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Review

Social Sustainability in Construction Projects—A Systematic Review of Assessment Indicators and Taxonomy

by
Mozhdeh Rostamnezhad
* and
Muhammad Jamaluddin Thaheem
School of Architecture & Built Environment, Deakin University, Geelong, VIC 3220, Australia
*
Author to whom correspondence should be addressed.
Sustainability 2022, 14(9), 5279; https://doi.org/10.3390/su14095279
Submission received: 9 March 2022 / Revised: 13 April 2022 / Accepted: 18 April 2022 / Published: 27 April 2022

Abstract

:
Despite its importance and appeal, the social dimension of sustainability in construction projects is less explored and lacks a comprehensive and standardized framework. This diminishes the holistic view of sustainability. The existing customized frameworks make the selection of factors challenging across different contexts. Eventually, the practitioners have to pick and choose the factors. This reduces the reliability of social sustainability assessments and makes them a procedural challenge. To fill this gap, the current review synthesizes a framework of social sustainability for construction projects. For this purpose, a systematic review of the literature published until 2021 is performed. The indicators are extracted from the selected 22 papers and their content is analyzed to check for similarities. The final set of 76 factors is synthesized into an assessment framework through a thematic analysis based on a bottom-up approach. The framework is organized into 7 enablers or themes, 27 indicators, and 76 sub-indicators. The enablers of social sustainability are stakeholder, safety and health, human resource development, project, industry, community, and government. The framework provides a comprehensive and precise view of social sustainability which can be leveraged to ensure better planning and sustainable development of construction projects.

1. Introduction and Background

Social sustainability is often the vaguest and least explicit dimension in practical attempts to shape sustainable development [1]. This is partly because social sustainability is a soft aspect of sustainable development, and its assessment has always posed practical challenges for experts [2,3,4,5]. To ensure long-term sustainability, it is critical to manage natural and social capital, not only economic capital [6]. Social sustainability is approached from the perspective of one of its ingredients, namely social acceptance [7]. The benefits of socially sustainable development may be returned in numerous ways, such as the creation of jobs and improved quality of life [8].
Within the holistic view, social sustainability aims to respond to the needs of people at every stage of involvement in the construction process (from commissioning to demolition), provide high customer satisfaction, and work closely with clients, suppliers, employees, and local communities [9]. A sustainable construction project should have social considerations for stakeholders and the end users, the influence of the project on the surrounding community, and the health, safety, and education of employees. Integrating these factors will enhance both the long-term project efficiency and the quality of life of those impacted by the project [10]. Like sustainable development, social sustainability is also a complex phenomenon and its assessment has remained challenging due to its subjective, qualitative, and contextual nature [11]. One of the promising assessment strategies is to break down this complex concept into smaller, more manageable, and realistically measurable variables, also called indicators, and organize them into an assessment framework [12,13]. But in the absence of a standardized assessment framework, like those available for environmental or economic sustainability, the assessment of social sustainability has remained elusive and subjective [14]. Various environmental sustainability assessment frameworks and movements have been suggested and adopted, including the EcoDistrict approach. These frameworks generate relevant information about the sustainability of regions [15,16]. The assessment of environmental sustainability is also carried out using the CML-IA (v.3.03) method, which has 11 baseline indicators. CML is the most commonly used life cycle impact assessment (LCIA) method (ISO, 2000) [17,18,19]. Moreover, Wang et al. [20] selected 28 environmental sustainability indicators based on the SDGs. They used a CES model to assess environmental sustainability at China’s national and provincial levels [20]. Ahmad and Thaheem [21] proposed an economic sustainability framework for residential buildings that considered life cycle cost to be a “traditional indicator”, while they characterized affordability, adaptability, and manageability factors as “non-traditional indicators”.
Some seminal studies have investigated various factors affecting social sustainability in construction projects. Some studies focused on a single factor affecting social sustainability in construction projects such as stakeholder [22,23], safety [8,24], and community involvement [25,26]. For instance, Toole and Carpenter [8] provided an overview of the prevention through design (also known as design for construction safety) concept and suggested that it should be a prerequisite for social equity in capital construction projects. Also, Doloi [23] evaluated social values in infrastructure projects by analyzing the influence of stakeholders and the impact of the project on society.
On the other hand, some studies have investigated multiple factors affecting social sustainability in construction projects. For example, Nasirzadeh et al. [1] modeled a wide range of factors affecting the social sustainability performance of construction projects, taking into account their complex interactions. Moreover, Stender and Walter [27] developed a framework involving 12 indicators grouped into three overarching themes: social cohesion, participatory processes, and accessibility to living opportunities. Social sustainability can only be understood by examining the whole system in which the problem occurs and how different various influencing factors interact [28].

1.1. Knowledge Gap

Several previous studies have developed assessment frameworks, some of which are fractional and focused on particular areas of social sustainability [29,30,31]. For example, Li et al. [32] provided a breakdown of multi-stakeholder-related social sustainability, whereas Doloi [23] provided a community-specific social sustainability assessment framework. These frameworks focus on particular areas of social sustainability. Though this approach provides a deeper insight into a chosen area of focus, it does not offer a comprehensive social sustainability breakdown into objectively measurable and highly reliable taxonomy. This unavailability puts researchers, policymakers, and practitioners in a tight spot; they have to imagine and expand on the possible hierarchies of social sustainability to achieve an accurate and representative assessment of the social implications of a construction project.
Due to this guessing game, not all aspects of social sustainability are included, and some major aspects run the risk of being neglected because of the verifiable, limited space-time perspectives and considerations of the concerned decision-makers. Also, this unavailability puts extra work on the practitioners and decision-makers of sourcing the existing frameworks and gathering a detailed, reliable, and generalizable breakdown of social sustainability.
Some very recent studies have attempted this task. For example, Goel et al. [33] developed a framework of social sustainability and construction project management. Their framework includes three layers of social sustainability characteristics, six identified areas of social sustainability integration in construction project management, and the project lifecycle. They only focused on the managerial aspects of construction projects through the lens of stakeholders. Further, Fatourehchi and Zarghami [34] developed an assessment framework for managing sustainable construction in residential buildings. They investigated the social sustainability indicators through a multi-criteria decision-making approach and obtained criteria priorities through local experts.
These frameworks have advanced the body of knowledge by providing a useful synthesis of social sustainability assessment. However, their inherent limitations of coverage and focus justify more effort in this direction.

1.2. Research Goal

A comprehensive framework for construction projects can act as a foundation to achieve more sustainable projects and advance the research in this direction. Surely, such a framework does not disregard all the focused and specialized work performed by the existing frameworks; it merely offers a one-stop solution to the assessment of social sustainability in construction projects.
Therefore, this review explores the research on social sustainability in construction projects. It highlights the development of frameworks, their focus and limitations, and the applications of their findings. Using the synthesized factors, it develops a comprehensive framework of social sustainability in construction projects through thematic analysis. In doing so, it identifies, extracts, and categorizes into themes the different contributors to social sustainability. Identification of the criteria for measuring the social sustainability performance of construction projects is particularly highlighted. Moreover, to improve the assessment, the framework contains a measurement unit for all the contributors over a five-point Likert scale (strongly agree, agree, neutral, disagree, and strongly disagree). Finally, the relevant project phase or phases for each contributor are mentioned to help better operationalize the social sustainability assessment. These phases are strictly following PMBOK guides project lifecycle phases and they mainly deal with project implementation. The standard PMBOK lifecycle for the project is used where the initiation is pre-implementation. These phases are intended to relate to the entire project life cycle as given in the PMBOK guide (initiating, planning, executing, monitoring and controlling, and closure). Post-implementation has been excluded in this paper. The outcomes of this research may have a significant impact on the improvement of social sustainability in construction projects through a holistic approach to investigating the influencing factors.

2. Review Methodology

The tradition of developing frameworks by synthesizing published factors and variables is not new in the literature. This method is popular since it allows one to stand on the shoulders of giants by leveraging on the existing research. It helps draw a holistic picture and configure a comprehensive set of factors into a framework. In the field of sustainability, where this trend is recent as evidenced by a majority of the retrieved papers published between 2017 to 2021, the systematic literature review is a dominant method for reviewing the papers and synthesizing the frameworks. For example, Koke and Moehler [35] used two systematic literature reviews to develop the conceptual framework for earned green value management to act as the theoretical groundwork for a new project management tool to track the attainment of sustainability goals in projects.
To achieve the goal of this study, a systematic literature review is performed. In doing so, journal papers published until 2021 in the area of social sustainability in the construction industry were reviewed to extract the relevant indicators. For this purpose, a qualitative meta-analysis of high-quality literature is carried out that offers an overview of the research environment in this field. It enables researchers to make findings relevant to the literature that would not be possible by other approaches [36]. The purpose of a systematic literature review is to provide an overall image of the research environment in a specific area. Systematic reviews remain at the top of the “hierarchy of facts” above all other research designs, since they can have the most important functional consequences [37].

2.1. Searching and Sourcing Relevant Literature

As detailed in Table 1 and graphically shown in Figure 1, the core collection of Scopus was searched in the first step with the search string of (“social sustainability” and “construction industry” or “construction project” or “construction management” or “project management” or “infrastructure project”) in titles+keywords+abstract. The Scopus platform was selected due to its higher journal coverage than similar databases [38]. It guarantees high-quality peer-reviewed articles, rigorous inclusion criteria and indexing processes, availability of more recent publications, and also provides a reproducible process [39].
Using the mentioned search query, 112 journal papers were found and an initial screening of their relevance helped eliminate the remaining papers. The relevance was determined by two criteria: (i) specific focus on social sustainability; (ii) area of application within the construction and built environment sectors. Papers not meeting the first criterion and targeting sustainability at large were removed. Similarly, papers not meeting the second criterion and targeting diverse areas of application excluding construction and built environment were removed. The remaining 94 papers were retrieved and thoroughly studied to ensure that they address the central research topic. In doing so, the entire content of these papers was read to choose suitable articles as per their relevance to the research topic. It was found that these papers can be largely distributed into two groups: social sustainability in construction projects and social sustainability in urban and regional planning. Based on the focus of this study, the final selection was reduced to 52 papers in which social sustainability in construction projects is investigated. The findings are based on the synthesis of these papers where one or more influencing factors of social sustainability are discussed, whereas the papers on urban and regional research were removed.
The shortlisted 52 research papers were carefully read to identify papers covering more than one factor. The purpose of this screening was to ensure broad coverage of factors. In doing so, papers addressing more than one factor were included and those addressing only one factor were excluded. For example, Toole and Carpenter [8], which discussed safety as a sole factor, was removed since the same factor has been discussed by Valdes-Vasquez and Klotz [10] and Nasirzadeh et al. [1] along with several other factors providing broader coverage.
The papers were carefully read to not only extract the factors but also understand their context. Therefore, the identified factors of safety in all the papers were pointing to the same macro area. Moreover, careful observation of the focus of each study reveals that papers with limited focus only cater to stakeholders or the community as the ends, and other areas of social sustainability are treated more like functions or a means to achieve social sustainability for the community or stakeholders. This presents a micro and narrow view. Thus, to achieve a more inclusive view of social sustainability, the second step of the screening helped reduce the number of papers from 52 to 28. These papers represent broad geographical origins and contexts, as shown in Table 2. The papers excluded at this stage, though relevant and valuable, were largely uni-focused. Some examples include [26] which explore the factor of the national culture impacting social sustainability.
The context of each study is extracted from the papers as reported by the authors. Generally, the papers deal with construction at large without specific case study projects. In such situations, the context is mentioned as “Construction”. However, in other areas, the authors have executed case studies of particular project types such as buildings, roads, and housing. It is important to note that the contexts do not seem to be mutually exclusive or even very different from one another. The overlapping represents the focus of the study in terms of its context and application.

2.2. Development of Social Sustainability Framework

The development of the social sustainability framework, as shown in Figure 2, follows a systematic stepwise approach.
The factors were extracted and assembled into a framework. The framework was developed through a bottom-up approach. In doing so, a thematic analysis was performed where the extracted factors were treated as sub-indicators and organized into indicators and enablers. The thematic analysis helps identify, analyze, and describe patterns or themes within data. It arranges and explains the dataset in great detail [54]. This has been applied in similar studies such as Derakhshan et al. [55], who performed a thematic analysis to find out the three contexts that influence an organization’s stakeholder engagement approaches.
The thematic analysis of the current study treats the themes as top-level enablers that contain indicators that are made of sub-indicators extracted from the literature. An indicator is not only representational but is also a way of making sense of and responding to the situations we find ourselves in, thus having an impact [56]. Additionally, an enabler, or a theme, represents a higher level hierarchy of schematics that can be leveraged to implement sustainability [57,58]. Based on the bottom-up approach, leveraging an enabler should ordinarily result in a change in the value of an indicator.
The tradition of enablers representing the higher level of the hierarchy is established in the literature [12,13,59]. For example, Kumar and Anbanandam [13] developed a framework for the social sustainability of the freight transportation system by dividing it into three levels: enabler, criteria, and attributes.
The enablers of the developed framework are not strictly mutually exclusive, and it is possible to have overlap among some of their areas, as shown in Figure 3. Additionally, the enablers follow both functional and attributive categorization. In the functional categorization, the sub-indicators and the indicators are placed under an enabler based on the similarity of their function. For example, all the sub-indicators functioning and supporting health and safety are combined into the enabler “Safety and health”. George et al. [60] and Munny et al. [61] have identified health and safety as a fundamental enabler of social sustainability of production and manufacturing supply chains. The appropriate safety culture, policies, tools, and praxis create an enabling environment to achieve social sustainability. Similarly, all the sub-indicators supporting the development of human resources are grouped under the “Human resource development” enabler. Several studies have mentioned the application domains or sub-parts of human resource development. Mani et al. [62] identified labor rights, wages, and education as enablers of social sustainability.
On the other hand, attributive categorization groups together all the sub-indicators that have similar characteristics. For example, the sub-indicators supporting a project are grouped into the “Project” enabler. A project and its management in a sustainable way create a breeding ground to achieve social sustainability [63]. It is important to note that some enablers are contextual. For example, the sub-indicators of the “Project” enabler refer to the context of the project. Further, a project will operate within an industry which in turn will operate within the government-provided rules and regulations. Industry, through its culture and coordination, enables social sustainability [64,65]. In addition, the government, through regulations and incentives, drives the change from traditional to sustainable construction [12]. Therefore, the enablers of “Industry” and “Government rules, regulations and support” provide contextual and operational support to social sustainability in construction projects.
Some functions such as human resource development or health and safety can be treated at a project level, but they cut across the boundaries of project, industry, and the government, which provide the context and activities, practices and culture, and rules and processes, respectively. Lastly, the “Community” enabler follows both functional and attributive categorization, in that, the community acts to support or oppose the project as a function of their stakes in the project, proximity with the project, or legal claim on the project. Additionally, the community shares attributes and characteristics that enable them to achieve social sustainability. The overlap between “Community” and “Stakeholder” enablers is interesting. Though the community is represented as a stakeholder [23], the developed framework treats it as an external entity influencing and being influenced by the project from a distance [31]. Stakeholders, on the other hand, are internal and external entities that closely interact with the project. These include clients, shareholders, government bodies, donor agencies, and project personnel including the technical and non-technical workforce of contractors, consultants, designers, and architects [66,67,68]. This distant interaction of the community is not so characteristic of the close cooperation that the project has with the primary stakeholders, which are often contractually bound. So, the enablers of the developed framework can be grouped into functions (human resource development, safety and health), attributes (project, industry, and government), and a combination of both (community and stakeholder). Also, the framework provides the means and ends of sustainability and, while treating the community and stakeholders as superimposed enablers, provides the basis to enable sustainability through the other enablers.

2.3. Synthesis of Sub-Indicators

After extracting the sub-indicators and recording them in an MS Excel sheet, they were synthesized. In doing so, similar sub-indicators are merged. This is carried out to avoid duplication, as sub-indicators with different words yet referring to the same concept are found in the literature. For example, “regular health check-ups of drivers” and “health check-ups for employers” [12] are merged into a combined sub-indicator “health check-ups” and placed under the “Site health and safety” [28] indictor.
Moreover, this was carried out to combine related sub-indicators under the umbrella of a more generic as well as representative sub-indicator. For example, “safety issues” [5] is merged with the “fatality rate caused by wrong construction systems” [12] as well as the “number of health-related premature deaths caused by the negative impact of freight transport” [13]. Then, it is placed in the framework as the sub-indicator “Fatality rate caused by wrong construction systems” categorized into “Site health and safety” [1,10] under the “Safety and health” [43] enabler in the framework.
To highlight the most significant sub-indicators, two-stage content analysis is performed. The purpose was to include only those sub-indicators in the framework that have a numerically higher presence in the literature and are considered qualitatively important. This could help in eliminating sub-indicators that are either very specific to particular case studies or represent a much smaller breakdown of a more generic sub-indicator. In doing so, the frequency of each sub-indicator is counted in the first stage. This means that the number of papers having a particular sub-indicator is cumulated. Additionally, in the second stage, a qualitative assessment is carried out on the scale of high, medium, and low, showing the contextual importance of a sub-indicator within each paper. For this purpose, each paper was carefully read to understand the importance of a sub-indicator reported there. For example, the sub-indicator “job security” reported as “employment stability” was interpreted to have a high score by Kumar and Anbanandam [13], since it is given a Fuzzy performance importance weight of 1.557, with the highest score being 1.9. However, this sub-indicator reported as “perceived job security” had a low score by Zuo et al. [40], since it had a frequency of 8 (50%) with the highest frequency being 16 (100%).
Based on their modal value, the qualitative score from each paper for every sub-indicator is determined and then converted to a semi-quantitative scale where low = one, medium = three, and high = five. After the qualitative and quantitative scoring, a final literature score is calculated through combined qualitative and quantitative scores as given in Equation (1). The quantitative score is normalized by dividing the frequency by 28 (total number of papers), and the qualitative score is normalized by dividing the modal value by 5 (the highest score value).
Literature score = (Cumulative frequency/28) × (Qualitative score/5)
Finally, screening is performed on the normalized cumulative score of above 50%, which represents a simple majority of the selected factors in driving their overall impact. This approach has been reported in several studies aimed at framework development [69,70,71].
To enhance the applicability of the developed framework, a measurement unit is synthesized for each sub-indicator from the literature. In doing so, the prescribed unit is recorded from each paper and then all the used units are proposed in the framework. It is important to mention that the proposed units are homogenous for all the sub-indicators, such as the Likert scale, and there is no case where the proposed units present any conceptual or metrological contradiction. Owing to the contextual and subjective nature of social sustainability assessment, all the sub-indicators are measured over the Likert scale.

3. Results and Discussion

Following the structured methodology, the social sustainability framework is synthesized, as shown in Table 3. The framework follows a typical structure in which it has enablers, indicators, and sub-indicators. As previously mentioned, the sub-indicators have been sourced from the published literature, and the remaining hierarchy is synthesized through their schematic analysis. As such, there are a total of 7 enablers, 27 indicators, and 76 sub-indicators. In the following sections, the entire framework is discussed.

3.1. Stakeholder

The first enabler for social sustainability in construction projects is the stakeholder. The stakeholder theory underscores the fundamental idea behind the notion of sustainable conduct. A stakeholder is the seed of unpredictability and subjectivity in the decision making of infrastructure and construction projects. Therefore, firms must consider stakeholders and community interests to ensure their long-term prosperity and survival [72]. Since each stakeholder plays a key role in an organization’s social responsibility, it is important to ensure that all stakeholders are identified and their interests are met [73]. However, not every system can satisfy all the needs of all the stakeholders, but it must satisfy the needs of many stakeholders. Moreover, the focus must not be only on short-term, static efficiencies such as productivity and profitability but also on long-term, dynamic efficiencies such as learning and innovations [74]. Moreover, corporate sustainability can be defined as meeting the needs of a firm’s direct and indirect stakeholders (such as shareholders, employees, clients, pressure groups, communities, etc.), without compromising its ability to meet the needs of future stakeholders as well [6]. Corporate social responsibility (CSR), or corporate sustainability management (CSM), refers to the new management discipline by which an organization can take steps to measure, manage, and report its impacts on society and the environment [75]. So, improving the social sustainability performance of construction projects can have a significant impact on the health, safety, education, wellbeing of people, etc. It also enhances the quality of life for people by demonstrating their social corporate responsibility and commitment.
The stakeholder as an enabler in this framework is made up of four indicators and nine sub-indicators.
Stakeholder and user participation and engagement as a first indicator is influenced by the degree to which the project incorporates the stakeholder’s opinions into operational decision making [1,12,28]. It has been reported that stakeholder participation in the early project stages helps create the final product as close to stakeholder perception and needs as possible [76]. This process helps the project meet the functionality needs of users and amenities such as easy access to parking [21,23,44]. Furthermore, the aesthetic properties of the project should be taken into consideration, as well as the landscape and visual impact on the neighborhood. This helps to align the project with the stakeholder expectations and enhances cooperation for mutual decision making.
Therefore, stakeholder collaboration and conflict management are affected by cooperation through sharing documents and the lessons learned during the planning and design phases to improve planning and decision making for current and future projects [1]. However, this sharing needs to follow formal, documented, and structured processes. Therefore, strategizing and developing effective partnering relationships are other important factors in stakeholder collaboration and conflict management. For example, determining the scope of activity, clarifying and specifying key objectives and responsibilities, the commitment of specific financial resources such as cash, equity, and accomplishing the ultimate goals [1,44]. A lack of such an effective partnering relationship will drive wages and cause dissatisfaction among the stakeholders.
Thus, user satisfaction [31,41] should be seen as a priority in stakeholder accessibility and satisfaction, which is influenced by user participation in the design so that decision makers, designers, architects, engineers, and experts can understand and anticipate their needs [21]. For instance, analyzing the impact of the project location on access to public transit, biking opportunities, safe walking routes, and green spaces can affect stakeholder accessibility and satisfaction [1,21,28,76]. Moreover, the choice of construction methods and materials should be aligned to increase the wellness and productivity of final users. In housing and building projects, this can be performed by providing quality housing, meeting the residents’ indoor and space needs, etc. [10,21].
Putting this all together, it is essential to identify the needs of stakeholders and effectively communicate with them. This involves openly communicating and hearing all the needs and complaints of stakeholders as well as exchanging information [1,28,67]. Open and effective communication and engagement will ensure that the opinion of a stakeholder is heard and taken into account in critical decision making, which will close the loop through higher satisfaction. This will help resolve conflicts among the stakeholders, as open communication will pave the way for more engagement and understanding of each other’s point of view.

3.2. Safety and Health

The safety of the working environment on the project site significantly affects the social sustainability of construction projects. Regarding safe working environments, most of the sustainability literature (including the Brundtland Report) mentions safe and healthy living and working conditions as a key component of social sustainability. Socially sustainable firms should pursue all reasonable means to reduce hazards on their projects [8]. The construction process should be well planned and managed to reduce the risk of accidents. As Gatti, Migliaccio, Bogus, Priyadarshini and Scharrer [24] stated, monitoring workers’ physical strain is important to enhance the social sustainability of the construction industry. They surveyed industry practitioners to gain insight into industry needs and challenges for physical strain monitoring.
Safety and health as an enabler in this framework are organized into seven indicators and twenty sub-indicators.
Safety climate and culture refers to an organization’s beliefs, character, and attitudes manifested in actions, policies, and procedures that affect its safety performance [77]. The concept of safety climate and culture is influenced by the safety and health care index of the jurisdiction where the project is executed [21]. So, improving safety climate and culture will result in reduced incidents and better safety performance [78]. However, achieving an improved culture will need multidimensional concerted efforts—one of which is health and safety literacy and education, which should be an important step. This kind of literacy and education includes several aspects such as economic, social, technical, etc. One of the technical aspects is safety prevention techniques that prevent or minimize occupational hazards and risks during construction, such as the analysis of the sequence of construction activities and the use of prefabrication techniques [10,28]. Besides, it is also influenced by induction to work areas and ongoing occupational health and safety training [40,41].
The end user’s health and safety are affected by providing a safe and secure public facility. This includes the provision of secure and safe open places, paths, and facilities for the public. Furthermore, including security considerations for the final users in the project design will positively impact its social sustainability [30,31]. To improve the occupational health and safety of facility users during post-occupancy, it is pertinent to involve the health and safety professionals during the design stage. These experts in the design and execution team help in analyzing the health impacts of the project on the end users and those of the construction activities on the community [1,28].
The construction activities raise several site-related health and safety issues in the form of constant disturbance and stress on residents. Examples are the stress caused by heavy traffic and congestion on the road, noise, dust, and pollution [12,13]. This stress can be reduced through proactive and preventive design measures. Apart from the residents, creating safe places where the workers also feel safe in the community influences site health and safety. In this regard, site layout considering safety issues as well as performing health check-ups, providing appropriate medical and first aid facilities for physical injuries, and psychological health check-ups for mental health improve site health and safety. Additionally, the right, functional, and well-maintained equipment is also important. Thus, sufficient access to personal protective equipment and regular vehicle maintenance affect on-site health and safety.
All these measures help improve overall health and safety performance. One important aspect of this performance is regulatory, in which the conformity of the project with the current health and safety regulations, including certification, public safety, and fair work requirements certifies the preparedness and performance of the project. Therefore, a supporting and compliant environment must be made available to and created by the project stakeholders. For example, the level of compliance with safety standards should be determined and the construction safety rules should be followed [13,21,30]. This will help ensure a safe and reliable workplace [10] and reduce accidents and fatalities, including the number of construction-related deaths due to safety issues as well as health-related premature deaths caused by the negative impact of construction projects [13].
Lastly, all of this has to be formally embedded into the project contract. For that purpose, healthy and safe procurement through the hiring of subcontractors considering their safety management abilities and the adoption of value engineering to improve construction safety is crucial [28]. Besides, incorporating social considerations, such as health, productivity, and quality of life, into a return on investment analysis will affect healthy and safe procurement [10]. Principally, to be appealing in its entirety, the business case for social sustainability has to be substantiated by economic and financial gains in the short to mid-term.

3.3. Human Resource Development

The development of human resources is the process of enhancing and unleashing human expertise through organization development and personnel training. It helps improve individual as well as organizational performance [79]. Despite its significant role in the economy and the importance of quality human resources to its performance, human resource development is not accorded priority in the industry [80]. This jeopardizes the social sustainability of construction projects.
Human resource development as an enabler in this framework is made by three indicators and seven sub-indicators.
Jobs and employment in the construction sector are affected by job security [1,12,13,41], fair and clear employment practices and methods [12,40], and creating jobs and investment opportunities [5,31,44]. For instance, encouraging businesses to invest in the area by incentivizing them to relocate can improve job opportunities and provide better employment.
Training in the construction industry globally usually means the provision of basic vocational training in various construction skills [80]. The enabler of education and training is influenced by access to education and training [1,13,40,43]. For instance, project managers must have access to education and training programs that enable them to update their skills [81]. Training employees is highly important, as better-trained and educated people are more valuable to a business [40].
However, it is not sufficient to create employment opportunities or train the employees for the sake of higher productivity. The employees must be motivated and incentivized, since their commitment is affected by rewards. The whole point of providing pay for performance is that additional financial rewards can be given to those who perform well. Thus, it acts as an incentive [82]. Rewards and incentives are impacted by limited working times [12,43]. Adequate breaks and reasonable working hours are perceived as critical criteria of social sustainability, otherwise the employees might feel like bonded labor [83]. The limited working times help reduce stress and fatigue-related injuries, offer better work-life balance, and improve the well-being of workers. In this regard, an employer should not insist on the employees working unreasonable hours, as they may feel “bullied” due to the fear of losing jobs [40]. Furthermore, not only must negative motivation be minimized, but positive motivation must be maximized through frequent wage revision and leave and rest time [12,13].

3.4. Project

Project-related factors are inputs to social sustainability practice that can directly or indirectly lead to project success. They encompass many factors, which have to be harmonized to ensure social sustainability. From an operational perspective, these factors are manageable at the project level. Thus, achieving social sustainability by addressing and optimizing them is relatively easier than those that are managed at higher levels. This dimension is gaining a lot of momentum lately [84,85].
The project as an enabler in this framework is made up of five indicators and fourteen sub-indicators.
Procurements and claims as the first indicator are influenced by a fair code of conduct [12,13]. Any excess or prejudice will harm the acceptance and reputation of the project, diminishing its social sustainability. The reputation may also be tarnished if the employees have a reason to believe that their claims are not restituted in a timely and fair manner. Therefore, the claims of workers and employees should be timely and fairly managed. Additionally, the material storage and warehousing must also be fair, in which any losses due to employee faults must be fairly yet compassionately restituted [12].
Project management is not only limited to its traditional success criteria but must have a broader view concerning sustainability [84]. However, it requires willing and capable project managersSilvius and de Graaf [86]. It also requires effective management of the project team. Therefore, teamwork with respect and honesty should be incorporated into the site discipline. Project team interaction is impacted by working together as a team with respect and honesty [1]. This will be possible when there are willing and capable members in a team. Thus, project planning and management are impacted by human capital [1,28], which is an intangible asset or quality that differentiates an organization from others. Human capital captures the economic value of experience and skill such as the qualification, training, intelligence, behavior, health, loyalty, and punctuality that employers value. The willingness and capability of the management go one step ahead of where the understanding of potential benefits [86] drives the application of green building practices throughout the design and construction processes [44]. It is also found that socially sustainable management of construction projects presents possibilities of integrating social concerns in management processes at various levels, ranging from permanent firms that provide resources to temporary project organizations that deliver value [47]. In this regard, regular taxes paid by the company [5,12] and the selection of design and construction firms with a sustainability focus [1,10] are a testament to a firm’s commitment to sustainability. Along with that, efficient pricing [23] and project cost and finance analyses [5] in the form of cost–benefit assessment, planning, and construction costs, escalating cost, sources, and terms of funds are the financial indicators and drivers that influence the commitment to social sustainability.
The social sustainability of construction sites is also influenced by the availability of amenities such as the provision of necessities such as toilets, water, rest areas, first aid, worship places, etc., to site personnel as well as the proximity of the project to public transportation and other amenities such as hospitals, shopping centers, etc. [5,31,44].
However, it is not sufficient to be mindful of the project personnel only, as neighbors and other potential affectees must also be considered. Thus, construction projects must not look inside but also outside to ensure that they do not disrupt the normal life in and around them too much. So, it is opportune to develop and provide a plan to minimize disruption caused by the construction process [1,23,44]. Their management includes controlling noise level, pollution, glare, and waste produced by the project, eliminating nuisances (such as poor air quality, odor, vibration, congestion, and dust) during construction, reducing disruption to existing facilities, and ensuring provision for access to areas surrounding the construction. The disruption can also be eliminated by providing alternative facilities such as the provision of car parks and the development of alternative traffic plans around the project [21,31].

3.5. Industry

Industry-related factors represent one step higher than project-related factors. To address these factors, merely better and more responsible project management will not be sufficient. It will require changes at the level of the entire construction industry to make some impact. This enabler in the current framework is divided into four indicators and seven sub-indicators.
The social performance of the construction industry is influenced by corrupt practices [10,12], which are influenced by social aspects [87] and severely impact the social sustainability of the construction industry. The social performance extends to ensuring preventive actions against child and bonded labor [43] as well as failure due to latent conditions. This includes resilient planning enabling future expansions due to population growth, which means design for future construction plans must be based on forecasted future needs [44].
Furthermore, the construction industry may also ensure social sustainability by engaging, training, and hiring local labor, businesses, and suppliers [1,28]. This involves vernacular design to enable the use of local construction labor and suppliers. In addition, not only is engaging the local supply chain at its current capacity sufficient, but these supply chain actors can be empowered by improving construction innovativeness [12,13]. For instance, the use of innovative construction technologies and products to reduce the ecological and social burden of construction projects.

3.6. Community

Community is key to the effectiveness of strategies aimed at enhancing the social sustainability of construction projects. Community, as an enabler, is organized into two indicators and fifteen sub-indicators.
Social sustainability at the community level starts from acknowledging its importance and its infrastructure and institutional needs. So, community importance is influenced by improving local infrastructure capacity [31,44] through rehabilitation of the existing infrastructure assets as well as improved interoperability with the present facilities and future development plans to meet future needs. Community importance is also impacted by adopting a holistic approach through management of further community infrastructure needs arising from the project (e.g., water, power) [43]. These assets and infrastructures will help maintain a productive and socially engaged community.
Social engagement also involves ancillary services, such as rehabilitation of local communities. The community-based rehabilitation service is a multidisciplinary service that uses a case coordination mentality approach to provide comprehensive assessment and targeted treatment to people in need of such services within a home-based setting. This impacts the community or social capital [12,13], which is the accumulated goodwill that builds trust between community groups.
Construction projects indirectly impact the community by influencing or altering the local social fabric. Therefore, it is important to assess the impact of introducing new social classes into the surrounding community (e.g., a community in which low-income housing is proposed might perceive the new social class as a threat based on stereotypes and misconceptions) [10]. Where one stands in the social hierarchy has broad implications on their health, family life, education, and other living habits. So, it is important to analyze the effect of the project on the local community’s cultural and ethnic identity [23,28]. The project will affect the neighboring properties and their value. This social impact on the community must be effectively monitored [10] through a social impact assessment of the project. Moreover, the community should be protected during the construction or demolition phases of the project [40]. For instance, establish a roadmap for the continuing assessment of the impact of the project on the local communities until it is operational.
Community importance is also influenced by the social and institutional relationships of the community. This includes cultural heritage preservation, social cohesion, protection of human rights, etc. [5,23,30]. This does not have to recognize only the international declarations but must also consider national, regional, and local declarations and customs. This goes on to proactively and immediately address community concerns and perceptions [10]. Such perceptions can be broader, such as support for primary education in communities [13], and equal access [30] are considered important factors of community importance.
All these functions are built into and leveraged through community participation and engagement, and the first rung of this ladder is paying heed to the community concerns and perceptions [28,44] through meeting the community needs in pursuing development and active engagement [23,43] through public discussion and transparency. This indicator is also affected by designing the project in a way that represents the local character and identity of the community [10,44]. This will only be possible if community concerns are heard. To address such aspects, a diverse design team including participants from various professions, genders, races, and firm sizes should be selected. Moreover, reflecting public art in the neighborhood (such as color harmonization) should also be taken into consideration. The optics of socially sustainable development go a long way with the community.

3.7. Government Rules, Regulations and Support

Smart and proactive governance is at the core of social sustainability [88], and not everything can be managed by stakeholders at the project, industry, or community level. Some higher powers in the form of legislation, support, and patronage need to come into play to enhance the social sustainability of construction projects. The synthesized framework contains the enabler of government, which is organized into two indicators and five sub-indicators.
The first and foremost job of a government is to bring about enabling legislation, and in that, the provision of rules and regulations is influenced by trade and tariff barriers [12,30] indicating the economic affordability of sustainability-related laws. The support offered by governments must ensure the applicable laws and policies such as land use, sector planning, and consistency with existing economic and social development are followed [1,12].
In addition to offering enabling legislation, a government’s role in providing a level playing field is also crucial. This is done through equity and human rights by ensuring social justice and recognizing the different statuses of relevant stakeholders [12,42]. This is important to share the quantity and quality of information with stakeholders. Moreover, in the interest of social cohesion and to provide transparency, the public should be educated about planning and design progress. Social empowerment through voting rights and political freedom is also identified as an influential sub-indicator. Lastly, social empowerment also demands safeguarding the consumer and human rights. By putting in place the human rights grievance mechanism as well as ensuring the protection of human rights and freedom, it enhances the social sustainability of the construction sector [12,13].

4. Conclusions

Social sustainability is a less focused area of sustainability both in the literature and in practice. This results in subjective assessment and vague recommendations. Not only the rec-ommendations coming out of social impact assessments are elusive but also the taxonomy to precisely and comprehensively measure it is subjective and contextual. Due to the lack of a standardized taxonomy, practitioners are left to pick and choose the measurement variables of social sustainability quite instinctively resulting in questionable reliability. The subjectivity in social sustainability assessment can be minimized under a comprehensive assessment framework and using diverse, representative, and reliable input data sources. For this purpose, the current study develops a comprehensive framework of social sustainability in construction projects based on the review of published research. In doing so, it extracts the relevant articles and identifies and cat-egorizes the different contributors to social sustainability.
Precisely, a systematic review methodology is employed in which journal papers published until 2021 in the area of social sustainability in the construction industry were reviewed. The findings are based on the synthesis of 28 selected papers where either one or more influencing factors on social sustainability are discussed. To develop the social sustainability framework, the shortlisted research papers were carefully read to cover more than one factor. This was done to ensure broad coverage of factors against the minimum effort. Identification of the criteria for measuring the social sustainability of construction projects is the main contribution of this review to the body of knowledge. The categorization offers an intuitive and methodical view of social sustainability. This paper facilitates an improved balance among the triple bottom line components of sustainability in construction projects by proposing a comprehensive assessment framework. With the hierarchy of framework components in place, the next area of concern will be establishing the aggregation approach to make the whole process unified while assessing social sustainability. Aggregation of parameters needs to take into account the scale effects and varying nature of parameters as for some, the higher values and for others, the lower values are preferable. Normalization of parameters using the Diaz-Balteiro equation is an effective solution for problems relating to the aggregation of parameters [89,90,91].
To identify the relative importance of different factors representative of social sustainability in the construction industry, a survey or structured interviews with experts need to be conducted. The development of an unbiased and fully representative framework can only be possible by improving upon the limitations of previous research and by understanding the perspective of experts in this area. The subjective sub-indicators used in social sustainability assessment can be measured on a Likert scale of 1–7 or 1–5 [91,92].
The outcomes of this research are expected to have a significant impact on the improvement of social sustainability by offering a holistic approach to investigating the influencing factors. The framework significantly contributes to research and practice. Practitioners and policymakers can use the framework as a guideline to plan, gauge, and improve efficiency in implementation practices and researchers can benefit from the structure and collection of sub-indicators, indicators, and enablers for their research.
This research like other literature reviews has some limitations that should be acknowledged. The framework can be enhanced as it is based on a limited number of studies since this topic is evolving as well as the choice of keywords can be broadened. Some papers that could have been included in developing the framework are [93,94]. Also, since the synthesis is based upon the core collection of Scopus, an intrinsic limitation in terms of the coverage of publications may be affected. Also, specific themes can be used as a search string to include papers focused on particular sub-areas of social sustainability. This could improve the number of papers and give out a fairly large sample of papers by dramatically increasing the set of keywords to ensure comprehensive coverage of relevant literature. Moreover, the absence of empirical evidence is out of the scope of this study, it could be the starting point for future research to empirically explore and validate the proposed framework by engaging with the industry experts and by putting it into practice.

Author Contributions

All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Nasirzadeh, F.; Ghayoumian, M.; Khanzadi, M.; Rostamnezhad Cherati, M. Modelling the social dimension of sustainable devel-opment using fuzzy cognitive maps. Int. J. Constr. Manag. 2019, 20, 223–236. [Google Scholar]
  2. Taticchi, P.; Tonelli, F.; Pasqualino, R. Performance measurement of sustainable supply chains: A literature review and a research agenda. Int. J. Product. Perform. Manag. 2013, 62, 782–804. [Google Scholar] [CrossRef]
  3. Neely, A.; Edgeman, R.; Eskildsen, J.; Ahi, P.; Searcy, C. Measuring social issues in sustainable supply chains. Meas. Bus. Excell. 2015, 19, 33–45. [Google Scholar]
  4. Josa, I.; Aguado, A. Infrastructures and society: From a literature review to a conceptual framework. J. Clean. Prod. 2019, 238, 117741. [Google Scholar] [CrossRef]
  5. Valentin, V.; Bogus, S.M. Assessing the link between public opinion and social sustainability in building and infrastructure projects. J. Green Build. 2015, 10, 177–190. [Google Scholar] [CrossRef]
  6. Dyllick, T.; Hockerts, K. Beyond the business case for corporate sustainability. Bus. Strategy Environ. 2002, 11, 130–141. [Google Scholar] [CrossRef]
  7. Assefa, G.; Frostell, B. Social sustainability and social acceptance in technology assessment: A case study of energy technologies. Technol. Soc. 2007, 29, 63–78. [Google Scholar] [CrossRef]
  8. Toole, T.M.; Carpenter, G. Prevention through Design as a Path toward Social Sustainability. J. Arch. Eng. 2013, 19, 168–173. [Google Scholar] [CrossRef]
  9. Hussin, J.M.; Rahman, I.A.; Memon, A.H. The Way Forward in Sustainable Construction: Issues and Challenges. Int. J. Adv. Appl. Sci. 2013, 2, 15–24. [Google Scholar] [CrossRef]
  10. Valdes-Vasquez, R.; Klotz, L.E. Social Sustainability Considerations during Planning and Design: Framework of Processes for Construction Projects. J. Constr. Eng. Manag. 2013, 139, 80–89. [Google Scholar] [CrossRef]
  11. Montalbán-Domingo, L.; Pellicer, E.; García-Segura, T.; Sanz-Benlloch, A. An integrated method for the assessment of social sus-tainability in public-works procurement. Environ. Impact Assess. Rev. 2021, 89, 106581. [Google Scholar] [CrossRef]
  12. Hendiani, S.; Bagherpour, M. Developing an integrated index to assess social sustainability in construction industry using fuzzy logic. J. Clean. Prod. 2019, 230, 647–662. [Google Scholar] [CrossRef]
  13. Kumar, A.; Anbanandam, R. Development of social sustainability index for freight transportation system. J. Clean. Prod. 2019, 210, 77–92. [Google Scholar] [CrossRef]
  14. Kordi, N.E.; Belayutham, S.; Che Ibrahim, C.K.I. Mapping of social sustainability attributes to stakeholders’ involvement in con-struction project life cycle. Constr. Manag. Econ. 2021, 39, 513–532. [Google Scholar] [CrossRef]
  15. Sharifi, A.; Murayama, A. Viability of using global standards for neighbourhood sustainability assessment: Insights from a comparative case study. J. Environ. Plan. Manag. 2015, 58, 1–23. [Google Scholar] [CrossRef]
  16. Robinson, B. From Marketing to Master Plan: An Environmental Sustainability Analysis of Toronto’s East Harbour EcoDistrict. Available online: http://hdl.handle.net/1974/26167 (accessed on 8 March 2022).
  17. Arshad, H.; Thaheem, M.; Bakhtawar, B.; Shrestha, A. Evaluation of Road Infrastructure Projects: A Life Cycle Sustainability-Based Decision-Making Approach. Sustainability 2021, 13, 3743. [Google Scholar] [CrossRef]
  18. Guinée, J. Handbook on life cycle assessment—Operational guide to the ISO standards. Int. J. Life Cycle Assess. 2001, 6, 255. [Google Scholar] [CrossRef]
  19. Goedkoop, M.; Oele, M.; Leijting, J.; Ponsioen, T.; Meijer, E. Introduction to LCA with SimaPro. Report Version 5.2. Recuperado a Partir de. 2016. Available online: www.pre-sustainability.com (accessed on 8 March 2022).
  20. Wang, Q.; Liu, C.; Hou, Y.; Xin, F.; Mao, Z.; Xue, X. Study of the spatio-temporal variation of environmental sustainability at national and provincial levels in China. Sci. Total Environ. 2021, 807, 150830. [Google Scholar] [CrossRef]
  21. Ahmad, T.; Thaheem, M.J. Developing a residential building-related social sustainability assessment framework and its implica-tions for BIM. J. Sustain. Cities Soc. Nat. Resour. 2017, 28, 1–15. [Google Scholar] [CrossRef]
  22. Martins, A.N.; Farias, J.S. Inclusive sustainability within favela upgrading and incremental housing: The case of Rocinha in Rio de Janeiro. Sustain. Dev. 2019, 27, 205–213. [Google Scholar] [CrossRef]
  23. Doloi, H. Community-Centric Model for Evaluating Social Value in Projects. J. Constr. Eng. Manag. 2018, 144, 04018019. [Google Scholar] [CrossRef]
  24. Gatti, U.; Migliaccio, G.; Bogus, S.M.; Priyadarshini, S.; Scharrer, A. Using Workforce’s Physiological Strain Monitoring to Enhance Social Sustainability of Construction. J. Arch. Eng. 2013, 19, 179–185. [Google Scholar] [CrossRef]
  25. Kaminsky, J.A. National Culture Shapes Private Investment in Transportation Infrastructure Projects around the Globe. J. Constr. Eng. Manag. 2018, 144, 04017098. [Google Scholar] [CrossRef]
  26. Kaminsky, J. The global influence of national cultural values on construction permitting. Constr. Manag. Econ. 2019, 37, 89–100. [Google Scholar] [CrossRef]
  27. Stender, M.; Walter, A. The role of social sustainability in building assessment. Build. Res. Inf. 2018, 47, 598–610. [Google Scholar] [CrossRef]
  28. Rostamnezhad, M.; Nasirzadeh, F.; Khanzadi, M.; Jarban, M.J.; Ghayoumian, M. Modelling social sustainability in construction projects by integrating system dynamics and fuzzy-DEMATEL method: A case study of highway project. Eng. Con-Struction Arch. Manag. 2020, 27, 1595–1618. [Google Scholar] [CrossRef]
  29. Hu, X.; Chong, H.-Y.; Wang, X. Sustainability perceptions of off-site manufacturing stakeholders in Australia. J. Clean. Prod. 2019, 227, 346–354. [Google Scholar] [CrossRef]
  30. Rohman, M.A.; Doloi, H.; Heywood, C.A. Success criteria of toll road projects from a community societal perspective. Built Environ. Proj. Asset Manag. 2017, 7, 32–44. [Google Scholar] [CrossRef]
  31. Almahmoud, E.; Doloi, H. Assessment of social sustainability in construction projects using social network analysis. Facilities 2015, 33, 152–176. [Google Scholar] [CrossRef]
  32. Li, H.; Zhang, X.; Ng, S.T.; Skitmore, M.; Dong, Y.H. Social Sustainability Indicators of Public Construction Megaprojects in China. J. Urban. Plan. Dev. 2018, 144, 04018034. [Google Scholar] [CrossRef] [Green Version]
  33. Goel, A.; Ganesh, L.; Kaur, A. Project management for social good. Int. J. Manag. Proj. Bus. 2020, 13, 695–726. [Google Scholar] [CrossRef]
  34. Fatourehchi, D.; Zarghami, E. Social sustainability assessment framework for managing sustainable construction in residential buildings. J. Build. Eng. 2020, 32, 101761. [Google Scholar] [CrossRef]
  35. Koke, B.; Moehler, R.C. Earned Green Value management for project management: A systematic review. J. Clean. Prod. 2019, 230, 180–197. [Google Scholar] [CrossRef]
  36. Cheng, F.-F.; Huang, Y.-W.; Yu, H.-C.; Wu, C.-S. Mapping knowledge structure by keyword co-occurrence and social network analysis. Libr. Hi Tech. 2018, 36, 636–650. [Google Scholar] [CrossRef]
  37. Siddaway, A.P.; Wood, A.M.; Hedges, L.V. How to Do a Systematic Review: A Best Practice Guide for Conducting and Reporting Narrative Reviews, Meta-Analyses, and Meta-Syntheses. Annu. Rev. Psychol. 2019, 70, 747–770. [Google Scholar] [CrossRef]
  38. Christidis, T.; Pintar, K.D.M.; Butler, A.J.; Nesbitt, A.; Thomas, M.K.; Marshall, B.; Pollari, F. Campylobacter spp. Prevalence and Levels in Raw Milk: A Systematic Review and Meta-Analysis. J. Food Prot. 2016, 79, 1775–1783. [Google Scholar] [CrossRef] [PubMed]
  39. Oraee, M.; Hosseini, M.R.; Edwards, D.J.; Li, H.; Papadonikolaki, E.; Cao, D. Collaboration barriers in BIM-based construction net-works: A conceptual model. Int. J. Proj. Manag. 2019, 37, 839–854. [Google Scholar] [CrossRef]
  40. Zuo, J.; Jin, X.-H.; Flynn, L. Social sustainability in construction–an explorative study. Int. J. Constr. Manag. 2012, 12, 51–63. [Google Scholar] [CrossRef]
  41. Doloi, H. Assessing stakeholders’ influence on social performance of infrastructure projects. Facilities 2012, 30, 531–550. [Google Scholar] [CrossRef]
  42. Chasey, A.D.; Agrawal, N.A.D.; Agrawal, N. A Case Study on the Social Aspect of Sustainability in Construction. In ICSDEC 2012; American Society of Civil Engineers: Reston, VA, USA, 2012; pp. 543–551. [Google Scholar]
  43. Hossain, M.U.; Poon, C.S.; Dong, Y.H.; Lo, I.M.; Cheng, J.C. Development of social sustainability assessment method and a comparative case study on assessing recycled construction materials. J. Int. J. Life Cycle Assess. 2018, 23, 1654–1674. [Google Scholar] [CrossRef]
  44. Karji, A.; Woldesenbet, A.; Khanzadi, M.; Tafazzoli, M. Assessment of Social Sustainability Indicators in Mass Housing Construction: A Case Study of Mehr Housing Project. J. Sustain. Cities Soc. Nat. Resour. 2019, 101697. [Google Scholar] [CrossRef]
  45. Karakhan, A.A.; Gambatese, J.; Simmons, D.R. Development of Assessment Tool for Workforce Sustainability. J. Constr. Eng. Manag. 2020, 146, 04020017. [Google Scholar] [CrossRef]
  46. Almahmoud, E.; Doloi, H.K. Identifying the key factors in construction projects that affect neighbourhood social sustainability. Facil. 2020, 38, 765–782. [Google Scholar] [CrossRef]
  47. Goel, A.; Ganesh, L.; Kaur, A. Social sustainability considerations in construction project feasibility study: A stakeholder salience perspective. Eng. Constr. Arch. Manag. 2020, 27, 1429–1459. [Google Scholar] [CrossRef]
  48. Montalbán-Domingo, L.; Aguilar-Morocho, M.; García-Segura, T.; Pellicer, E. Study of Social and Environmental Needs for the Selection of Sustainable Criteria in the Procurement of Public Works. Sustainanility 2020, 12, 7756. [Google Scholar] [CrossRef]
  49. Kawesittisankhun, K.; Pongpeng, J. Social Sustainability: Satisfying Owners and Communities by Multilevel Strategies of Con-tractors. Sustainability 2020, 12, 2131. [Google Scholar] [CrossRef] [Green Version]
  50. Hosny, H.E.; Ibrahim, A.H.; Eldars, E.A. Development of infrastructure projects sustainability assessment model. Environ. Dev. Sustain. 2021, 1–39. [Google Scholar] [CrossRef]
  51. Stanitsas, M.; Kirytopoulos, K. Underlying factors for successful project management to construct sustainable built assets. Built Environ. Proj. Asset Manag. 2021; ahead-of-print. [Google Scholar] [CrossRef]
  52. Novelo, R.A.A.; Álvarez Romero, S.O.; Suárez, G.A.C.; Ramírez, J.D.M. Social Sustainability in the Planning, Design, and Construction in Developing Countries: Guidelines and Feasibility for México. Civ. Eng. Arch. 2021, 9, 1075–1083. [Google Scholar] [CrossRef]
  53. Pham, H.; Pham, T.; Dang, C.N. Barriers to corporate social responsibility practices in construction and roles of education and government support. Eng. Constr. Arch. Manag. 2021; ahead-of-print. [Google Scholar] [CrossRef]
  54. Braun, V.; Clarke, V. Using thematic analysis in psychology. Qual. Res. Psychol. 2006, 3, 77–101. [Google Scholar] [CrossRef] [Green Version]
  55. Derakhshan, R.; Turner, R.; Mancini, M. Project governance and stakeholders: A literature review. Int. J. Proj. Manag. 2019, 37, 98–116. [Google Scholar] [CrossRef]
  56. Hale, J.; Legun, K.; Campbell, H.; Carolan, M. Social sustainability indicators as performance. Geoforum 2019, 103, 47–55. [Google Scholar] [CrossRef]
  57. Peenstra, R.; Silvius, G. Enablers for Considering Sustainability in Projects; the Perspective of the Supplier. Procedia Comput. Sci. 2017, 121, 55–62. [Google Scholar] [CrossRef]
  58. Lee, S.Y.; Klassen, R.D. Drivers and enablers that foster environmental management capabilities in small-and medium-sized suppliers in supply chains. Prod. Oper. Manag. 2008, 17, 573–586. [Google Scholar] [CrossRef]
  59. Rajak, S.; Vinodh, S. Application of fuzzy logic for social sustainability performance evaluation: A case study of an Indian au-tomotive component manufacturing organization. J. Clean. Prod. 2015, 108, 1184–1192. [Google Scholar] [CrossRef]
  60. George, R.A.; Siti-Nabiha, A.; Jalaludin, D.; Abdalla, Y.A. Barriers to and enablers of sustainability integration in the performance management systems of an oil and gas company. J. Clean. Prod. 2016, 136, 197–212. [Google Scholar] [CrossRef]
  61. Munny, A.A.; Ali, S.M.; Kabir, G.; Moktadir, M.A.; Rahman, T.; Mahtab, Z. Enablers of social sustainability in the supply chain: An example of footwear industry from an emerging economy. Sustain. Prod. Consum. 2019, 20, 230–242. [Google Scholar] [CrossRef]
  62. Mani, V.; Gunasekaran, A.; Papadopoulos, T.; Hazen, B.; Dubey, R. Supply chain social sustainability for developing nations: Evi-dence from India. Resour. Conserv. Recycl. 2016, 111, 42–52. [Google Scholar] [CrossRef]
  63. Marcelino-Sádaba, S.; González-Jaen, L.F.; Pérez-Ezcurdia, A. Using project management as a way to sustainability. From a comprehensive review to a framework definition. J. Clean. Prod. 2015, 99, 1–16. [Google Scholar] [CrossRef]
  64. Hussain, M.; Ajmal, M.M.; Gunasekaran, A.; Khan, M. Exploration of social sustainability in healthcare supply chain. J. Clean. Prod. 2018, 203, 977–989. [Google Scholar] [CrossRef]
  65. Khan, M.; Ajmal, M.; Hussain, M.; Helo, P. Barriers to social sustainability in the health-care industry in the UAE. Int. J. Organ. Anal. 2018, 26, 450–469. [Google Scholar] [CrossRef]
  66. Zhao, Z.-Y.; Zhao, X.-J.; Zuo, J.; Zillante, G. Corporate social responsibility for construction contractors: A China study. J. Eng. Des. Technol. 2016, 14, 614–640. [Google Scholar] [CrossRef]
  67. Ma, L.; Wang, L.; Wu, K.-J.; Tseng, M.-L. Assessing co-benefit barriers among stakeholders in Chinese construction industry. Resour. Conserv. Recycl. 2018, 137, 101–112. [Google Scholar] [CrossRef]
  68. Afolabi, A.; Ibem, E.; Aduwo, E.; Tunji-Olayeni, P.; Oluwunmi, O. Critical Success Factors (CSFs) for e-Procurement Adoption in the Nigerian Construction Industry. Buildings 2019, 9, 47. [Google Scholar] [CrossRef] [Green Version]
  69. Khan, R.A.J.; Thaheem, M.J.; Ali, T.H. Are Pakistani homebuyers ready to adopt sustainable housing? An insight into their will-ingness to pay. Energy Policy 2020, 143, 111598. [Google Scholar] [CrossRef]
  70. Ahmad, Z.; Thaheem, M.J.; Maqsoom, A. Building information modeling as a risk transformer: An evolutionary insight into the project uncertainty. Autom. Constr. 2018, 92, 103–119. [Google Scholar] [CrossRef]
  71. Ullah, F.; Ayub, B.; Siddiqui, S.Q.; Thaheem, M.J. A review of public-private partnership: Critical factors of concession period. J. Financial Manag. Prop. Constr. 2016, 21, 269–300. [Google Scholar] [CrossRef]
  72. Ehrgott, M.; Reimann, F.; Kaufmann, L.; Carter, C.R. Social Sustainability in Selecting Emerging Economy Suppliers. J. Bus. Ethics 2010, 98, 99–119. [Google Scholar] [CrossRef]
  73. Duckworth, H.A.; Moore, R.A. Social Responsibility: Failure Mode Effects and Analysis; CRC Press: Boca Raton, FL, USA, 2010. [Google Scholar]
  74. Docherty, P.; Kira, M.; Shani, A.R. Creating Sustainable Work Systems: Developing Social Sustainability; Routledge: London, UK, 2008. [Google Scholar]
  75. McElroy, M.W.; Jorna, R.J.; van Engelen, J. Sustainability quotients and the social footprint. Corp. Soc. Responsib. Environ. Manag. 2008, 15, 223–234. [Google Scholar] [CrossRef]
  76. Goosen, H.; Vellinga, P. Experiences with restoration of inland freshwater wetlands in the Netherlands: Lessons for science and policy-making. Reg. Environ. Change 2004, 4, 79–85. [Google Scholar] [CrossRef] [Green Version]
  77. Guldenmund, F.W. The nature of safety culture: A review of theory and research. Saf. Sci. 2000, 34, 215–257. [Google Scholar] [CrossRef]
  78. Kalteh, H.O.; Mortazavi, S.B.; Mohammadi, E.; Salesi, M. The relationship between safety culture and safety climate and safety performance: A systematic review. Int. J. Occup. Saf. Ergon. 2021, 27, 206–216. [Google Scholar] [CrossRef]
  79. Nguyen, H.T.; Hadikusumo, B.H. Human resource related factors and engineering, procurement, and construction (EPC) project success. J. Financ. Manag. Prop. Constr. 2018, 23, 24–39. [Google Scholar] [CrossRef]
  80. Debrah, Y.A.; Ofori, G. Human resource development of professionals in an emerging economy: The case of the Tanzanian construction industry. Int. J. Hum. Resour. Manag. 2006, 17, 440–463. [Google Scholar] [CrossRef]
  81. Ellis, R.C.; Wood, G.D.; Thorpe, T. Technology-based learning and the project manager. Eng. Constr. Arch. Manag. 2004, 11, 358–365. [Google Scholar] [CrossRef]
  82. Cooper, D.J. Improving People Performance in Construction; Gower Publishing, Ltd.: Aldershot, UK, 2004. [Google Scholar]
  83. Upadhyaya, K. Bonded Labour in South. Asia: India, Nepal and Pakistan The Political Economy of New Slavery; Springer: Berlin/Heidelberg, Germany, 2004; pp. 118–136. [Google Scholar]
  84. Stanitsas, M.; Kirytopoulos, K.; Leopoulos, V. Integrating sustainability indicators into project management: The case of con-struction industry. J. Clean. Prod. 2021, 279, 123774. [Google Scholar] [CrossRef]
  85. Shah, S.; Ganji, E.N. Sustainability adoption in project management practices within a social enterprise case. Manag. Environ. Qual. Int. J. 2019, 30, 346–367. [Google Scholar] [CrossRef]
  86. Silvius, A.G.; de Graaf, M. Exploring the project manager’s intention to address sustainability in the project board. J. Clean. Prod. 2019, 208, 1226–1240. [Google Scholar] [CrossRef]
  87. Owusu, E.K.; Chan, A.P.C.; Shan, M. Causal Factors of Corruption in Construction Project Management: An Overview. Sci. Eng. Ethics 2019, 25, 1–31. [Google Scholar] [CrossRef]
  88. Lin, Y.; Zhang, X.; Geertman, S. Toward smart governance and social sustainability for Chinese migrant communities. J. Clean. Prod. 2015, 107, 389–399. [Google Scholar] [CrossRef]
  89. Bragança, L.; Mateus, R.; Koukkari, H. Building sustainability assessment. Sustainability 2010, 2, 2010–2023. [Google Scholar] [CrossRef] [Green Version]
  90. Díaz-Balteiro, L.; Romero, C. In search of a natural systems sustainability index. Ecol. Econ. 2004, 49, 401–405. [Google Scholar] [CrossRef]
  91. Ahmad, T.; Thaheem, M.J. Economic sustainability assessment of residential buildings: A dedicated assessment framework and implications for BIM. Sustain. Cities Soc. 2018, 38, 476–491. [Google Scholar] [CrossRef]
  92. Akber, M.Z.; Thaheem, M.J.; Arshad, H. Life cycle sustainability assessment of electricity generation in Pakistan: Policy regime for a sustainable energy mix. Energy Policy 2017, 111, 111–126. [Google Scholar] [CrossRef]
  93. Sierra, L.A.; Yepes, V.; García-Segura, T.; Pellicer, E. Bayesian network method for decision-making about the social sustainability of infrastructure projects. J. Clean. Prod. 2018, 176, 521–534. [Google Scholar] [CrossRef]
  94. Montalbán-Domingo, L.; García-Segura, T.; Sanz, M.A.; Pellicer, E. Social sustainability criteria in public-work procurement: An international perspective. J. Clean. Prod. 2018, 198, 1355–1371. [Google Scholar] [CrossRef]
Figure 1. Literature review process.
Figure 1. Literature review process.
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Figure 2. The process of creating the framework.
Figure 2. The process of creating the framework.
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Figure 3. The organization of enablers in the framework.
Figure 3. The organization of enablers in the framework.
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Table 1. Search strings, restrictions, and results.
Table 1. Search strings, restrictions, and results.
Search EngineStrings and RefinementsResults
Scopus(TITLE-ABS-KEY (“social sustainability”) AND TITLE-ABS-KEY (“construction industry”) OR TITLE-ABS-KEY (“construction project”) OR TITLE-ABS-KEY (“construction management”) OR TITLE-ABS-KEY (“project management”) OR TITLE-ABS-KEY (“infrastructure project”))178
AND PUBYEAR <2022177
AND (LIMIT-TO (“journal”))112
AND (Screening of titles/abstract/full text)94
AND (Content analysis)52
AND (Second step screening)28
Table 2. Selected papers for framework development.
Table 2. Selected papers for framework development.
AuthorsFocus of StudyStudy LocationContextApproach
Zuo et al. [40]Stakeholder-ConstructionA qualitative approach was used and semi-structured interviews of 16 industry professionals were conducted.
Doloi [41]StakeholderAustraliaInfrastructureA quantitative approach was used. A university building case study was run and a questionnaire survey of 25 respondents was performed.
Valdes-Vasquez and Klotz [10]Wide-ranging framework with a focus on the planning and design phasesUSAConstructionA quantitative approach was used along with performing a questionnaire survey of 25 experts in academia, industry, and government.
Chasey and Agrawal [42]Wide-ranging frameworkUSAConstructionA qualitative approach was used, and a case study in the Advanced Technology Facility Sector was used.
Almahmoud and Doloi [31]StakeholderSaudi ArabiaConstructionA quantitative approach was used. A building project was used as a case study. Also, a questionnaire survey of 20 experts across the project was performed.
Valentin and Bogus [5]Wide-ranging frameworkUSABuilding and infrastructure projectsA qualitative approach was used, and eight case studies of building and infrastructure projects were used.
Ahmad and Thaheem [21]Wide-ranging frameworkPakistanResidential buildingA mixed-method approach was used. A case study of a low-rise residential building was used. Besides, a questionnaire survey of 66 respondents from research and education disciplines was conducted.
Rohman et al. [30]CommunityIndonesiaToll road projectA quantitative approach was used. A toll road project was used as a case study. 206 respondents from three stakeholder groups (government, private, and end-users communities) were surveyed
Doloi [23]CommunityAustraliaInfrastructureA quantitative approach was used. A toll road project in Melbourne was used as a case study. A questionnaire survey was also performed on 25 respondents.
Hossain et al. [43]Construction materialsHong KongConstruction materialA mixed-method approach was used. And a case study on construction materials was conducted. A case-specific survey was performed through 40 responses.
Karji et al. [44]Wide-ranging frameworkIranMass housingA quantitative approach was used. A Mehr Housing Project in Iran was used as a case study. A two-stage questionnaire survey was performed by collecting 128 and 62 responses from the residents of the project and the construction industry experts, respectively.
Kumar and Anbanandam [13]Wide-ranging frameworkIndiaFreight infrastructureA quantitative approach was used. An Indian freight transportation project was used as a case study. A questionnaire survey was also performed on 8 experts.
Hendiani and Bagherpour [12]Wide-ranging framework-ConstructionA quantitative approach was used. A questionnaire survey was also performed by participating 7 experts.
Nasirzadeh et al. [1]Wide-ranging frameworkIranConstructionA mixed-method approach was used. A building project was used as a case study. A questionnaire survey was also performed with the participation of 10 experts.
Rostamnezhad et al. [28]Wide-ranging frameworkIranHighway projectA mixed-method approach was used. A Qom-Mashhad highway project in Iran was used as a case study. A questionnaire survey was also performed with the participation of 12 experts.
Karakhan et al. [45]WorkforceUSAConstructionA mixed-methods approach that relied on semi-structured interviews and surveys was utilized. This process involved interviewing six experts—four industry professionals and two academics.
Almahmoud and Doloi [46]CommunitySaudi ArabiaConstructionA quantitative approach was used. Two case studies of regeneration projects in Saudi Arabia were used as case studies. Also, a questionnaire survey was performed with the participation of 102 respondents.
Goel et al. [33]Wide-ranging framework-ConstructionA quantitative approach was used. Knowledge abstraction was performed through thematic analysis
Goel et al. [47]StakeholderIndiaConstructionA mixed-method approach was used. Feasibility study reports for 61 projects were obtained from various government organizations in India.
Montalbán-Domingo et al. [48]Wide-ranging frameworkEU countriesConstructionA qualitative approach was used. 451 tendering documents from 10 European countries were analyzed.
Fatourehchi and Zarghami [34]Wide-ranging frameworkIranConstructionA quantitative approach was used. Also, a questionnaire survey was performed by participating 50 construction specialists and 15 academic researchers.
Kawesittisankhun and Pongpeng [49]Wide-ranging frameworkThailandConstructionA qualitative approach was used. Also, a questionnaire survey was performed by 225 participants from the construction sector. Interviews with six experts were also used to test the content validity of the questionnaire.
Montalbán-Domingo et al. [11]Wide-ranging framework-ConstructionA mixed-method approach was used. A questionnaire survey was also performed on 12 experts.
Hosny et al. [50]Wide-ranging framework-InfrastructureA qualitative approach was used. Besides, a questionnaire of 100 infrastructure development experts from various sectors was conducted.
Stanitsas and Kirytopoulos [51]Wide-ranging framework-ConstructionA qualitative approach was used. Also, semi-structured interviews were conducted with 6 experts from academia and industry.
Novelo et al. [52]Wide-ranging frameworkMexicoConstructionA qualitative approach was used. Semi-structured interviews of 5 participants from different disciplines were conducted. Also, a survey was performed by obtaining 79 responses from academic and industry participants.
Pham et al. [53]Wide-ranging frameworkVietnamConstructionA qualitative approach was used. Moreover, using a survey questionnaire, empirical data are collected from 17 construction firms in Vietnam through 137 questionnaires.
Kordi et al. [14]Wide-ranging framework-ConstructionA qualitative approach was used. Systematic Reviews and Meta-Analyses (PRISMA) methodology was also used.
Table 3. Social sustainability framework.
Table 3. Social sustainability framework.
EnablersIndicatorsSub-indicatorsProject Phase
StakeholderStakeholder and user participation and engagementThe project incorporates stakeholder’s opinions into operational decision-makingAll phases
The project stakeholders agree with the project functions and amenitiesInitiation and planning phases
Stakeholder collaboration and conflict managementLessons learned during the planning and design phases are documented and shared with all stakeholdersPlanning phase
Partnering strategies are applied for resolving interpersonal conflicts among project stakeholdersInitiation phase
Stakeholder accessibility and satisfactionFinal users participate in the design so that decision-makers can understand and anticipate their needsPlanning phase
Designs increase the wellness and productivity of the final usersPlanning and execution phases
Impact of the project location on access to public transit, biking opportunities, safe walking routes, and green spacesInitiation and planning phases
The level of satisfaction among usersAll phases
Stakeholder needs identification and communicationThere is open communication among all stakeholders regarding their needsAll phases
Safety and healthSafety climate and cultureSafety and health care indexPlanning and execution phases
Health and safety literacy and educationPrevention through design is incorporatedPlanning phase
Induction to work areas and ongoing OH&S trainingPlanning and execution phases
Health and safety professionalsHealth and safety professionals are part of the design and execution team to help analyze health impacts on the final users and the communityInitiation, planning, and execution phases
Health and safety performanceThe project conforms to current regulations, including certification, public safety, and fair work requirementPlanning, execution, and monitoring and control phases
There is a safe and reliable workplaceExecution and monitoring and control phases
Site health and safetyFatality rate caused by wrong construction systemsExecution and monitoring and control phases
Safe places are created where workers can feel safe in the communityExecution phases
Site layout considers safety issuesPlanning phase
Health check-upsExecution phase
Stress on residents is caused by construction operationsExecution and monitoring and control phases
There are appropriate medical centers for injured workersExecution phase
There is a psychological health check of the workforceExecution phase
Materials robberyExecution phase
Sufficient access to personal protective equipmentExecution phase
Regular vehicle maintenanceExecution phase
Healthy and safe procurementSubcontractors are hired considering their safety management abilitiesPlanning phase
Value Engineering is performed to improve construction safety issuesPlanning phase
Social considerations are incorporated into a return-on-investment analysisInitiation and planning phases
End-user health and safetyThere is a safe and secure public facility for final usersPlanning, execution, and closing phases
Human resource developmentEducation and trainingEducation and training opportunities are provided for employees and project staffInitiation and planning phases
Jobs and employmentThere is job security for employees and project staffAll phases
There are jobs and investment opportunitiesInitiation phase
There are fair and clear employment practices/methodsAll phases
Rewards and incentivesLimited working times are availableAll phases
Wage revision is regularly carried outInitiation and execution phases
Leave and rest time are providedInitiation and execution phases
ProjectProcurements and claimsA fair code of conduct is in practiceAll phases
Claims of workers and employees are properly handledAll phases
Material losses due to employee faults happenExecution phases
Project planning and managementHuman capitalAll phases
Local governments engage in design so that decision-makers can understand and anticipate their needsPlanning phase
Green building practices are applied throughout the design and construction processesPlanning and execution phases
Regular taxes are paid by the companyAll phases
Design and construction firms with a sustainability focus are selectedPlanning phases
Efficient pricing is practicedPlanning and execution phases
Project cost and finance are effectively managedInitiation and planning phases
AmenitiesImportant amenities are providedPlanning and execution phases
The project is close to public transportation and amenitiesPlanning phase
Group/team interactionEveryone works as a team with respect and honestyAll phases
Disruptions caused by construction projectsPlanning to minimize disruption caused by the construction process is donePlanning and monitoring and control phases
Traffic management around the project is donePlanning and execution phases
IndustrySocial performanceThere are corrupt practices in constructionAll phases
Preventative actionsPrevention of child and bonded labor is guaranteedAll phases
Resilient planning is done to enable future expansions due to population growthPlanning phase
Local labor/supplierLocal labor is trained, and local businesses are hiredPlanning and execution phases
Supplier/business-related issuesThere is an improvement in construction innovativenessPlanning and execution phases
CommunityCommunity importanceThere is an improvement in local infrastructure capacityInitiation and planning phases
New/additional community infrastructure needs resulting from the project are managedInitiation and planning phases
Local communities are rehabilitatedClosing phase
Community CapitalAll phases
There is an impact of introducing new social classes into the surrounding communityPlanning and closing phases
The project impacts the cultural and ethnic identity of the surrounding communityPlanning and closing phases
The actual social impact on the community is monitoredClosing phase
The social and institutional relationships toward the community are managedAll phases
There is a quick response to community concerns and perceptionsAll phases
The community is protected during the construction/demolition of a projectAll phases
Primary education is supported in communitiesAll phases
There is equal access for all communityPlanning phase
Community participation and engagementCommunity concerns and perceptions are heardAll phases
The project is designed in a way that represents the local character and identity of the communityPlanning phase
Public involvement, discussion, and transparency are ensuredAll phases
Government rules, regulations and supportProvision of rules and regulationsThere are trade and tariff barriersAll phases
There is compliance with relevant laws and policies such as land use, sector plan, cohesion with existing economic and social developmentAll phases
Equity and human rightsSocial justice and equity are ensured, and the different status of relevant stakeholders is recognizedAll phases
Voting rights and political freedom are upheldAll phases
Consumer and human rights are protectedAll phases
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Rostamnezhad, M.; Thaheem, M.J. Social Sustainability in Construction Projects—A Systematic Review of Assessment Indicators and Taxonomy. Sustainability 2022, 14, 5279. https://doi.org/10.3390/su14095279

AMA Style

Rostamnezhad M, Thaheem MJ. Social Sustainability in Construction Projects—A Systematic Review of Assessment Indicators and Taxonomy. Sustainability. 2022; 14(9):5279. https://doi.org/10.3390/su14095279

Chicago/Turabian Style

Rostamnezhad, Mozhdeh, and Muhammad Jamaluddin Thaheem. 2022. "Social Sustainability in Construction Projects—A Systematic Review of Assessment Indicators and Taxonomy" Sustainability 14, no. 9: 5279. https://doi.org/10.3390/su14095279

APA Style

Rostamnezhad, M., & Thaheem, M. J. (2022). Social Sustainability in Construction Projects—A Systematic Review of Assessment Indicators and Taxonomy. Sustainability, 14(9), 5279. https://doi.org/10.3390/su14095279

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