Green Roof Development in ASEAN Countries: The Challenges and Perspectives
Abstract
:1. Introduction
2. Materials and Methods
3. Results
3.1. Mapping of Selected Literatures
3.2. Stages of Green Roofs in ASEAN Countries
3.3. Green Roof Performance in ASEAN Countries
3.3.1. Drivers of Green Roofs in ASEAN Countries
- Policy Pressure.
Authors | Key Findings | Country | |
---|---|---|---|
Subsidy Scheme | Regulations and Standards | ||
Ismail et al. [28] | The scheme supported 50% of green roof installation costs by Singapore National Parks (NParks) to encourage owners to have green roofs | Standards for Singapore GRs,
| Singapore |
Fauzi et al. [29,30], Siew et al. [65], Zaid et al. [66] | None |
| Malaysia |
- Advance Innovation Technology.
3.3.2. Motivations for Green Roofs in ASEAN Countries
- Energy Efficiency.
- Urban Heat Island Mitigation.
- Outside Surface Temperature.
- 2.
- Indoor Room Temperature.
- Runoff Control.
- Storm Water Retention.
- 2.
- Runoff Water Quality.
- Biodiversity Increase.
3.3.3. Barriers to Green Roofs in ASEAN Countries
- Government Policy and Technology Barriers.
- Economy.
- Social Acceptability and Feasibility Issues in ASEAN Countries.
Challenge | Brunei | Malaysia | Indonesia | Thailand | Vietnam | Myanmar | References |
---|---|---|---|---|---|---|---|
Lack of Interest using GRs | ✓ | ✓ | ✓ | ✓ | [48,52,104,105,106,107] | ||
Lack of Guidelines | ✓ | ✓ | [67,102,108] | ||||
Less Government Intensive | ✓ | ✓ | ✓ | [60,103,109] | |||
High Installation Cost | ✓ | [110] | |||||
Lack of Expertise | ✓ | [105,106] |
4. Discussion
4.1. Challenges of GR Development in ASEAN Countries
4.2. Perspective and Future Needs of GR Development in ASEAN Countries
- -
- GRs can reduce energy consumption in buildings by up to 57%, reduce roof surface temperatures when compared to bare roofs up to 23.8 °C, and reduce the room temperature to 14 °C. It should be noted that heating load reductions can be influenced by substrate [73], vegetation [76], and insulating material [81]. Some researchers describe alternative material such as lightweight concrete deck that can improve GR properties [40,51].
- -
- GRs aid in water management, owing to their high water retention potential and increased runoff quality. The application of GRs in ASEAN countries is highly appropriate due to the region’s abundant precipitation. GRs can control up to 98.8% of flood water retention. However, the retention is high only for low- to moderate-intensity rainfall. Countries with significant precipitation, such as the Philippines, are highly interested in GR water management research (e.g., as described in the case reported by Orozco [36]). The use of hydrogel to increase water retention on the substrate is an interesting innovation to be developed (from research by Asinas [57]). Other countries with heavy precipitation, such as Indonesia, are encouraged to conduct studies on the water management of GRs.
- -
- The present review study also signals biodiversity, which is the fact that GRs can promote urban biodiversity and enhanced habitat connectivity between flora and fauna as was shown in research in Singapore [113]. A habitat is created from many environmental factors. We found no literature on biodiversity in other ASEAN nations during our search. We need further research on the effect of environment and topography on the biodiversity of the GR.
- Investigating alternative materials that can enhance the efficacy of GRs and reduce installation costs.
- Developing intelligent technology that can expedite the retrieval of GR data in order to accelerate the pre-development, construction, and maintenance processes.
- Planning guidelines and economic schemes that can be referred to in the future when creating government regulations.
- Conducting research on the benefits of GRs at each city scale (e.g., residential buildings, commercial buildings, and high-rise buildings) to educate users on the advantages of GR use.
- At this time, numerous diverse data can be suggested for calculating the mean and median value for each parameter. Due to the heterogeneity of the parameters in the calculated studies, it was deemed statistically invalid to compute such values. Evaluation of performance can serve as an indicator for evaluating the performance of green roofs in ASEAN countries.
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Authors | Findings | Details |
---|---|---|
Mahdiyar et al. [32] | Development of a decision support system (DSS) for selecting the optimum type of GR for residential buildings in Kuala Lumpur | Malaysia, All types GR, System to selection GRs |
He et al. [68] | Artificial neural network (ANN) models had a better average prediction for accurate modelling of thermal and hydrological performance | Singapore, EGR, Evaluate plant evapotranspiration |
He et al. [70] | A methodology for a quick evaluation of thermal performance of a green roof during the early stages of design | Singapore, EGR, Model development of RTTV |
Phoomirat et al. [33] | Develop a rapid assessment checklist (RAC) to assess GR services | Thailand, All GRs, Assessment tools |
Munir et al. [31] | The panel 400 mm width is an optimal form for the structural roof deck of the green roof system | Indonesia, EGR, Structural deck precast foamed concrete for GRs |
Shahid et al. [71] | Palm oil clinker has good ability to drain excess water, and there is no side effect in terms of plant development | Malaysia, EGR, Palm oil clinker as drainage layer |
Chandra et al. [69] | Lightweight cellular concrete 1200 and 1400 kg/m3 meets the standard to substitute normal concrete | Thailand, EGR, Structural deck alternative for GRs |
Authors | Energy Savings | Details |
---|---|---|
Wong et al. [74] | 1–15% reduction in energy consumption | Singapore, EGR, Comparison rooftop garden with turfing, shrubs, and tree |
Dewi et al. [76] | 11.24–21% reduction in cooling load | Indonesia, EGR, GR simulations by planting Tradescantia Spathacea and Sedum acre |
Sittipong and Pichai [73] | GR thickness 0.10 m–31.07% GR thickness 0.20 m–37.11% | Thailand, EGR, Increasing soil depth improves energy savings by around 6% |
Azis et al. [75] | 37–40% reduction in energy consumption | Johor Bahru, Malaysia, EGR and IGR GR integration with 17-floor apartment |
Yuliani et al. [77] | Concrete GRs, 57.1% reduction in heat flow Corrugated Zinc GRs, 50.8% reduction in heat flow | Surakarta, Indonesia, EGR, A corrugated zinc roof with plants could improve thermal conditions in a building |
Authors | Max. Outdoor Surface Temperature Reduction | Ambient Temperature | Remarks |
---|---|---|---|
Sunakorn [79] | 10.4 °C | 30 °C | Thailand, Actual Survey Study, EGR, Local material Thailand (Green Mat) can be applied on GRs |
Qin [80], Yang et al. [81] | 19 °C | 24–32 °C | Singapore, Simulation study, Cool roofs, Insulation layer on cool roofs plays a negligible role in heat flux values |
Munir et al. [51] | 19.1 °C | 28–57 °C | Aceh, Indonesia, Experimental study, EGR, Precast foamed concrete, Combination of lightweight foamed concrete and GR |
Ahmed and Rumana [82], Ismail et al. [83] | 19.8 °C | 30.2 °C | Malaysia, Actual survey study, Roof garden, GRs performed better than white concrete roof and gardening roof |
Yuliani et al. [53,77] | 20 °C | 24–35 °C | Surakarta, Indonesia, Experimental study, EGR, Concrete and corrugated zinc, A corrugated zinc roof with plants could improve thermal conditions in a building |
Azis et al. [75], Rahmat et al. [54], Rahman et al. [84] | 23.8 °C | 30–36 °C | Kuala Lumpur and Putrajaya, Malaysia, Experimental study, EGR, Green roof improving public environment |
Yuliani et al. [53,77] | 20 °C | 24–35 °C | Surakarta, Indonesia, Experimental study, EGR, Concrete and corrugated zinc, A corrugated zinc roof with plants could improve thermal conditions in a building |
Azis et al. [75], Rahmat et al. [54], Rahman et al. [84] | 23.8 °C | 30–36 °C | Kuala Lumpur and Putrajaya, Malaysia, Experimental study, EGR, Green roof improving public environment |
Authors | Max. Indoor Temperature Reduction | Temperature Comparison | Remarks |
---|---|---|---|
Yuliani et al. [77] | 3 °C | GR 23–28 °C NON-GR 27–31 °C | Surakarta, Indonesia, Experimental study, EGR, Concrete and corrugated zinc, A corrugated zinc roof with plants could improve thermal conditions in a building |
Pahm et al. [62] | 3 °C | GR 31 °C NON-GR 34 °C | Ho Chi Minh City, Vietnam, Actual survey study, roof garden In cooler area, GR still resulted lower than non-GR temperature |
Ahmed and Rumana [82], Ismail et al. [83], Rahman et al. [84] | 3 °C | GR 24.5–31.5 °C NON-GR 25.5–33 °C | Malaysia, Actual survey study, roof garden, GRs performed better than white concrete roof and gardening roof |
Irsyad et al. [35] | 6.8 °C | GR 23–26 °C NON-GR 24–32 °C | Bandung, Indonesia, Experimental study, EGR, The use of Amaranta and Bromelia plants can inhibit heat transfer into the room |
Sunakorn [79] | 7 °C | GR 24.6–27.9 °C NON-GR 29.6–39.9 °C | Thailand, Actual survey study, EGR, Local material Thailand (Green Mat) can be applied on GRs |
Munir et al. [51] | 10.2 °C | GR 35–38 °C NON-GR 42–51 °C | Aceh, Indonesia, Experimental study, EGR, Precast foamed concrete Combination of lightweight foamed concrete and green roof |
Yang et al. [81] | 14 °C | GR 26–27 °C NON-GR 28–41 °C | Singapore, Simulation study, EGR, Insulation layer on cool roofs plays a negligible role in heat flux values |
Authors | Water Retention Capacity | Remarks and Influence Factors |
---|---|---|
Chanrachna et al. [49] | 37.90% | Phnom Penh, Cambodia, Comparison study, GI (Green Infrastructure) scenario by installation tree, bioswales, permeable pavements, and green roofs |
Cuong et al. [85] | 42% | Hanoi, Vietnam, Experimental study, EGR, Four models with different irrigation systems |
Asinas et al. [57] | 46% | Philippines, Experimental study, EGR, Waterproof substrate improving water retention by adding hydrogel to substrate media |
Chai et al. [87] | 72.5% | Kuching, Malaysia, Simulation study, EGR, Green roof water balance by virtual modelling approach |
Orozco et al. [36] | 75% | Metro Manila, Philippines, Comparison study, EGR, Suppliers company, Comparison of suppliers with six different GR technologies |
Ayub et al. [88], Fai et al. [89], Chow et al. [90], Romali et al. [37], Kok et al. [91], Chai et al. [87], Musa et al. [92] | 86% | Malaysia, Simulation study, EGR, GRs decrease of stormwater runoff, Types of substrates resulting in different runoff, Mixture of plant species was the most effective vegetation at reducing runoff water |
Vergroesen and Joshi [93] | 98.8% | Singapore, Experimental study, EGR, 3-day experiment, Different sedum comparison |
Authors | Findings | Remarks and Influence Factors |
---|---|---|
Romali et al. [37] | GRs with beach morning glory improve the COD up to 99% GRs with creeping oxeye reduce the BOD up to 17% | Malaysia, Experimental study, EGR, Green roof with beach morning glory and creeping oxeye |
Lim et al. [94] | Mixture substrate clay (5–30%), silt (5–60%), and sand (20–75%) can decline in chemical concentration level | Singapore, Experimental study, EGR, Substrate comparison |
Vijayaraghavan et al. [97] | The concentrations of most of the chemical components in runoff were highest during the beginning of rain events and subsided in the subsequent rain events | Singapore, Experimental study, EGR, Real rain events and ten different simulated rain events |
Authors | Findings | Remarks |
---|---|---|
Suparwoko and Taufani [111] | The potential to use GRs as an urban farming space | Sleman, Indonesia, Survey study, Feasibility of buildings |
Chow and Abu Bakar [102] | Industries were very cautious about having rooftop gardens due to the unknown risk on maintenance aspects | Malaysia, Survey study, Feasibility of buildings |
Rahman et al. [112] | GRs help to regenerate and revitalize the commercial setting in urbanized areas | Malaysia, Survey study, Feasibility of buildings |
Hwang and Roscoe [113] | Green roofs as a platform for the interaction between humans and nature is a possibility that is yet to be fully explored, especially in a tropical context | Singapore, Actual study, Feasibility of buildings |
Naing et al. [114] | 47% of selected buildings in sampling area were possible to retrofit for a green roof | Thailand, Survey study, Feasibility of buildings |
Jalanugroh and Tikul [115] | Of twenty-six education buildings, three can be built with an intensive green roof, seven can be built but gardeners are needed, and sixteen can be built with extensive green roofs | Thailand, Survey study, Feasibility of buildings |
Lwin and Panuwatwanich [108] | Energy efficiency, water efficiency, and waste and pollution, are the most crucial categories that should be concerned | Myanmar, Survey study, Feasibility of buildings |
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Pratama, H.C.; Sinsiri, T.; Chapirom, A. Green Roof Development in ASEAN Countries: The Challenges and Perspectives. Sustainability 2023, 15, 7714. https://doi.org/10.3390/su15097714
Pratama HC, Sinsiri T, Chapirom A. Green Roof Development in ASEAN Countries: The Challenges and Perspectives. Sustainability. 2023; 15(9):7714. https://doi.org/10.3390/su15097714
Chicago/Turabian StylePratama, Hanny Chandra, Theerawat Sinsiri, and Aphai Chapirom. 2023. "Green Roof Development in ASEAN Countries: The Challenges and Perspectives" Sustainability 15, no. 9: 7714. https://doi.org/10.3390/su15097714
APA StylePratama, H. C., Sinsiri, T., & Chapirom, A. (2023). Green Roof Development in ASEAN Countries: The Challenges and Perspectives. Sustainability, 15(9), 7714. https://doi.org/10.3390/su15097714