Exploring Influencing Factors and Innovative Solutions for Sustainable Water Management on Green Roofs: A Systematic Quantitative Review
Abstract
:1. Introduction
- a.
- Question 1: What is the impact of green roofs on runoff quantity and quality, and what are the key controlling factors?
- b.
- Question 2: What are the water retention and consumption capacities of green roofs, and what are their influencing factors?
- c.
- Question 3: Which design aspects can be altered, and what techniques can be employed to improve the sustainability of water management on green roofs?
2. Background about Water Sources and Their Quality
2.1. Rainwater
2.2. Irrigation
3. Methodology
4. Statistical Results
5. The Impact of Green Roofs on Runoff Quantity
5.1. Rainwater Retention
5.2. Delaying the Peak Runoff
5.3. Influencing Factors
5.3.1. Climate Characteristics
5.3.2. Substrate Characteristics
5.3.3. Vegetation
5.3.4. Drainage Layer
5.3.5. Other Influencing Factors
5.3.6. Summary
6. The Impact of Green Roofs on Runoff Water Quality
6.1. Green Roofs as a Sink or a Source of Pollutants
6.2. Controlling Factors
6.2.1. Substrate Properties
6.2.2. Vegetation
6.2.3. Other Factors
7. Techniques to Control Runoff and Water Consumption on Green Roofs
7.1. Evaluating and Controlling Potential Evapotranspiration
7.2. Adapting Green Roof Layers and Considering Non-Traditional Green Roof Types
7.3. Controlling the Irrigation Regime
7.4. Harvesting the Runoff
8. Techniques to Control the Runoff Quality from Green Roofs
8.1. Phytoremediation
8.2. Biosorption
8.3. Controlling Fertilisers and Pesticides
9. Discussion
9.1. Practical Implications and Proposed Framework
9.1.1. Proposed Sustainable Water Management Framework
- 1.
- Site assessment and planning:
- a.
- Prioritise water management objectives: rank and prioritise water management objectives based on their significance and feasibility for the project.
- b.
- Integrate water management into site planning: ensure water management is integrated with the overall site planning process, considering factors such as building design, landscaping, and infrastructure.
- c.
- Assess local regulations and permits: ensure compliance with local regulations and obtain necessary permits and guidelines for water sources and management.
- d.
- Comprehensive site assessment: conduct a thorough site assessment, including climate conditions, rainfall patterns, access to sunlight, roof slope, neighbouring buildings, pollutants, vegetation, and drainage systems.
- 2.
- Green roof design and configurations:
- a.
- Select appropriate green roof type: determine the most suitable green roof type based on site-specific factors and water management objectives.
- b.
- Optimise water management design: design the green roof to optimise water management, considering factors such as slope, drainage systems, substrate composition, and vegetation selection.
- c.
- Emphasise water conservation strategies: incorporate water conservation strategies, such as using drought-tolerant plant species, mulching, retention layers, and water-efficient fixtures.
- d.
- Efficient drainage system: design an efficient and well-structured drainage system to manage excess water and prevent waterlogging.
- 3.
- Irrigation design and management:
- a.
- Estimate water demand: estimate the water demand for the site based on vegetation requirements, evapotranspiration rates, and irrigation needs.
- b.
- Develop a smart irrigation plan: develop an irrigation plan that considers water needs, availability, and conservation goals. Implement smart irrigation controllers adjusting schedules based on weather conditions, soil moisture, and plant requirements.
- c.
- Efficient irrigation systems: implement efficient irrigation systems, such as drip irrigation or sub-irrigation, and incorporate moisture sensors to optimise water use and prevent overwatering.
- d.
- Explore alternative water sources: encourage using greywater or recycled water for irrigation, if feasible and permitted.
- 4.
- Excess and rainwater harvesting:
- a.
- Assess the feasibility of rainwater harvesting: evaluate feasibility based on rainfall patterns, roof area, and water storage capacity.
- b.
- Design a rainwater collection system: design and implement a rainwater collection system, including gutters, downspouts, and storage tanks, considering the water requirements of the green roof.
- 5.
- Runoff control and stormwater management:
- a.
- Retain and gradually release water: implement methods to retain and gradually release stored water from the drainage layer, reducing the burden on conventional drainage systems.
- b.
- Integrate with green infrastructure: incorporate green roofs with other green infrastructure elements, such as bioswales or rain gardens, to enhance stormwater management.
- c.
- Ensure a functional drainage system: design and maintain a well-functioning drainage system to direct excess water away from the building and prevent damage.
- 6.
- Water quality management:
- a.
- Enhance water quality on green roofs: implement measures such as appropriate vegetation, substrates, and filtration systems to enhance water quality on green roofs.
- b.
- Regular water quality monitoring: conduct regular monitoring and testing of water quality parameters to ensure compliance with local regulations and standards and implement required techniques to enhance the quality if needed.
- 7.
- Maintenance, monitoring, and improvement:
- a.
- Develop a comprehensive maintenance plan: develop a comprehensive maintenance plan, including regular inspections, cleaning of drainage systems, and vegetation management.
- b.
- Monitor performance and consumption: monitor water consumption, stormwater runoff, and overall system performance to identify opportunities for improvement and address any issues promptly.
- c.
- Periodic inspections and adjustments: conduct periodic inspections to identify and address potential issues and make necessary adjustments to optimise water efficiency and sustainability.
- d.
- Stay updated on advances: stay informed about advances in green roof technologies, water management strategies, and best practices through engagement with research institutions and industry experts.
- e.
- Stakeholder feedback and engagement: seek feedback from stakeholders, including building owners, occupants, and facility managers, to understand their needs, preferences, and concerns regarding water management. Involve stakeholders throughout the process to ensure their support and participation.
9.1.2. Feasibility Assessment
- Cost-benefit analysis: conduct a detailed cost-benefit analysis to determine the economic feasibility of implementing the green roof water management system. Evaluate installation costs, maintenance expenses, and potential savings in water bills or stormwater management infrastructure.
- Environmental impact assessment: assess the potential environmental benefits of the green roof water management system, such as reducing stormwater runoff and improving water quality. Consider the life cycle environmental impacts of materials and maintenance practices.
- Technical feasibility: evaluate the technical feasibility of implementing the required systems, including green roof design, irrigation systems, rainwater collection and drainage infrastructure.
- Risk assessment and mitigation: identify and evaluate potential risks associated with green roof water management, such as leakage, water damage, or increased maintenance requirements. Develop mitigation strategies to minimise risks and ensure long-term performance.
- Social considerations: engage with stakeholders to understand their needs and concerns related to water management, specifically for the water sources used for irrigation.
9.1.3. Decision-Making
- Informed decision-making: based on the assessments conducted, stakeholder input, and feasibility analysis, make an informed decision on the practicality of implementing the green roof water management system. Consider alternative approaches or modifications if necessary.
- Scalability and adaptability: assess the scalability of the system to other projects and consider adaptability to different contexts. Ensure that the framework can be replicated and adjusted based on varying site conditions, regulations, and resources.
- Continual improvement: continuously evaluate the performance of the green roof system in terms of water management goals and objectives. Monitor water usage, rainfall, runoff and system efficiency to identify areas for improvement and implement necessary adjustments.
- Knowledge updates: stay updated on the latest advances in green roof technologies, water management strategies, and best practices. Engage with research institutions, industry experts, and relevant professional networks to stay informed and incorporate new knowledge into the water management framework.
9.2. Limitation and Future Studies
10. Conclusions
Supplementary Materials
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Hydrological Performance | Water Sources | Water Quality | Water Management | Innovative and Integrated Solutions |
---|---|---|---|---|
Green roof* runoff | Green roof* *water | Green roof* *water quality | Green roof* *water manag* | Green roof* integrated technolog* |
Green roof* retention | Green roof* irrigat* | Green roof* *water pollut* | Green roof* *water harvest* | Green roof* integrated infrastructure |
Green roof* drought* | Green roof* *water source* | Green roof* runoff quality | Green roof* *water design* | Blue green roof* |
Green roof* drain* | Green roof* precipitation | Green roof* runoff pollut* | Constructed wetland roof* | |
Green roof* storm* | Green roof* rain* | Green roof* runoff contaminat* | ||
Green roof* hydrolog* | Green roof* *water treat* |
Reference | Methods | Climate | Location | Green Roof Type | Green Roof Area (m2) | Rainfall Depth (mm) | Rainfall Events | Substrate Depth (cm) | RWR Rate (%) |
---|---|---|---|---|---|---|---|---|---|
Li and Liu [49] | Experiment | humid subtropical | Chongqing, China | Test beds | 1.44 | 2.26–71.20 | 99 | 20 | 40–83 |
Todorov, Driscoll [50] | Measurements | Cool, humid | Syracuse, NY, USA | Extensive | 1190 | 6.93 ± 6.50 average | - | 9.5 | 75–99.6 |
Soulis, Ntoulas [43] | Experiment | Mediterranean | Athens, Greece | 30 test beds | 2 | 10.3 average | - | 8 and 16 | 50.6–81.1 |
Brandao, Cameira [42] | Experiment | Mediterranean | Lisbon, Portugal | Test beds | 2.5 | 13.05 average | 184 | 15 | 71.1–82 |
Zhang, Miao [51] | Experiment | Subtropical, monsoon | Chongqing, China | Test bed | 1 | 1116.5 total | 19 | 15 | 35.5–100 |
Beecham and Razzaghmanesh [28] | Experiment | Hot, Mediterranean | Adelaide, Australia | 16 test beds | 0.15 | 24.12 average | 5 | 10 and 30 | 52 and 95 |
Burszta-Adamiak [52] | Experiment | Temperate | Wroclaw, Poland | Five test plots | 2.88 | - | 153 | - | 82.6–99.9 |
Simmons, Gardiner [46] | Experiment | Subhumid, subtropical | Austin, TX, USA | 24 roof platforms | 3.4 | 89.3 total | 3 | 10 | 8–88 |
Stovin, Dunnett [41] | Experiment | Temperate | Sheffield, UK | Test bed | 3 | 9.2 average | 11 | 8 | 10–90 |
Carter and Rasmussen [53] | Experiment | Humid, subtropical | Athens, GA, USA | Test plot | 42.64 | 1079 total | 31 | 7.62 | 39–100 |
VanWoert, Rowe [40] | Experiment | Temperate | MI, USA | Vegetated roof | 5.9536 | - | - | 2.5 | 60.6–96 |
Reference | Method | Climate | Location | Substrate Depth (cm) | Plants | Delay Runoff (h) |
---|---|---|---|---|---|---|
Wang, Garg [59] | Experiment + modelling | tropical | South China | 10, 19, 25 | Grass | 0.40–1.68 |
Santos, Silva [54] | Experiment | Mediterranean | Lisbon, Portugal | 15 | Sedum album, Sedum sexangular, Sedum spurium, Sedum spurium tricolor, Sedum coral reef, Sedum oreganum, Sedum forsteriamum, Armeria Maritima and Thymus red creeping e Rosmarinus officinalis. | 0.03–0.30 |
Zhang, Lin [60] | Experiment | humid continental | Beijing, China | 10, 15 | Sedum spp. | 1.05–2.18, 1.36–3.50 |
Brandao, Cameira [42] | Experiment | Mediterranean | Lisbon, Portugal | 15 | Mixed Shrubs, grass, and moss | 0.49 |
Grass (Brachypodium phoenicoides) | 2.54 | |||||
Shrub (Rosmarinus officinalis) | 1.26 | |||||
Bare soil | 0.94 | |||||
Burszta-Adamiak, Stańczyk [61] | Experiment | Temperate | Wroclaw, Poland | extensive green roof | Sedum acre, Sempervivum | 1.5–1.7 |
Almaaitah and Joksimovic [62] | Experiment | continental climate | Toronto, ON, Canada | 25–30 | Planted with seeds of thirty different crops | 7.70–8.00 |
Carter and Rasmussen [53] | Experiment | Humid, Subtropical | Athens, GA, USA | 7.62 | Sedum spp. | 0.58 |
Nawaz, McDonald [63] | Measurements | Maritime, temperate | Leeds, UK | 3 | Sedum spp. | 4.25–8.25 |
Article | Substrate Depth | Max WHC% | Growing Media Composition | RWR Rate (%) |
---|---|---|---|---|
Beecham and Razzaghmanesh [28] | 10 | 41 | (A) Crushed red brick, scoria, coir fibre, and composted organics | 70 |
30 | 74 | |||
10 | 44 | (B) Comprised scoria, composted pine bark, and hydro-cell flakes | 58 | |
30 | 60 | |||
10 | 48 | (C) 50% of media type B with 50% organic compost | 68 | |
30 | 70 | |||
Simmons, Gardiner [46] | 10 | 34 | (A) Expanded shale, sand, and organic matter | 21.67 |
37 | (B) Expanded clay, expanded shale, sand, and organic matter | 51.67 | ||
43 | (C) Expanded clay, sand, perlite, and organic matter | 41.67 | ||
46 | (D) Decomposed granite, perlite, and organic matter | 58.33 | ||
38 | (E) Expanded clay, expanded shale, sand, and organic matter | 32 | ||
32 | (F) Expanded clay, expanded shale, sand, and organic matter | 17 | ||
Baryla, Karczmarczyk [77] | 8 | 20 | Washed gravel | 62.7 |
8 | 20 | Expanded clay aggregate | 62.7 | |
17 | 55 | Washed sand, chalcedony, clay, low peat, and compost | 80 | |
Soulis, Ntoulas [43] | 8 | 54.2 | Pumice (65%), attapulgite clay (15%), zeolite (5%), and grape marc (15%) | 50.6 |
16 | 54.8 |
Reference | Substrate Depth (cm) | Plants | RWR Rate (%) |
---|---|---|---|
Soulis, Ntoulas [43] | 8 | O. onites | 63.6 |
8 | S. sediforme | 50.8 | |
8 | F. arundinacea | 54.9 | |
8 | - | 50.6 | |
16 | O. onites | 81.1 | |
16 | S. sediforme | 60.3 | |
16 | F. arundinacea | 68.8 | |
16 | - | 54.8 | |
Brandao, Cameira [42] | 15 | Mix of shrubs (Rosmarinus officinalis, Lavandula stoechas subspecies Luisieri), grass (Brachypodium phoenicoides), and moss (Pleurochaete squarrosa) | 82 |
Grass (Brachypodium phoenicoides) | 73.2 | ||
Shrub (Rosmarinus officinalis) | 71.1 | ||
- | 64.2 |
Article | Drainage Layer | Substrate Depth (cm) | RWR Rate (%) |
---|---|---|---|
Burszta-Adamiak [52] | Plastic profiled drainage elements type FKD 12 (height: 1.2 cm) | - | 82.5 |
Gravel with 2–5 cm granulation | - | 85.7 | |
Baryla, Karczmarczyk [77] | Polypropylene mat (Terrafond Garden 20 L type with a thickness of 2 cm) and geotextile fabric on top of the drainage layer | 17 | 80 |
Washed gravel | 8 | 62.7 | |
Expanded clay aggregate | 8 | 62.7 |
Article | Climate | Study Location | Green Roof Area | Substrate Depth (cm) | Slope | RWR Rate (%) |
---|---|---|---|---|---|---|
Getter and Rowe [10] | Temperate | USA | 5.9536 | 6 | 2% | 85.2 |
7% | 82.2 | |||||
15% | 78 | |||||
25% | 75.3 | |||||
Villarreal and Bengtsson [66] | Oceanic | Sweden | 1.544 | 4 | 2° | 62 |
8° | 43 | |||||
14° | 39 | |||||
Chow and Abu Bakar [93] | Tropical | Malaysia | 2 | 13 | 0° | 56.9 |
2° | 56.4 | |||||
5° | 55.9 | |||||
7° | 52.3 |
Reference | Green Roof Type | Substrate | Plants | Metal | Nutrient | pH | ||||||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Zn | Pb | Cd | Fe | Cr | Cu | Ca | As | Al | Mg | Ni | K | Na | NO3−-N | PO43−-P | TP | NO3− | NH4+ | NH4-N | DOC | DON DON | ||||||
Chen, Kang [105] | 10 cm extensive | cultivated (C), light (L), Cultivated +recycled glass (R) | Sedum nussbaumerianum (Sn) | RW | - | - | - | - | - | - | - | - | - | - | - | - | - | Y | Y | Y | - | - | S | - | - | I |
10 cm extensive | Nephrolepis exaltata (L.) Schott (Ne) | - | - | - | - | - | - | - | - | - | - | - | - | - | Y | Y | Y | - | - | S | - | - | I | |||
10 cm extensive | Serissa foetida (L.f.) Poir. (Sf) | - | - | - | - | - | - | - | - | - | - | - | - | - | Y | Y | Y | - | - | S | - | - | I | |||
Buffam, Mitchell [106] | 10 cm extensive | Tremco’s standard aggregate-based | Mixed species. | RW | Y | - | - | Y | - | - | Y | - | Y | Y | - | Y | Y | - | Y | - | M | S | - | Y | Y | I |
Schwager, Schaal [107] | Substrate | Pine Bark and Peat | - | SRW | Y | M | Y | - | Y | Y | - | Y | - | - | Y | - | - | - | - | - | - | - | - | - | - | - |
Coco Coir & Zeolite | Y | M | Y | - | Y | Y | - | Y | - | - | Y | - | - | - | - | - | - | - | - | - | - | - | ||||
Compost and Slag and Clay | Y | Y | - | - | Y | Y | - | Y | - | - | Y | - | - | - | - | - | - | - | - | - | - | - | ||||
Expanded Clay 1 | Y | - | - | - | Y | Y | - | Y | - | - | Y | - | - | - | - | - | - | - | - | - | - | - | ||||
Vijayaraghavan and Joshi [108] | pilot-scale green roof | local garden soil | - | MSTW | S | S | S | S | S | S | Y | - | S | Y | S | Y | Y | - | - | - | - | - | - | - | - | I |
optimised green roof substrate | - | S | S | S | Y | S | S | S | - | Y | S | S | Y | Y | - | - | - | - | - | - | - | - | I | |||
local garden soil | P. grandiflora | S | S | S | S | S | S | Y | - | S | Y | S | Y | Y | - | - | - | - | - | - | - | - | I | |||
optimised green roof substrate | P. grandiflora | S | S | S | S | S | S | S | - | S | S | S | Y | Y | - | - | - | - | - | - | - | - | I | |||
local garden soil | - | USTW | S | - | - | - | - | Y | Y | - | - | Y | Y | Y | Y | - | - | - | - | - | - | - | - | D | ||
optimised green roof substrate | - | Y | - | - | Y | - | Y | S | - | Y | S | Y | Y | Y | - | - | - | - | - | - | - | - | D | |||
local garden soil | P. grandiflora | S | - | - | - | - | - | Y | - | Y | Y | - | Y | Y | - | - | - | - | - | - | - | - | D | |||
optimised green roof substrate | P. grandiflora | S | - | - | Y | - | S | S | - | Y | S | Y | Y | Y | - | - | - | - | - | - | - | D |
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Abuseif, M. Exploring Influencing Factors and Innovative Solutions for Sustainable Water Management on Green Roofs: A Systematic Quantitative Review. Architecture 2023, 3, 294-327. https://doi.org/10.3390/architecture3020017
Abuseif M. Exploring Influencing Factors and Innovative Solutions for Sustainable Water Management on Green Roofs: A Systematic Quantitative Review. Architecture. 2023; 3(2):294-327. https://doi.org/10.3390/architecture3020017
Chicago/Turabian StyleAbuseif, Majed. 2023. "Exploring Influencing Factors and Innovative Solutions for Sustainable Water Management on Green Roofs: A Systematic Quantitative Review" Architecture 3, no. 2: 294-327. https://doi.org/10.3390/architecture3020017
APA StyleAbuseif, M. (2023). Exploring Influencing Factors and Innovative Solutions for Sustainable Water Management on Green Roofs: A Systematic Quantitative Review. Architecture, 3(2), 294-327. https://doi.org/10.3390/architecture3020017