: An Approach to Engage Stakeholders. Sustainability 2022, 14, 5314. [Google Scholar] [CrossRef]
  77. Alite, M.; Abu-Omar, H.; Agurcia, M.T.; Jácome, M.; Kenney, J.; Tapia, A.; Siebel, M. Construction and demolition waste management in Kosovo: A survey of challenges and opportunities on the road to circular economy. J. Mater. Cycles Waste Manag. 2023, 25, 1191–1203. [Google Scholar] [CrossRef]
  78. Su, P.; Peng, Y.; Hu, Q.; Tan, R. Incentive Mechanism and Subsidy Design for Construction and Demolition Waste Recycling under Information Asymmetry with Reciprocal Behaviors. Int. J. Environ. Res. Public Health 2020, 17, 4346. [Google Scholar] [CrossRef]
  79. Hoang, N.H.; Ishigaki, T.; Kubota, R.; Tong, T.K.; Nguyen, T.T.; Nguyen, H.G.; Yamada, M.; Kawamoto, K. Waste generation, composition, and handling in building-related construction and demolition in Hanoi, Vietnam. Waste Manag. 2020, 117, 32–41. [Google Scholar] [CrossRef]
  80. Kamsook, S.; Phongphiphat, A.; Towprayoon, S.; Vinitnantharat, S. Investigation of plastic waste management in Thailand using material flow analysis. Waste Manag. Res. 2023, 41, 924–935. [Google Scholar] [CrossRef] [PubMed]
  81. Landeta, J. The Delphi Method: A Forecasting Technique for Uncertainty, 1st ed.; Editorial Ariel: Barcelona, Spain, 1999. [Google Scholar]
Sustainability 17 01057 g001
Figure 1. The Delphi process used in this study.
Figure 1. The Delphi process used in this study.
Sustainability 17 01057 g001
Table 1. Factors considered by the Delphi panel of experts, categorized by dimension, and defined based on the literature.
Table 1. Factors considered by the Delphi panel of experts, categorized by dimension, and defined based on the literature.
DimensionFactorDefinition
Socio-EnvironmentalAwareness, Knowledge, and Sustainable Actions Level of awareness of CDW recycling and environmental protection [30,31].
Short-Term InterestConstruction companies prioritize short-term monetary savings over environmental care, thus preferring the use of illegal landfills and unauthorized personnel to manage their CDW [32,33,34].
Population Density and UrbanizationPopulation growth pressures companies to build, prioritizing rapid construction instead of sustainable CDW management [30,31,34,35,36,37].
Risks and Natural DisastersLack of assignment of responsibility in the management of CDW in the face of natural disasters [36,38].
TechnicalInfrastructure, Technology, and ProcessesLack of adequate infrastructure, technology, and processes that allow classification, transport, and recovery of CDW [32,33,39,40,41].
Technological KnowledgeStakeholders have inadequate technological knowledge and information along with a lack of experience in CE, which translates into traditional CDW management [30,35,36,40,41,42,43,44].
Project Design and ExecutionPresentation and implementation of initiatives, integrating sustainable CDW principles [45].
Certification of Recycled MaterialsLack of technical certification of waste quality, leading to a low preference for recovered materials [15,42].
FinancialCapital Investment BudgetDifficulty and lack of budget for capital investment given its high value [30,32].
Expected Return on InvestmentEstimation of financial benefits [44].
Willingness to Pay for Recycled MaterialsWillingness to pay for recycled materials below their market price, leading to substitution of new materials [36,39,43].
Cost of Production of Recycled MaterialsThe production cost of recovered materials is greater than the market price, discouraging new supply of these materials [36,42].
Strategic-RegulatoryPolitical–Strategic VisionPolitical priorities and state agents are not focused on strategic CE objectives for CDW, which increases uncertainty and demotivation for sustainable waste management [30,35,46].
Specific Legislation and RegulationsSpecific laws and regulations established by the government that regulate and promote sustainable practices [30,34,36].
Incentives for CELack of incentives and supervision to recognize those who recirculate CDW and penalize those who manage CDW in non-authorized sites [32,33,34,40,41].
Stakeholder Collaboration and CoordinationCollaboration that maximizes social benefit between interest groups is hindered by asymmetries and lack of coordination systems at central and local levels, due to lack of information [30,33,35,36,44].
Table 2. Factor importance results for Round 1.
Table 2. Factor importance results for Round 1.
DimensionFactorMinMaxMedAverage RangeAbs.
Deviation		IQRConsensus
Socio-EnvironmentalAwareness, Knowledge, and Sustainable Actions2555.870.840.0Yes
Short-Term Interest1543.341.101.0No
Population Density and Urbanization1532.891.311.0No
Risks and Natural Disasters1543.341.101.0No
TechniqueInfrastructure, Technology, and Processes3555.32891.0Yes
Technological Knowledge3544.241.001.0Yes
Project Design and Execution3555.420.890.5Yes
Certification of Recycled Materials3554.840.941.0Yes
FinancialCapital Investment Budget1554.391.421.5No
Expected Return on Investment2544.551.101.5No
Willingness to Pay for Recycled Materials1554.501.152.0No
Cost of Production of Recycled Materials2543.580.731.0Yes
Strategic-RegulatoryPolitical–Strategic Vision3554.971.051.0No
Specific Legislation and Regulations4555.710.630.5Yes
Incentives for CE4554.820.891.0Yes
Stakeholder Collaboration and Coordination3555.210.891.0Yes
Table 3. Factor influence results for Round 1, presented as percentages (%) of experts indicating each of the influence types.
Table 3. Factor influence results for Round 1, presented as percentages (%) of experts indicating each of the influence types.
DimensionFactor[1: Enables+][2: Does Not Contribute][3: Inhibits−]
Socio-EnvironmentalAwareness, Knowledge, and Sustainable Actions681616
Short-Term Interest371152
Population Density and Urbanization262648
Risks and Natural Disasters571132
TechniqueInfrastructure, Technology, and Processes79021
Technological Knowledge781111
Project Design and Execution84511
Certification of Recycled Materials79516
FinancialCapital Investment Budget581131
Expected Return on Investment321652
Willingness to Pay for Recycled Materials371647
Cost of Production of Recycled Materials212653
Strategic-RegulatoryPolitical–Strategic Vision74215
Specific Legislation and Regulations631621
Incentives for CE9055
Stakeholder Collaboration and Coordination79516
Table 4. Factor importance results for Round 2.
Table 4. Factor importance results for Round 2.
DimensionFactorMin.MaxMedAverage RangeAbs.
Deviation		IQRConsensus
Socio-EnvironmentalShort-Term Interest3542.270.380.0Yes
Population Density and Urbanization2541.311.072.0No
Risks and Natural Disasters1542.190.761.0Yes
FinancialCapital Investment Budget2553.270.611.0Yes
Expected Return on Investment4553,580.301.0Yes
Willingness to Pay for Recycled Materials3551.690.762.0No
Political–Strategic Vision4553.690.230.0Yes
Table 5. Factor influence results for Round 2, presented as percentages (%) of experts indicating each of the influence types.
Table 5. Factor influence results for Round 2, presented as percentages (%) of experts indicating each of the influence types.
DimensionFactor[1: Enables +][2: Does Not Contribute][3: Inhibits −]
Socio-EnvironmentalShort-Term Interest46054
Population Density and Urbanization621523
Risks and Natural Disasters461538
FinancialCapital Investment Budget54046
Expected Return on Investment46054
Willingness to Pay for Recycled Materials462331
Table 6. Ranking of consensus factors for Round 1 and Round 2. Each factor in this table reached consensus for influence type (enables, no influence, or inhibits). The mode for influence type for each consensus factor is also provided.
Table 6. Ranking of consensus factors for Round 1 and Round 2. Each factor in this table reached consensus for influence type (enables, no influence, or inhibits). The mode for influence type for each consensus factor is also provided.
FactorsRanking (R)Average RangeInfluence TypeConsensus Round
Awareness, Knowledge, and Sustainable ActionsR15.87Enables1
Specific Legislation and RegulationsR25.71Enables1
Project Design and ExecutionR35.42Enables1
Infrastructure, Technology, and ProcessesR45.32Enables1
Stakeholder Collaboration and CoordinationR55.21Enables1
Certification of Recycled MaterialsR64.84Enables1
Incentives for CER74.82Enables1
Technological KnowledgeR84.24Enables1
Cost of Production of Recycled MaterialsR93.58Inhibits1
Political–Strategic VisionR103.69Enables2
Expected Return on InvestmentR113.58Non-consensus2
Capital Investment BudgetR123.27Non-consensus2
Short-Term InterestR132.27Non-consensus2
Risks and Natural DisastersR142.19Non-consensus2
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Véliz, K.D.; Busco, C.; Walters, J.P.; Esparza, C. Circular Economy for Construction and Demolition Waste in the Santiago Metropolitan Region of Chile: A Delphi Analysis. Sustainability 2025, 17, 1057. https://doi.org/10.3390/su17031057

AMA Style

Véliz KD, Busco C, Walters JP, Esparza C. Circular Economy for Construction and Demolition Waste in the Santiago Metropolitan Region of Chile: A Delphi Analysis. Sustainability. 2025; 17(3):1057. https://doi.org/10.3390/su17031057

Chicago/Turabian Style

Véliz, Karina D., Carolina Busco, Jeffrey P. Walters, and Catalina Esparza. 2025. "Circular Economy for Construction and Demolition Waste in the Santiago Metropolitan Region of Chile: A Delphi Analysis" Sustainability 17, no. 3: 1057. https://doi.org/10.3390/su17031057

APA Style

Véliz, K. D., Busco, C., Walters, J. P., & Esparza, C. (2025). Circular Economy for Construction and Demolition Waste in the Santiago Metropolitan Region of Chile: A Delphi Analysis. Sustainability, 17(3), 1057. https://doi.org/10.3390/su17031057

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop