Sustainability Performance of Green Building Rating Systems (GBRSs) in an Integration Model
1
Department of Civil and Construction Engineering, National Taiwan University of Science and Technology, Taipei 106, Taiwan
2
Graduate Institute of Architecture & Sustainable Planning, National Ilan University, Yi-Lan 260007, Taiwan
*
Author to whom correspondence should be addressed.
Buildings 2022, 12(2), 208; https://doi.org/10.3390/buildings12020208
Submission received: 9 January 2022
/
Revised: 31 January 2022
/
Accepted: 4 February 2022
/
Published: 11 February 2022
(This article belongs to the Special Issue Sustainability and Life Cycle Assessment of Buildings)
Abstract
:In most countries, more than one green building rating system (GBRS) is available on the market. Because of their different approaches, it is difficult to confirm which system can respond to sustainability requirements better. A building considered to be “green” by one Green Building Council (GBC) may fail to satisfy the requirements set by another council. The aim of this study is to evaluate the sustainability performance of GBRSs and establish an integrated model of multi-certification for optimal sustainability. A direct content analysis method was utilized to evaluate GBRSs’ qualitative performance using the ISO sustainable building standards. In this study, seven purposively selected multi-certified buildings were evaluated, and an integrated model was proposed as a better mechanism for the multi-certification process. The proposed integrated model contributes to the achievement of sustainability indicators. The model was implemented on case study buildings, and the proposed combination shows better sustainability performance than existing practice. The developed model helps practitioners in their selection of GBRSs in the multi-certification process. In addition, the performance evaluation of GBRSs will support the future update of GBRSs. The qualitative performance evaluation was performed considering mandatory requirements and prerequisite and credit requirements of selected rating systems, making the work a stronger approach than previous studies.
1. Introduction
Sustainable building principles, a major part of sustainable construction, are mainly applied using green building rating systems (GBRSs). Acceptance of the systems has been increasing since their emergence [1,2,3]. Nowadays, several rating systems, from those in the local context to fully flexible international systems, such as the Sustainable Building Tool (SBTool) [4,5], are available on the market. However, the heterogeneity [6] of the GBRS approach and the contradictory results of the system performance [7,8] along with the benefits for users [9,10,11] have been believed to affect the wide acceptance of the approach, especially in developing nations.
One of the key challenges in the system is the difficulty in balancing the conflicting requirements among the main dimensions (i.e., environmental, social, and economic) [12]. Because of this challenge, the managers of building design and construction need more support to achieve the complete sustainability [13]. Doan, et al. [14] evaluated Leadership in Energy and Environmental Design (LEED), Building Research Establishment Environmental Assessment Method (BREEAM), Comprehensive Assessment System for Built Environment Efficiency (CASBEE), and Green Star New Zealand (Green Star NZ) according to the environmental, social, economic, and institutional “sustainability pillars” and concluded that they fail to balance and fulfill all requirements. Moreover, a building classified as green or sustainable by one rating system may not satisfy the requirements set by another rating system [15,16]. For these reasons, owners apply for more than one green building certification [17,18]. However, multiple certifications implemented so far lack clear objectives on sustainability, making the process less efficient. The availability of many rating systems in one country [19,20] and lack of a simple and user-friendly international checklist to evaluate the sustainability of heterogeneous indicators [21] in GBRSs make the selection of a rating system a complex task. Although some of the GBRSs are widely accepted and are promoting sustainability worldwide, because they are developed based on the country of origin’s situation they have limitations on balancing the developed and developing nations’ priority areas [22,23]. It is a difficult task to decide on which rating system to adopt and which one can respond to local sustainability priorities.
Most of the previous studies mainly focus on evaluating the rating system performance based on the weighting assigned to each category or criterion. This evaluation method has limitations because of the uncertainty [24] and subjectivity [25] of the weighting assignment. Moreover, the weighting of each category depends on the local priority area of assessment, yet some systems are adopted in many countries. These conditions motivated researchers to conduct qualitative performance evaluation using content analysis [26,27,28], which is more reliable than any other of unit of analysis method [29]. The content analysis was carried out based on the International Standards Organization (ISO) sustainable building indicators, the available international benchmark. The standard was also used by Liang et al. [30] to evaluate GBRSs’ performance on the “institutional” pillar. Multi-certified projects were analyzed to identify their contribution toward sustainability.
The case study evaluation result shows the impact of subjective selection of GBRSs on sustainability. For example, the LEED system and HQE have no assessment for a life cycle cost indicator. A dual-certified building from these systems lacks one of the essential economic aspect indicators. Because of inconsistency on the evaluated building performance, this study developed an integrated model that helps to achieve optimal sustainability that is from the perspective of balancing the three main pillars, incorporating seven core areas of protection (CAPs) and their indicators listed under the ISO sustainable building standards [31]. The developed model was validated using case studies of multi-certified buildings. This study mainly emphasizes sustainability performance rather than only the popularity of the GBRSs during the selection process. The objectives of the study are as follows:
- Evaluate GBRS sustainability performance using the ISO sustainable building indicators;
- Discuss the performance of selected multi-certified buildings based on the ISO indicators;
- Develop an integration model that helps practitioners in the selection of multiple GBRSs for a single project.
The previous studies conducted on multi-certified projects only show the differences in approach and the impact of rating system selection on level of certification. This is the first study on an integration model for selection of multiple rating systems on a single project. The model helps to balance qualitative indicators of the three main pillars and to achieve more sustainability indicators.
This paper is organized into six Sections. Section 2 focuses on GBRSs used in the study, previous studies in the area, and the sustainability principles in the ISO standard. Section 3 clarifies the method and procedure used in this study. Section 4 evaluates the GBRSs using the ISO standard. The results and discussion presented in Section 5 focus on evaluating the variation of parameters among the different rating systems, identifying the limitations of multi-certified buildings, and the application of the integrated model on selected cases. Finally, we draw conclusions on the study output in Section 6.
2. Materials and Methods
2.1. Selecting Rating Systems for the Study
To identify and select well-known rating systems, a review of the literature was carried out, and information on the websites of the World Green Building Council (WGBC) and the GBCs of different countries was collected. There is previous research on comparing the rating systems for certain countries or areas [32]. Selecting different rating systems influences the strategies to calibrate the design principles and construction methods, such as roof systems [33]. Because of the availability of many GBRSs globally, the researchers used purposive sampling to select rating systems. The following rating systems were selected for the following reasons. BREEAM is a leading method in building certification [34], and LEED is a widely accepted rating system [35] reaching 167 countries and territories. DGNB awarded certification in around 30 countries [36]; HQE certified projects in five continents [37], and both are popular systems in Europe [6]. The country of origin-focused rating systems, CASBEE [4,38,39] and ITACA (Istituto per l’innovazione e Trasparenza degli Appalti e la Compatibilita Ambientale) [40,41], are also well-known. Nowadays, CASBEE is expanding outside the country by certifying buildings in China [39].
Among the selected systems, ITACA has been included in the study sample because it is well-known from the SBTool-adopted methods. SBTool is an international standard managed by the International Initiative for Sustainable Built Environment [42], which has a different approach to most popular systems for evaluation and certification. To include one rating system from developing countries, a popular green star system family [3,43] that has been gaining acceptance in African countries and adopted in more than five countries [44], the Green Star South Africa (Green Star SA) was included in this study.
2.2. Sustainability: The Top Goal for Green Buildings
Previous studies have illustrated the difficulty in defining sustainable building when comparing variations in scoring and certification levels for the sample buildings. Suzer [15] compared the compliance and correlation between 20 dual-certified (LEED and BREEM) buildings and concluded that the LEED score and award level tended to be higher than that of BREEAM. Asdrubali, Baldinelli, Bianchi, and Sambuco [14] conducted a study to compare residential buildings certified by LEED and ITACA in Italy using five common parameters. The study showed that the ITACA evaluation score was higher than the LEED evaluation score. Cruz, et al. [45] developed a roadmap to ensure “sustainable sustainability” that helps to balance the main pillars. Other studies aimed to respond to common industry challenges by studying mechanisms to achieve more points [46], developing a new rating system for a specific country using various GBRSs and local situations [23,47,48], and some other studies developed rating systems based on stakeholder interest [49].
Sustainability should be the top goal based on the concept of the theory, science, and style of buildings [50]. It also has to contain the insights of life cycle assessment [51]. Although many studies have been conducted, they did not establish necessary mechanisms for achieving more sustainability indicators from existing GBRSs. By contrast, the activity of multi-certification is gaining greater acceptance in the industry [52,53]. However, no specific criteria are established for the selection of rating systems during the multi-certification process, and the contribution of multi-certificates is not clear yet.
The ISO 21929-1 set 14 major and 12 minor indicators. For the purpose of analysis, the 26 indicators in this study are adapted from ISO 21929-1 [31] and grouped into 19 based on their direct influence area (aspect) and the approach of GBRS use for evaluation. However, outdoor conditions, emission to air (troposphere), and heat island effect directly affect more than one aspect as specified in the standard, and they are grouped together, including nuisance on neighborhood (which has a direct effect on only one aspect), as “outdoor environment”, as shown in Table 1. Use of renewable resources and that of non-renewable resources have similar aims in green building assessment; therefore, they are merged and renamed as “resources”.
3. Research Approach
3.1. Sampling and Analysis Method
In this study, we propose a three-phase approach as shown in Figure 1 to achieve the aim of the study. The first phase is to select and evaluate GBRS candidates. The LEED, BREEAM, CASBEE, DGNB, HQE, Green Star SA, and ITACA protocols were the selected rating systems. Of the various manuals available in GBRSs, we selected the manual for new construction of office buildings, because office building types are leading in certification [34,36,54]. Various approaches of content analysis were used by researchers to evaluate sustainability performance [55,56,57]; therefore, direct content analysis [29,58,59,60] is adopted in this study as shown in Figure 2.
To identify the multi-certification gap, ISO indicators were used for evaluation. Since no specific database exists that helps identify multi-certified buildings, in this study available information collected by using beneficial keywords on literature and generic search platforms as well as GBC websites was used to select multi-certified buildings. Seven samples were selected using the following criteria: combination of certifications to represent GBRSs in this study, office building type, one sample from each combination, and availability of essential information for analysis [17,18,34,36,37,54,61,62]. There was no multi-certified combination identified from CASBEE, ITACA, and Green Star SA, and so they are not included in the analysis.
3.2. Development of Integrated Model
Desk study conducted on the existing practices of multi-certification indicates that there is no scientific model or approach that helps to select GBRSs for multi-certification. Moreover, the evaluation result of dual- and triple-certified buildings is inconsistent. A new integrated model that helps to achieve both ISO sustainable building indicators and developer interest was developed in this study as shown in Figure 3.
The first step in implementation of the model is selection of preferable rating systems for the project. This can be done based on the interest of the project owner or suggestion from experts. Rating systems such as LEED and DGNB have mandatory/minimum requirements that must be fulfilled by all projects. Therefore, the next step is checking whether the project can meet minimum requirements set by selected GBRSs. Because receiving higher certification increases the market value of a building, initial estimation of the certification level is conducted for the candidate rating systems. The rating systems that are deemed suitable for the project are then listed and evaluated for their ability to meet the ISO sustainable building indicators. The first candidate GBRS is selected depending on the interest of practitioners. If the first rating system cannot fully meet the ISO indicators, an integration procedure should be implemented until the combination fulfills the set requirements or achieves the ISO sustainable building benchmark indicators. Finally, the expert prepares an implementation plan, which considers aspects including the scope of the selected rating system, conflicting requirements, similar parameters, and the most dominant category or credit from similar parameters.
4. Evaluation of Green Building Rating Systems Using ISO Standard
Although ISO by itself has some limitations, it is the available international benchmark that balances the three main pillars sufficiently [30]. The ISO [31] indicators are suggestions for the development of a sustainable building rating system. Some credits and criteria in the rating systems can respond to the ISO indicator individually, whereas others must come together to respond to the indicators. For example, the serviceability of a building requires the engagement of owners or users during the design period, setting criteria of evaluation, and subsequent evaluation of user satisfaction after occupancy in terms of space design and other specified requirements.
5. Results and Discussion
5.1. Comparison of Evaluated Rating Systems
This study selected and evaluated seven GBRSs by using the ISO sustainable building requirements. Among the 14 major and 12 additional indicators of the ISO standard, safety in use and fire safety are covered only by the DGNB system. The effect of fire on the sustainability of a building and that of the chemicals used for firefighting on the environment [63] is enormous, and some less developed nations have limitations in implementing fire safety and safety in use issues. Most widely acceptable GBRSs should consider the global situation.
Most of the environmental aspect-related indicators in the ISO standard are considered by all seven rating systems included in the evaluation, whereas the economic aspect-related ISO indicators are considered less, as shown in Figure 4; this also poses a limitation in most GBRSs in responding to and balancing sustainability goals. The comparison of GBRS performance is summarized according to the three aspects as described in the following sections.
5.1.1. Environmental Aspects
Emission to air, which is measured using the global warming potential and ozone depletion potential, were assessed in the GBRSs by analyzing the effects of energy consumption, transportation, construction materials, and the refrigerant selection. Consumption of non-renewable energy, public and personal modes of transport, and maintainability of buildings are also related to emission to air. Therefore, some credits/issues, such as those for energy, transportation, and materials, can be used to fulfill more than one ISO requirement. Although all of the rating systems focused on energy consumption, transportation systems, and material usage as strategies to respond to global warming impact, CASBEE only evaluated bicycle usage as transportation and used other categories such as “Consideration of global warming” and “Air pollution” to assess global warming potential. LEED’s depth of assessment and its evaluation parameters are more detailed, compared with those of the other systems, for accounting for global warming.
The only rating system that does not consider ozone-depleting materials or refrigerant requirements is ITACA, while LEED and BREEAM set strict criteria. The LEED rating system requires that candidate buildings should eliminate CFC-based refrigerants in heating, ventilating, air-conditioning, and refrigeration (HVAC&R). In BREEAM, European standard and ISO minimum requirements must be satisfied to obtain the credits under “Impact of refrigerants”. Table 3 summarizes the environmental aspect-related ISO indicators with the corresponding credits/criteria of the seven GBRSs.
BREEAM, LEED, HQE, Green Star SA, and ITACA consider both the operational waste management systems and waste minimization and management during construction activities. The DGNB system mainly focuses on waste during construction activities and evaluates liquid waste management during the operation phase. The ISO standard mentions waste generation generally, and so all rating systems address this core area, regardless of the scope of assessment.
LEED, BREEAM, DGNB, CASBEE, and Green Star SA are found to be the strongest rating systems that respond to all ISO indicators in the environmental aspect, and HQE is the weakest. However, the method of assessment and the depth of criteria/requirement set vary from one GBRS to another.
5.1.2. Social Aspects
Studies show consideration of social aspects in green building development help to improve work comfort and productivity [64]. In Middle Eastern countries, the cultural issue is one of the essential parameters [23]. Only one indicator, “esthetic quality”, is available in the ISO to measure the cultural issue directly. The evaluation (Table 2) shows that, except CASBEE and DGNB, all of the remaining rating systems do not consider integration of cultural values in new building construction. The focus area of all of the evaluated rating systems is indoor conditions and air quality. The ISO also has a number of direct indicators for indoor air quality assessment. Unique among the rating systems, Green Star SA includes “Formaldehyde minimization” and “Mold prevention” as a part of the “Indoor environmental quality” assessment, whereas HQE assesses measures to “limit electromagnetic exposure”.
The green and open areas requirement in GBRSs and the accessibility of the building site (curtilage) in ISO standards have a similar target. Green Star SA and BREEAM do not include private space in the assessment of office buildings. LEED, CASBEE, and ITACA consider private or outdoor areas in their assessment, but they do not include accessibility requirements. In the LEED system, physical accessibility and level differences are considered; however, the rating system does not include specific evaluations for universal accessibility or accessibility restriction based on prosperity and wealth differences [31], which is one of the main targets of the ISO standard.
DGNB is the only rating system that fulfills all social aspect indicators of the ISO standard and Green Star SA shows the weakest performance. Preceding the environmental aspect, most rating systems criteria fall under social aspects, as shown in Table 4.
The BREEAM, DGNB, and CASBEE systems evaluate the resistance of structures to natural hazards. However, the CASBEE system focuses on earthquake hazards. Because the BREEAM and DGNB assessments consider most natural hazards that may occur, these systems are strong in the structural stability indicator of the safety criteria.
5.1.3. Economic Aspects
From the evaluated systems, the only rating system that responds to all economic aspects is BREEAM. However, to increase the acceptance of GBRSs in developing countries, it is essential to indicate economic benefits of the system [65,66], although studies show that energy efficiency and water efficiency can save up to 40% of life cycle cost [67], because high cost is one of the major barriers in green building [68]. Table 5 shows weakness of some rating systems, such as LEED, in this aspect.
In the ISO standard, life cycle cost is used as one of the major indicators for this pillar. Only BREEAM and DGNB consider this major indicator in their assessment strategies. In BREEAM, the “Life cycle cost and service life planning” and “Project brief and design” criteria are included, while the DGNB incorporates life cycle cost credits and additional assessment areas such as “influence on the district”, and “ease of cleaning” The value stability indicator of the ISO is one of the additional but essential indicators to respond to economic sustainability of green buildings. DGNB’s assessment areas for the building’s “influence on the district” and “commercial viability” criteria are most suitable to fulfill this indicator.
5.1.4. Indicators with Direct Effect on More Than One Aspect
Some of the ISO indicators directly impact more than one aspect as indicated in the ISO standard. Except “Nuisance on neighborhood”, which has a direct influence only on the social aspect, all indicators in a group named “outdoor environment” in this study have a direct effect on two aspects. HQE is the strongest system that considers all indicators in this group. The emission to air (troposphere) indicator is considered by all GBRSs except ITACA. Table 6 summarizes the three indicators with a direct effect on more than one aspect and their corresponding rating system criteria.
The analysis also shows that the qualitative depth of assessment varies across rating systems. Cases from multi-certified buildings are selected and evaluated to identify the benefits of existing multi-certification practice for sustainability, as shown in Table 7.
5.2. Evaluation of Multi-Certified Buildings
Seven cases from multi-certified buildings are considered for the evaluation, as shown in Table 7. The evaluation was conducted considering the sustainability limitations of the certification combination and individual GBRSs’ limitations identified in Table 2.
The Challenger building in France received the top-level certification from three popular GBRSs. The rating systems selected by experts are preferable for having many common criteria, minimizing conflicting requirements. However, from the perspective of the ISO sustainable building, they have limitations that come from a weak combination of rating systems. The BNP Paribas building in Luxembourg also received triple certification from three popular rating systems but with a different combination. Although the building achieved a low rating in the DGNB system, owing to the low performance in “site evaluation” (60.1%), “process quality” (62.7%), and “technical quality” (63.1%) [36], the combination selection of HQE, BREEAM, and DGNB is beneficial for sustainability evaluation.
All but one of the dual-certified buildings have their own limitations in sustainability indicators. Although the aim of the study is not about the performance of the building itself, this study identified variation in most buildings’ certifications, which is due to the designers’ preference of one rating system or the low performance of buildings in some GBRS criteria [15]. From the five combinations, the HQE and LEED combination (case 2) is the weakest combination.
The study finds that it is not the number of rating systems that makes the building fulfill the sustainability indicators (case 1 and case 4 have a similar combination deficiency) but the choice of the rating systems. The developed integrated model (Figure 3) is implemented on the case study buildings as described in the following section.
5.3. Application of Integrated Model
Multi-certification should consider many aspects that ensure that a building is acceptable for everyone. However, criteria conflict, and participation of various stakeholders [69] and accredited professionals in a project causes difficulties and challenges for integration. Therefore, while using the model shown in Figure 3, it is essential to identify possible conflicting requirements in the rating systems.
To implement and demonstrate the efficacy of the proposed model, this study selected two of the cases from combinations that fail to fulfill the ISO indicators and completed the integration process based on the model shown in Figure 3. To clarify the model process, case 1, the Challenger building in France, and case 2, the Max Frank building in Germany, shown in Table 7, were selected. The selection and integration process is shown in Figure 5.
For case 1, the model first selected the candidate rating systems for the project. In this study, all seven rating systems were selected for evaluation. Although the detailed evaluation of the building is not acquired from GBCs, this study utilized the LEED scorecard [54], and the level of achievement in the three rating systems indicates that the building can meet mandatory requirements of all candidate GBRSs; in addition, the building may be able to achieve a high score in other rating systems. Because of the preferences of the French green building market, we selected LEED, BREEAM, DGNB, and HQE for integration for this case. ITACA, CASBEE, and Green Star SA have no certification in France. To start the integration process, we first selected HQE as the first priority, because it is a local rating system and widely accepted in the country. For analysis purposes, the goal for the project is to achieve sustainability and to increase the (market) property value [70]. According to this goal, we chose to begin integration using DGNB to increase the sustainability assessment coverage. The two rating systems help evaluate all sustainable building indicators of the ISO. Because the interest was triple certification, the next integration was selected to increase the global influence of the building. Although both BREEAM and LEED are globally recognized rating systems, BREEAM is preferable in this scenario, because it is a more common system that is related to LEED in France [34,54]. As shown in Figure 5, the proposed model provides the suggestion that the combination of BREEAM, HQE, and DGNB are suitable and beneficial for this building, because these systems can assess more ISO indicators.
This study also utilized the proposed model for other cases. The second example selected for model application was the Tour First in France (case 2). Case 2 was preferred to other dual-certified buildings, because this case shows more deficiencies of combination from all cases. By applying the proposed model, we found that integrating either LEED or HQE with the DGNB systems can result in better coverage of the ISO sustainability indicators. A similar procedure was implemented on cases 4, 5 and 7, and the model shows better performance.
The seven buildings selected by this study received multiple certifications from well-known rating systems. The performance of the applied rating systems combination is not consistent, as shown in Table 7. We used the developed model and found that it is possible to create a better combination that considers both sustainability and popularity or market value during multi-certification. The model developed in this study can be used to achieve building sustainability, and it also can provide support to regional or any applicable standards for achieving complete sustainability.
6. Conclusions
The selection of GBRSs nowadays is dependent on the popularity of rating systems. This situation may lead to the industry missing the sustainability goals. This study was conducted to influence practitioners to pay more attention to sustainability performance than popularity of GBRSs during selection.
The first main contribution of this study is to build a model that helps to achieve more sustainability indicators. Seven multi-certified buildings were selected as case studies and evaluated using the ISO standard. The multi-certification practices have gaps in considering more sustainability. The developed integrated model was applied on case study buildings to validate its application. The results indicate that the proposed model can consider different scenarios of certification and assessment of more sustainability areas.
Another main contribution of this study is to demonstrate sustainability performance of existing GBRSs samples. This study evaluated the qualitative performances of the seven well-known GBRSs according to the ISO sustainable building criteria, which have relatively balanced indicators in the environmental, social, and economic aspects. The evaluation was conducted considering the mandatory requirements, prerequisites, and criteria that the rating systems use for certification. The evaluation results indicated that DGNB is the strongest in covering most of the ISO indicators. The BREEAM system is the only rating system that covers all economic aspect indicators of the ISO, which are the least considered by most of the rating systems. LEED and ITACA pay more attention to the environmental aspects, while the LEED depth of assessment in this aspect is stronger than the rest. CASBEE emphasizes the local scenario; HQE is the only rating system that evaluates all outdoor environment-related ISO indicators. The performance evaluation conducted in this study will help developers in their GBRSs selection and GBCs for their future updates of the systems.
The integrated model is the first scientific approach to integration of different GBRSs for multi-certified projects. The model was developed considering the heterogeneous approach of different GBRSs. The model is beneficial to considering the vast scope of sustainable construction and its core area of protection. The developed model can be utilized by accredited professionals, owners, or builders for decision-making on selecting a suitable combination from the available systems.
This model was developed based on the international sustainable building standard benchmark indicators. In practice, the sustainable building indicators may vary depending on project location, economic status of the nation, and other factors. For more practical utilization, the model proposed by this study can be extended in future research using international, regional, or national standards on selected new construction projects to elaborate more on the process and real challenges during the implementation of the model on multi-certification.
Author Contributions
Conceptualization, S.A. and H.-Y.L.; methodology, S.A. and H.-Y.L.; writing—original draft preparation, S.A. and H.-Y.L.; resources, S.A. and F.-J.S.; writing—review and editing, F.-J.S.; supervision, H.-Y.L. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Not applicable.
Conflicts of Interest
The authors declare no conflict of interest.
References
- Azhar, S.; Carlton, W.A.; Olsen, D.; Ahmad, I. Building information modeling for sustainable design and LEED® rating analysis. Autom. Constr. 2011, 20, 217–224. [Google Scholar] [CrossRef]
- De Paula, N.; Arditi, D.; Melhado, S. Managing sustainability efforts in building design, construction, consulting, and facility management firms. Eng. Constr. Archit. Manag. 2017, 24, 1040–1050. [Google Scholar] [CrossRef]
- Shan, M.; Hwang, B.-G. Green building rating systems: Global reviews of practices and research efforts. Sustain. Cities Soc. 2018, 39, 172–180. [Google Scholar] [CrossRef]
- Giarma, C.; Tsikaloudaki, K.; Aravantinos, D. Daylighting and Visual Comfort in Buildings’ Environmental Performance Assessment Tools: A Critical Review. Procedia Environ. Sci. 2017, 38, 522–529. [Google Scholar] [CrossRef]
- Mateus, R.; Bragança, L. Sustainability assessment and rating of buildings: Developing the methodology SBToolPT–H. Build. Environ. 2011, 46, 1962–1971. [Google Scholar] [CrossRef]
- Sánchez Cordero, A.; Gómez Melgar, S.; Andújar Márquez, J.M. Green Building Rating Systems and the New Framework Level(s): A Critical Review of Sustainability Certification within Europe. Energies 2020, 13, 66. [Google Scholar] [CrossRef] [Green Version]
- Gui, X.; Gou, Z. Association between green building certification level and post-occupancy performance: Database analysis of the National Australian Built Environment Rating System. Build. Environ. 2020, 179, 14. [Google Scholar] [CrossRef]
- Wu, X.; Lin, B.; Papachristos, G.; Liu, P.; Zimmermann, N. A holistic approach to evaluate building performance gap of green office buildings: A case study in China. Build. Environ. 2020, 175, 15. [Google Scholar] [CrossRef]
- Baja, F.; Bajracharya, S.; Freeman, M.A.; Gray, A.; Haglund, B.; Kuipers, H.R.; Opatola, O.R. LEED Gold but not equal: Two case study buildings. Int. J. Des. Nat. Ecodyn. 2019, 14, 52–62. [Google Scholar] [CrossRef]
- Liu, Y.; Wang, Z.; Lin, B.; Hong, J.; Zhu, Y. Occupant satisfaction in Three-Star-certified office buildings based on comparative study using LEED and BREEAM. Build. Environ. 2018, 132, 1–10. [Google Scholar] [CrossRef]
- Shurrab, J.; Hussain, M.; Khan, M. Green and sustainable practices in the construction industry. Eng. Constr. Archit. Manag. 2019, 26, 1063–1086. [Google Scholar] [CrossRef]
- Shi, Q.; Yan, Y.; Zuo, J.; Yu, T. Objective conflicts in green buildings projects: A critical analysis. Build. Environ. 2016, 96, 107–117. [Google Scholar] [CrossRef]
- Hwang, B.-G.; Ng, W.J. Project management knowledge and skills for green construction: Overcoming challenges. Int. J. Proj. Manag. 2013, 31, 272–284. [Google Scholar] [CrossRef]
- Doan, D.T.; Ghaffarianhoseini, A.; Naismith, N.; Zhang, T.; Ghaffarianhoseini, A.; Tookey, J. A critical comparison of green building rating systems. Build. Environ. 2017, 123, 243–260. [Google Scholar] [CrossRef]
- Asdrubali, F.; Baldinelli, G.; Bianchi, F.; Sambuco, S. A comparison between environmental sustainability rating systems LEED and ITACA for residential buildings. Build. Environ. 2015, 86, 98–108. [Google Scholar] [CrossRef]
- Suzer, O. Analyzing the compliance and correlation of LEED and BREEAM by conducting a criteria-based comparative analysis and evaluating dual-certified projects. Build. Environ. 2019, 147, 158–170. [Google Scholar] [CrossRef]
- Chamber of Commerce. BNP Paribas in Luxembourg Earns Triple Environmental Certification at European Level. Available online: https://www.corporatenews.lu/en/archives-shortcut/archives/article/2018/03/exceptional-hqe-excellent-breeam-and-gold-dgnb-bnp-paribas-in-luxembourg-earns-triple-environmental-certification-at-european-level?author=BGL+BNP+Paribas (accessed on 1 May 2021).
- Design Curial. Challenger Building Becomes World’s First to Obtain Triple Certification. Available online: http://www.designcurial.com/news/challenger-building-becomes-world-s-first-to-obtain-triple-certification (accessed on 10 June 2020).
- PLGBC. Polish Certified Green Buildings in Number. Available online: https://plgbc.org.pl/ (accessed on 5 February 2021).
- GBIG. Explore Green Buildings. Available online: http://www.gbig.org/ (accessed on 24 December 2021).
- Wallhagen, M.; Glaumann, M.; Eriksson, O.; Westerberg, U. Framework for Detailed Comparison of Building Environmental Assessment Tools. Buildings 2013, 3, 39–60. [Google Scholar] [CrossRef] [Green Version]
- Amasuomo, T.T.; Atanda, J.; Baird, G. Development of a Building Performance Assessment and Design Tool for Residential Buildings in Nigeria. Procedia Eng. 2017, 180, 221–230. [Google Scholar] [CrossRef]
- Al-Jebouri, M.F.A.; Saleh, M.S.; Raman, S.N.; Rahmat, R.A.A.B.O.K.; Shaaban, A.K. Toward a national sustainable building assessment system in Oman: Assessment categories and their performance indicators. Sustain. Cities Soc. 2017, 31, 122–135. [Google Scholar] [CrossRef]
- Berardi, U. Sustainability assessments of buildings, communities, and cities. In Assessing and Measuring Environmental Impact and Sustainability; Klemeš, J.J., Ed.; Butterworth-Heinemann: Oxford, UK, 2015; pp. 497–545. [Google Scholar]
- Awadh, O. Sustainability and green building rating systems: LEED, BREEAM, GSAS and Estidama critical analysis. J. Build. Eng. 2017, 11, 25–29. [Google Scholar] [CrossRef]
- Krippendorff, K.H. Content Analysis: An Introduction to Its Methodology, 3rd ed.; SAGE Publications Inc.: Washington, DC, USA, 2013; p. 96. [Google Scholar]
- Roca, L.C.; Searcy, C. An analysis of indicators disclosed in corporate sustainability reports. J. Clean. Prod. 2012, 20, 103–118. [Google Scholar] [CrossRef]
- Sobhani, F.A.; Amran, A.; Zainuddin, Y. Sustainability disclosure in annual reports and websites: A study of the banking industry in Bangladesh. J. Clean. Prod. 2012, 23, 75–85. [Google Scholar] [CrossRef]
- Aras, G.; Tezcan, N.; Kutlu Furtuna, O.; Hacioglu Kazak, E. Corporate sustainability measurement based on entropy weight and TOPSIS. Meditari Account. Res. 2017, 25, 391–413. [Google Scholar] [CrossRef]
- Liang, L.; Wen, B.; Musa, S.N.; Onn, C.C.; Ramesh, S.; Yan, J.; Wang, W. Rectify the performance of Green Building Rating Tool (GBRT) in sustainability: Evidence from ISO 21929-1. J. Clean. Prod. 2021, 278, 24. [Google Scholar] [CrossRef]
- ISO 21929-1:2011. Sustainability in Building Construction—Sustainability Indicators. Part 1: Framework for the Development of Indicators and a Core Set of Indicators for Buildings; ISO: Geneva, Switzerland, 2011; 42p. [Google Scholar]
- Lohmeng, A.; Sudasna, K.; Tondee, T. State of The Art of Green Building Standards and Certification System Development in Thailand. Energy Procedia 2017, 138, 417–422. [Google Scholar] [CrossRef]
- Naranjo, A.; Colonia, A.; Mesa, J.; Maury, H.; Maury-Ramírez, A. State-of-the-Art Green Roofs: Technical Performance and Certifications for Sustainable Construction. Coatings 2020, 10, 69. [Google Scholar] [CrossRef] [Green Version]
- BREEAM. Homepage of BREEAM. Available online: https://www.breeam.com/ (accessed on 18 May 2020).
- USGBC. Top 10 Countries and Regions for LEED Green Building. Available online: https://www.usgbc.org/articles/us-green-building-council-announces-top-10-countries-and-regions-leed-green-building (accessed on 18 May 2020).
- DGNB. Homepage of DGNB. Available online: https://www.dgnb.de/en/council/worldwide/ (accessed on 18 May 2020).
- HQE. Homepage of HQE. Available online: https://www.behqe.com/hqe-in-the-world/list-of-projects (accessed on 18 May 2020).
- Ali, H.H.; Al Nsairat, S.F. Developing a green building assessment tool for developing countries—Case of Jordan. Build. Environ. 2009, 44, 1053–1064. [Google Scholar] [CrossRef]
- CASBEE. Homepage of CASBEE. Available online: http://www.ibec.or.jp/CASBEE/english/index.htm (accessed on 17 May 2020).
- Mattoni, B.; Guattari, C.; Evangelisti, L.; Bisegna, F.; Gori, P.; Asdrubali, F. Critical review and methodological approach to evaluate the differences among international green building rating tools. Renew. Sustain. Energy Rev. 2018, 82, 950–960. [Google Scholar] [CrossRef]
- ITACA. Home Page of ITACA. Available online: https://www.itaca.org/indexs.asp (accessed on 18 July 2020).
- Baglivo, C.; Congedo, P.M.; Fazio, A. Multi-criteria optimization analysis of external walls according to ITACA protocol for zero energy buildings in the mediterranean climate. Build. Environ. 2014, 82, 467–480. [Google Scholar] [CrossRef]
- Wen, B.; Musa, N.; Onn, C.C.; Ramesh, S.; Liang, L.; Wang, W. Evolution of sustainability in global green building rating tools. J. Clean. Prod. 2020, 259, 17. [Google Scholar] [CrossRef]
- Agyekum, K.; Goodier, C.; Oppon, J.A. Key drivers for green building project financing in Ghana. Eng. Constr. Archit. Manag. 2021. ahead-of-print. [Google Scholar] [CrossRef]
- Cruz, C.O.; Gaspar, P.; de Brito, J. On the concept of sustainable sustainability: An application to the Portuguese construction sector. J. Build. Eng. 2019, 25, 8. [Google Scholar] [CrossRef]
- Vyas, G.S.; Jha, K.N.; Rajhans, N.R. Identifying and evaluating green building attributes by environment, social, and economic pillars of sustainability. Civ. Eng. Environ. Syst. 2019, 36, 133–148. [Google Scholar] [CrossRef]
- Akhanova, G.; Nadeem, A.; Kim, J.R.; Azhar, S. A multi-criteria decision-making framework for building sustainability assessment in Kazakhstan. Sustain. Cities Soc. 2020, 52, 11. [Google Scholar] [CrossRef]
- Khan, M.A.; Wang, C.C.; Lee, C.L. A Framework for Developing Green Building Rating Tools Based on Pakistan’s Local Context. Buildings 2021, 11, 202. [Google Scholar] [CrossRef]
- Karaca, F.; Guney, M.; Kumisbek, A.; Kaskina, D.; Tokbolat, S. A new stakeholder opinion-based rapid sustainability assessment method (RSAM) for existing residential buildings. Sustain. Cities Soc. 2020, 60, 13. [Google Scholar] [CrossRef]
- Ragheb, A.; El-Shimy, H.; Ragheb, G. Green Architecture: A Concept of Sustainability. Procedia Soc. Behav. Sci. 2016, 216, 778–787. [Google Scholar] [CrossRef] [Green Version]
- Mesa, J.A.; Fúquene-Retamoso, C.; Maury-Ramírez, A. Life Cycle Assessment on Construction and Demolition Waste: A Systematic Literature Review. Sustainability 2021, 13, 7676. [Google Scholar] [CrossRef]
- Ieong, N. Considering a Dual Certification for WELL/BREEAM? You Are Half Way to Go. Available online: https://teraoasia.com/2019/03/08/considering-a-dual-certification-for-wellbreeam-you-are-half-way-to-go/ (accessed on 10 May 2021).
- Marlow, A.T. LEED and BREEAM Move Closer Together. Available online: https://emsmastery.com/2012/07/03/leed-and-breeam-move-closer-together/ (accessed on 10 May 2021).
- USGBC. LEED Rating System. Available online: https://www.usgbc.org/leed (accessed on 18 May 2021).
- Hussain, N.; Rigoni, U.; Orij, R.P. Corporate Governance and Sustainability Performance: Analysis of Triple Bottom Line Performance. J. Bus. Ethics 2018, 149, 411–432. [Google Scholar] [CrossRef]
- Nobanee, H.; Ellili, N. Corporate sustainability disclosure in annual reports: Evidence from UAE banks: Islamic versus conventional. Renew. Sustain. Energy Rev. 2016, 55, 1336–1341. [Google Scholar] [CrossRef]
- Rebai, S.; Azaiez, M.N.; Saidane, D. A multi-attribute utility model for generating a sustainability index in the banking sector. J. Clean. Prod. 2016, 113, 835–849. [Google Scholar] [CrossRef]
- Goubran, S. On the Role of Construction in Achieving the SDGs. J. Sustain. Res. 2019, 1, 52. [Google Scholar] [CrossRef]
- Hsieh, H.-F.; Shannon, S.E. Three Approaches to Qualitative Content Analysis. Qual. Health Res. 2005, 15, 1277–1288. [Google Scholar] [CrossRef] [PubMed]
- Miyazaki, G.; Kawakubo, S.; Murakami, S.; Ikaga, T. How can CASBEE contribute as a sustainability assessment tool to achieve the SDGs? IOP Conf. Ser. Earth Environ. Sci. 2019, 294, 8. [Google Scholar] [CrossRef] [Green Version]
- HQE. Certimap. Available online: https://certimap.certivea.fr/ (accessed on 5 July 2021).
- CF Moller Architects. Company House III. Available online: https://www.cfmoller.com/p/Company-House-III-Skejby-i3016.html (accessed on 12 November 2021).
- Adams, R.; Simmons, D. Ecological effects of firefighting foams and retardants: A summary. Aust. For. 1999, 62, 307–314. [Google Scholar] [CrossRef]
- Grzegorzewska, M.; Kirschke, P. The Impact of Certification Systems for Architectural Solutions in Green Office Buildings in the Perspective of Occupant Well-Being. Buildings 2021, 11, 659. [Google Scholar] [CrossRef]
- Gobbi, S.; Puglisi, V.; Ciaramella, A. A Rating System for Integrating Building Performance Tools in Developing Countries. Energy Procedia 2016, 96, 333–344. [Google Scholar] [CrossRef] [Green Version]
- Adabre, M.A.; Chan, A.P.C. Towards a sustainability assessment model for affordable housing projects: The perspective of professionals in Ghana. Eng. Constr. Archit. Manag. 2020, 27, 2523–2551. [Google Scholar] [CrossRef]
- Assylbekov, D.; Nadeem, A.; Hossain, M.A.; Akhanova, G.; Khalfan, M. Factors Influencing Green Building Development in Kazakhstan. Buildings 2021, 11, 634. [Google Scholar] [CrossRef]
- Durdyev, S.; Mohandes, S.R.; Mahdiyar, A.; Ismail, S. What drives clients to purchase green building? The cybernetic fuzzy analytic hierarchy process approach. Eng. Constr. Archit. Manag. 2021. ahead-of-print. [Google Scholar] [CrossRef]
- Mok, K.Y.; Shen, G.Q.; Yang, R. Stakeholder Complexity in Large Scale GREEN building Projects. Eng. Constr. Archit. Manag. 2018, 25, 1454–1474. [Google Scholar] [CrossRef]
- WGBC. About Green Building. Available online: https://www.worldgbc.org/benefits-green-buildings (accessed on 10 December 2020).
Figure 1.
Research approach.
Figure 2.
Proposed evaluation system based on direct content analysis.
Figure 3.
Green building rating system integration model.
Figure 4.
ISO indicators consideration in seven GBRSs.
Figure 5.
Case 1: Integration process for multi-certification.
Table 1.
Sustainable building indicators adapted from ISO 21929-1 [31].
Table 1.
Sustainable building indicators adapted from ISO 21929-1 [31].
| Code | Indicators Group | Indicators | Aim | |
|---|---|---|---|---|
| 1 | Emission to air | A. | Global warming potential | Reduce greenhouse gas (GHG) emissions |
| B. | Ozone depletion potential | Minimize/avoid stratospheric ozone layer depilating materials | ||
| 2 | Resources ** | A. | Renewable and non-renewable resource consumption ** | Reduce non-renewable and use renewable/recycled material |
| B. | Renewable and non-renewable energy consumption ** | Enhance renewable energy and energy saving | ||
| 3 | Freshwater consumption | - | Freshwater consumption | Reduce freshwater consumption |
| 4 | Waste generation | Waste generation | Reduce waste production during construction and enhance reusing, recovering, and recycling | |
| 5 | Change of land use | Change of land use | Avoid use of greenfield, reuse brownfield, and infill sites. | |
| 6 | Access to services | A. | Public modes of transportation | Enhance quality and proximity of public transport |
| B. | Personal modes of transportation | Provide sidewalks, pedestrian footways, bicycle paths | ||
| C. | Green and open areas | Provide publicly accessible green and open areas | ||
| D. | User-relevant basic services | Presence of basic services in the building site | ||
| 7 | Accessibility | A. | Accessibility of building site (curtilage) | Make all relevant parts of the building site (or curtilage) barrier-free |
| B. | Accessibility of building | Accessibility of a building by all users (different classes) | ||
| 8 | Indoor conditions and air quality | A. | Indoor thermal conditions | Provide good indoor thermal conditions |
| B. | Indoor visual conditions | Provide good indoor visual conditions | ||
| C. | Indoor acoustic conditions | Provide good indoor acoustic conditions | ||
| D. | Indoor air quality | Provide indoor air suitable for human health and comfort | ||
| 9 | Adaptability | A. | Change of use or user needs | Adaptability in terms of changed user requirements, use/purpose |
| B. | Adaptability for climate change | Adaptability during unexpected projected climate change | ||
| 10 | Life cycle costs (LCC) | Lifecycle costs | Lifecycle cost of building | |
| 11 | Maintainability | Maintainability | Quality of maintenance plan that considers LCC, user comfort, and building functionality | |
| 12 | Safety | A. | Structural stability | Stability against loading |
| B. | Fire safety | Resistance of building to fire loadings and provisions for early warning and means of escape, considering different fire scenarios. | ||
| C. | Safety in use | Usability of the building while limiting the potential risk of tripping, falling, and other types of accidents. | ||
| 13 | Serviceability | Serviceability | Ability of a building to fulfil the user requirements from the functionality point of view. | |
| 14 | Esthetic quality | Esthetic quality | Consideration of cultural value and stakeholders’ requirements | |
| 15 | Emission to land/water ** | A. | Emission to water * | Reduce PO4 equivalent chemical emission |
| B. | Emission to land/water * | Reduce SO2 equivalent chemical emission | ||
| 16 | Value stability | Value stability * | Future value of building stability or growth | |
| 17 | Outdoor environment ** | A. | Emission to air (troposphere) * | Minimize/avoid tropospheric ozone (O3) formation materials |
| B. | Nuisance on neighborhood * | Minimize nuisance and other effects on neighborhood and local environment. | ||
| C. | Outdoor conditions * | Enhance good outdoor environment | ||
| D. | Heat island effect * | Reduce heat island in the area | ||
| 18 | Site ecology ** | A. | Protection of rare species and natural features * | Protect rare species and valuable individual natural features on-site (within the curtilage) |
| B. | Ecological quality of site * | Avoid construction in areas valuable in biodiversity | ||
| C. | Effect on surface drainage * | Reduce paved and non-permeable area | ||
| 19 | Participation | Participation * | Enhance users’ and other stakeholders’ participation | |
* Additional indicators of ISO. ** Name given or renamed for analysis purposes.
Table 2.
Evaluation of green building rating systems using the ISO standard.
| Code | ISO Core Areas | LEED | BREEAM | HQE | CASBEE | DGNB | Green Star SA | ITACA |
|---|---|---|---|---|---|---|---|---|
| 1A | Global warming potential | V | V | V | V | V | V | V |
| 1B | Ozone depletion potential | V | V | V | V | V | V | |
| 2A | Renewable and non-renewable raw materials consumption by type ** | V | V | V | V | V | V | |
| 2B | Renewable and non-renewable energy consumption ** | V | V | V | V | V | V | V |
| 3 | Freshwater consumption | V | V | V | V | V | V | V |
| 4 | Waste generation by type | V | V | V | V | V | V | V |
| 5 | Change of land use | V | V | V | V | V | V | |
| 6A | Public modes of transportation | V | V | V | V | V | V | V |
| 6B | Personal modes of transportation | V | V | V | V | V | V | V |
| 6C | Green and open areas | V | - | - | V | V | - | V |
| 6D | User-relevant basic services | V | V | - | - | V | V | V |
| 7A | Accessibility of the building site (curtilage) | - | - | V | - | V | - | - |
| 7B | Accessibility of the building | - | V | - | V | V | - | - |
| 8A | Indoor thermal conditions | V | V | V | V | V | V | V |
| 8B | Indoor visual conditions | V | V | V | V | V | V | V |
| 8C | Indoor acoustic conditions | V | V | V | V | V | V | V |
| 8D | Indoor air quality | V | V | V | V | V | V | V |
| 9A | Change of use or user needs | V | V | V | V | - | - | |
| 9B | Adaptability for climate change | - | V | - | - | V | - | - |
| 10 | Life cycle costs | - | V | - | - | V | - | - |
| 11 | Maintainability | - | V | V | V | V | - | V |
| 12A | Structural stability | - | V | - | V | V | - | - |
| 12B | Fire safety | - | - | - | - | V | - | - |
| 12C | Safety in use | - | - | - | - | V | - | - |
| 13 | Serviceability | - | V | V | V | V | V | - |
| 14 | Esthetic quality | - | - | - | V | V | - | - |
| 15A | Emission to water * | V | V | V | V | V | V | V |
| 5B | Emission to land/water * | V | V | V | V | V | V | - |
| 16 | Value stability * | - | V | V | - | |||
| 17A | Emission to air (troposphere) | V | V | V | V | V | V | - |
| 17B | Nuisance on neighborhood * | - | V | V | V | V | V | - |
| 17C | Outdoor conditions * | - | - | V | - | V | - | - |
| 17D | Heat island effect * | V | - | V | V | - | - | V |
| 18A | Protection of rare species * | V | V | V | V | V | V | - |
| 18B | Ecological quality of site * | V | V | - | V | V | V | - |
| 18C | Effect on surface drainage * | V | V | V | V | V | V | V |
| 19 | Participation * | V | V | V | - | V | - | - |
* Additional indicators. ** Indicator renamed for analysis. V: GBRS system fulfilled the ISO indicator requirements.
Table 3.
ISO indicators and corresponding GBRS criteria in environmental aspect.
| Indicator | LEED | BREEAM | HQE | CASBEE | DGNB | GSSA | ITACA |
| 1A | LT5–8 EA(P)2/(P)3/2–5, MR1–4, WE3 | Man03, Ene01/02a/04–08, Tra01–05, Mat01 | 1.1.3/1.1.4/2.2/2.3/3.2/3.3/4.1/4.2/4.3.1 | LR1.1–1.4, LR3.1 | ENV1.1/1., TEC3.1, PRO2.1/2.2/2.5 | Ene(all) Tra2–5, Mat5/6/9/11, Emi2/3 | A1.6/3.4, B1.2/1.5/3.2/3.3/4.9/6.2, C1.2, E3.5 |
| 1B | EA(P)4/6 MR1/2/4 | Pol01 | 4.3.3/4.3.4 | LR2.3 | ENV1.2 | Emi1/4 | - |
| 2A | MR1/3/5 | Mat03–06, Wst02 | - | LR2.2 | ENV1.1/1.3, TEC1.6 | Mat2–6/8–10 | B4.6/4.7/4.10, E6.1 |
| 2B | EA(P)2/(P)3/2–5 | Ene (all) | 3.3.1/4.1/4.2/7.2.1 | LR1.1–1.4 | TEC1.3/1.4 | Ene0/2/3/5 | B1.2/1.5/3.2/3.3, C1.2, E3.5 |
| 3 | WE (all), SS4 | Wat (all) | 3.3.2/5.1–5.3/7.2.2 | LR2.1 | ENV2.2 | Wat(all) | B5.1/5.2 |
| 4 | MR(P)1/P2/1–3 | Mat06, Wst01/03a/04 | 2.1/3.1/6.1/6.2 | LR3.2.3 | TEC1.6/PRO2.1 | Man7, Mat1/3/9 | B4.6/4.7/4.10, C3.2 |
| 5 | LT2/3/7 SS(P)1/1/2 | LE01 | - | Q3.1 | ENV2.3 | Eco1-3 | A1.5 |
| 15A | SS(P)1/4, LT7 | Pol03, Mat01 | 3.2.3/5.3 | LR3.2.3 | ENV1.1/2.2 | Emi5/6 | C4.1/4.3 |
| 15B | SS4 | Pol02/03, Mat01 | 3.2.3/4.3.2/5.3 | LR3.2.1/3.2.3 | ENV1.1/2.2 | Emi5/6 | - |
| 18A | SS1 | Man03, LE02/04/05 | 1.1.6/3.2.5 | Q3.1 | ENV2.4 | Eco4 | - |
| 18B | LT2 | LE02 | - | Q3.2 | PRO2.1 | Eco0 | - |
| 18C | LT7, SS4 | Pol03 | 1.1.5/5.3 | LR3.2.3 | ENV2.2 | Emi6, Tra1 | C4.1/4.3 |
Note: “/” (slash) and “,” (comma) are used only for separation purposes, and they represent “and”. “–”: all consecutive credits; (all): all credits in the category; “/”: credit in the same category. GSSA: Green Star SA; LEED category with (P): prerequisites; without (P): credit.
Table 4.
ISO indicators and corresponding GBRSs criteria in social aspect.
| Indicator | LEED | BREEAM | HQE | CASBEE | DGNB | GSSA | ITACA |
|---|---|---|---|---|---|---|---|
| 6A | LT5 | Tra01 | 1.1.3 | LR3.2.3 | SITE1.3 | Tra4 | A1.6 |
| 6B | LT6 | Hea06, Tra03a | 1.1.2/1.1.4 | LR3.2.3 | SITE1.3 | Tra3 | A3.4 |
| 6C | SS3 | - | - | Q2.1.2 | SOC1.6 | - | A3.3 |
| 6D | LT4 | Tra02 | - | - | SITE1.4 | Tra5 | A1.8 |
| 7A | - | - | 1.2 | - | SOC1.7/2.1 | - | - |
| 7B | - | Hea06 | - | Q2.1.1 | SOC2.1 | - | - |
| 8A | IEQ5 | Hea04 | 8.1–8.4 | Q1.2 | SOC1.1 | IEQ9 | - |
| 8B | IEQ6–8 | Hea01 | 10.1/10.2 | Q1.3 | SOC1.4 | IEQ4/5/7/8, Ene4 | - |
| 8C | IEQ9 | Hea05 | 9.1 | Q1.1 | SOC1.3 | IEQ12 | - |
| 8D | EIQ(P)1/(P)2/1–4 | Hea02 | 11.1, 12.1/12.2,13.1/13.2 | Q1.4/LR2.3 | ENV1.2, SOC1.2/1.5 | Man4, IEQ1/3/11/13–17, Emi3 | - |
| 12A | - | Hea07 | - | Q2.2.1/2.2.4 | SITE1.1 | - | - |
| 12B | - | - | - | - | Mand | - | - |
| 12C | - | - | - | - | SITE1.7 | - | - |
| 14 | - | - | - | Q3.2 | PRO1.6 | - | - |
| 17B | - | Man03, Pol04/05 | 1.3, 3.2.1/3.2.2 | LR3.3 | PRO2.1 | Man6 | - |
| 19 | IP | Man01/02 | Mand | - | PRO1.6/2.1 | - | - |
Mand: mandatory requirement for certification.
Table 5.
ISO indicators and corresponding GBRS criteria in economic aspect.
| Indicator | LEED | BREEAM | HQE | CASBEE | DGNB | GSSA | ITACA |
|---|---|---|---|---|---|---|---|
| 9A | - | Wst06 | 2.1 | Q2.3 | ECO2.1 | - | - |
| 9B | - | Wst05 | - | - | SITE1.1 | - | - |
| 10 | - | Man01/02 | - | - | ECO1.1, TEC1.5 | - | - |
| 11 | - | Man04/05 | 7.1 | Q2.1.3 | TEC1.5, PRO2.2 | - | E6.5 |
| 13 | - | Man05 | - | Q2.1.1 | PRO2.4, ECO 2.1 | Man3–5 | - |
| 16 | - | Man02 | - | - | ECO2.2, SITE1.2 | - | - |
Table 6.
ISO indicators and corresponding GBRS criteria in dual aspects.
| Indicator | LEED | BREEAM | HQE | CASBEE | DGNB | GSSA | ITACA |
|---|---|---|---|---|---|---|---|
| 17A | IEQ2, MR1 | Pol02 | 3.2.4 | LR2.1 | ENV1.1/1.2 | Emi9 | - |
| 17C | - | - | 1.2.2/1.2.3 | - | TEC1.7, SITE1.2 | - | - |
| 17D | LT7, SS5 | - | 1.1.5/1.2.1 | LR3.2.2 | - | - | C6.8 |
Table 7.
Multi-certified buildings evaluation summary.
| Case No. | Project Name and Location | Certification (Year) | Combination Deficiency to ISO | Remark |
|---|---|---|---|---|
| 1 | Challenger (Versailles, France) | BREEAM, Outstanding (2014) | 12B: Fire safety 12C: Safety in use 14: Esthetic quality | The ISO indicators not satisfied |
| HQE, Exceptional (2014) | ||||
| LEED, Platinum (2014) | ||||
| 2 | Tour First (Paris, France) | HQE, Very Good (2011) | 7B: Accessibility of building 9B: Adaptability for climate change 10: Life cycle cost 12: Safety 14: Esthetic quality 16: Value stability | The ISO indicators not satisfied |
| LEED, Gold (2009) | ||||
| 3 | BNP Paribas (Luxembourg) | HQE, Exceptional (2016) | - | The ISO indicators satisfied |
| BREEAM, Excellent (2017) | ||||
| DGNB, Good (2018) | ||||
| 4 | Enovos (Luxembourg) | BREEAM, Very Good (2016) | 12B: Fire safety 12C: Safety in use 14: Esthetic quality | The ISO indicators not satisfied |
| HQE, Exceptional (2016) | ||||
| 5 | Administrative building of Max Frank (Leiblfing, Germany) | LEED, Gold (2015) | - | The ISO indicators satisfied |
| DGNB, Gold (2015) | ||||
| 6 | Eiffel Palace office building (Budapest, Hungary) | BREEAM, Very good (2009) | 7A: Accessibility of building site 12B: Fire safety 12C: Safety in use 14: Esthetic quality 17C: Outdoor conditions | The ISO indicators not satisfied |
| LEED, Gold (2009) | ||||
| 7 | Company House III (Aarhus, Denmark) | BREEAM, Very Good (2012) | 17D: Heat island effect | The ISO indicators not satisfied |
| DGNB, Gold (2012) |
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. |
© 2022 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Assefa, S.; Lee, H.-Y.; Shiue, F.-J. Sustainability Performance of Green Building Rating Systems (GBRSs) in an Integration Model. Buildings 2022, 12, 208. https://doi.org/10.3390/buildings12020208
AMA Style
Assefa S, Lee H-Y, Shiue F-J. Sustainability Performance of Green Building Rating Systems (GBRSs) in an Integration Model. Buildings. 2022; 12(2):208. https://doi.org/10.3390/buildings12020208
Chicago/Turabian StyleAssefa, Sintayehu, Hsin-Yun Lee, and Fang-Jye Shiue. 2022. "Sustainability Performance of Green Building Rating Systems (GBRSs) in an Integration Model" Buildings 12, no. 2: 208. https://doi.org/10.3390/buildings12020208
APA StyleAssefa, S., Lee, H. -Y., & Shiue, F. -J. (2022). Sustainability Performance of Green Building Rating Systems (GBRSs) in an Integration Model. Buildings, 12(2), 208. https://doi.org/10.3390/buildings12020208
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
