Hostname: page-component-78c5997874-j824f Total loading time: 0 Render date: 2024-11-19T15:26:33.287Z Has data issue: false hasContentIssue false

Prospects of porous concrete as a plant-growing medium and structural component for green roofs: a review

Published online by Cambridge University Press:  25 May 2022

Md Sazan Rahman
Affiliation:
Department of Bioresource Engineering, Macdonald Stewart Building, McGill University, 21111 Lakeshore Road, Ste-Anne-de-Bellevue, QC H9X 3V9, Canada
Sarah MacPherson
Affiliation:
Department of Bioresource Engineering, Macdonald Stewart Building, McGill University, 21111 Lakeshore Road, Ste-Anne-de-Bellevue, QC H9X 3V9, Canada
Mark Lefsrud*
Affiliation:
Department of Bioresource Engineering, Macdonald Stewart Building, McGill University, 21111 Lakeshore Road, Ste-Anne-de-Bellevue, QC H9X 3V9, Canada
*
Author for correspondence: Mark Lefsrud, E-mail: [email protected]

Abstract

Green roof technology can partially mitigate the adverse effects of urbanization by controlling stormwater runoff, pre-filtering water, minimizing climate change outcomes and reducing heat island effects. However, improvements to current green roof systems and innovative approaches are paramount to advancing environmental benefits and consumer acceptance of this technology. Regular green roofs are hindered by high cost and mass, as well as the incorporation of large amounts of polymers. Hydroponic green roofs (HGRs) require specific setups, maintenance and frequent replacement of plant-growing substrate, with limited energy savings in the heating and cooling load of the building due to the space between the roof surface and the hydroponic setup. In this review, a comparison of regular and HGRs is provided, and research into the environmental benefits of these technologies, including stormwater control, water purification and lifecycle assessment, is summarized. Following this, the prospect of porous concrete (PC), as a combined plant-growth substrate and structural layer in a novel extensive hydroponic green roof (EHGR) design is proposed, through a compilation and analysis of recent studies reporting the feasibility of this construction material for different applications. The mechanical, hydrological and vegetative properties of PC are discussed. Finally, a new green roof system that incorporates both PC and hydroponics, termed the EHGR system, is presented. This new green roof system may help offset the effects of urbanization by providing stormwater and pollution control, runoff delay and physical and thermal benefits, while concurrently producing biomass from a reusable substrate.

Type
Review Article
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Ahammed, F (2017) A review of water-sensitive urban design technologies and practices for sustainable stormwater management. Sustainable Water Resources Management 3, 269282.CrossRefGoogle Scholar
Akbari, H (1997) Peak power and cooling energy savings of shade trees. Energy and Buildings 25, 139148.CrossRefGoogle Scholar
Alsubih, M, Arthur, S, Wright, G and Allen, D (2017) Experimental study on the hydrological performance of a permeable pavement. Urban Water Journal 14, 427434.CrossRefGoogle Scholar
Andrenko, I, Montague, T, McKenney, C and Plowman, R (2020) Salinity tolerance of select wildflower species in a hydroponic setting. HortScience 1, 113.Google Scholar
Antrop, M (2004) Landscape change and the urbanization process in Europe. Landscape and Urban Planning 67, 926.CrossRefGoogle Scholar
Ascione, F, Bianco, N, de'Rossi, F, Turni, G and Vanoli, GP (2013) Green roofs in European climates. Are effective solutions for the energy savings in air-conditioning? Applied Energy 104, 845859.CrossRefGoogle Scholar
ASTM (2017) D5683: Standard Test Method for Flexibility of Roofing and Waterproofing Materials and Membranes. West Conshohocken, PA, USA: American Society for Testing and Materials (ASTM). Available at doi:10.1520/D5683_D5683M-95R17 (Accessed 17 August 2020).Google Scholar
Barthel, S, Isendahl, C, Vis, BN, Drescher, A, Evans, DL and van Timmeren, A (2019) Global urbanization and food production in direct competition for land: leverage places to mitigate impacts on SDG2 and on the Earth System. The Anthropocene Review 6, 7197.CrossRefGoogle Scholar
Bates, AJ, Sadler, JP and Mackay, R (2013) Vegetation development over four years on two green roofs in the UK. Urban Forestry & Urban Greening 12, 98108.CrossRefGoogle Scholar
Beck, DA, Johnson, GR and Spolek, GA (2011) Amending greenroof soil with biochar to affect runoff water quantity and quality. Environmental Pollution 159, 21112118.CrossRefGoogle ScholarPubMed
Berardi, U, GhaffarianHoseini, A and GhaffarianHoseini, A (2014) State-of-the-art analysis of the environmental benefits of green roofs. Applied Energy 115, 411428.CrossRefGoogle Scholar
Berndtsson, JC (2010) Green roof performance towards management of runoff water quantity and quality: a review. Ecological Engineering 36, 351360.CrossRefGoogle Scholar
Berndtsson, JC, Emilsson, T and Bengtsson, L (2006) The influence of extensive vegetated roofs on runoff water quality. Science of the Total Environment 355, 4863.CrossRefGoogle ScholarPubMed
Berndtsson, JC, Bengtsson, L and Jinno, K (2008) First flush effect from vegetated roofs during simulated rain events. Hydrology Research 39, 171179.CrossRefGoogle Scholar
Bessenouci, M, Triki, NB, Khelladi, S, Draoui, B and Abene, A (2011) The apparent thermal conductivity of pozzolana concrete. Physics Procedia 21, 5966.CrossRefGoogle Scholar
Bhutta, MAR, Hasanah, N, Farhayu, N, Hussin, MW, bin Md Tahir, M and Mirza, J (2013) Properties of porous concrete from waste crushed concrete (recycled aggregate). Construction and Building Materials 47, 12431248.CrossRefGoogle Scholar
Bianchini, F and Hewage, K (2012) How ‘green’ are the green roofs? Lifecycle analysis of green roof materials. Building and Environment 48, 5765.CrossRefGoogle Scholar
Bisceglie, F, Gigante, E and Bergonzoni, M (2014) Utilization of waste autoclaved aerated concrete as lighting material in the structure of a green roof. Construction and Building Materials 69, 351361.CrossRefGoogle Scholar
Blank, L, Vasl, A, Levy, S, Grant, G, Kadas, G, Dafni, A and Blaustein, L (2013) Directions in green roof research: a bibliometric study. Building and Environment 66, 2328.CrossRefGoogle Scholar
Bliss, DJ, Neufeld, RD and Ries, RJ (2009) Storm water runoff mitigation using a green roof. Environmental Engineering Science 26, 407418.CrossRefGoogle Scholar
Bougoul, S, Ruy, S, De Groot, F and Boulard, T (2005) Hydraulic and physical properties of stonewool substrates in horticulture. Scientia Horticulturae 104, 391405.CrossRefGoogle Scholar
Cao, CT, Farrell, C, Kristiansen, PE and Rayner, JP (2014) Biochar makes green roof substrates lighter and improves water supply to plants. Ecological Engineering 71, 368374.CrossRefGoogle Scholar
Catalano, C, Laudicina, VA, Badalucco, L and Guarino, R (2018) Some European green roof norms and guidelines through the lens of biodiversity: do ecoregions and plant traits also matter? Ecological Engineering 115, 1526.CrossRefGoogle Scholar
Chen, J and Poon, C-S (2009) Photocatalytic activity of titanium dioxide modified concrete materials – influence of utilizing recycled glass cullets as aggregates. Journal of Environmental Management 90, 34363442.CrossRefGoogle ScholarPubMed
Chow, MF and Bakar, MFA (2017) Environmental benefits of green roof to the sustainable urban development: a review. Proceedings of the 1st Global Civil Engineering Conference, GCEC 2017, 1525–1541, Kuala Lumpur, Malaysia. https://doi.org/10.1007/978-981-10-8016-6_110CrossRefGoogle Scholar
Collins, KA, Hunt, WF and Hathaway, JM (2008) Hydrologic comparison of four types of permeable pavement and standard asphalt in eastern North Carolina. Journal of Hydrologic Engineering 13, 11461157.CrossRefGoogle Scholar
DeNardo, J, Jarrett, A, Manbeck, H, Beattie, D and Berghage, R (2005) Stormwater mitigation and surface temperature reduction by green roofs. Transactions of the ASAE 48, 14911496.CrossRefGoogle Scholar
Dinsdale, S, Pearen, B and Wilson, C (2006) Feasibility Study for Green Roof Application on Queen's University Campus. Kingston, Canada: Retrieved from Queen's Physical Plant Services, Queens University.Google Scholar
Drake, J, Bradford, A and Van Seters, T (2014) Hydrologic performance of three partial-infiltration permeable pavements in a cold climate over low permeability soil. Journal of Hydrologic Engineering 19, 04014016.CrossRefGoogle Scholar
Eksi, M, Rowe, DB, Wichman, IS and Andresen, JA (2017) Effect of substrate depth, vegetation type, and season on green roof thermal properties. Energy and Buildings 145, 174187.CrossRefGoogle Scholar
EPA (2016) Update on Green Roof ASTM Standards. United States Environmental Protection Agency, Washington, D.C., United States. Available at https://www.epa.gov/heatislands/update-green-roof-astm-standards (Accessed 28 August 2020).Google Scholar
EPA (2020) Automated Hydroponic Green Roof with Rainwater Recycling Infrastructure for Residential and Commercial Buildings. EPA Grant Number: SU836133. USA: Environmental Protection Agency, Washington, D.C., United States. Available at https://cfpub.epa.gov/ncer_abstracts/index.cfm/fuseaction/display.abstractDetail/abstract_id/10539/report/F (Accessed 8 July 2020).Google Scholar
Fassman, EA and Blackbourn, S (2010) Urban runoff mitigation by a permeable pavement system over impermeable soils. Journal of Hydrologic Engineering 15, 475485.CrossRefGoogle Scholar
Gao, J, Zhou, M, Xu, W, Liu, D, Shen, J, Peng, S and Du, Y (2020) The evolution of structure properties of vegetation concrete under freeze–thaw cycles. The International Journal of Electrical Engineering & Education 0, 1-19.CrossRefGoogle Scholar
Getter, KL and Rowe, DB (2006) The role of extensive green roofs in sustainable development. HortScience 41, 12761285.CrossRefGoogle Scholar
Getter, KL, Rowe, DB, Andresen, JA and Wichman, IS (2011) Seasonal heat flux properties of an extensive green roof in a Midwestern US climate. Energy and Buildings 43, 35483557.CrossRefGoogle Scholar
Ghafoori, N and Dutta, S (1995) Pavement thickness design for no-fines concrete parking lots. Journal of Transportation Engineering 121, 476484.CrossRefGoogle Scholar
Greenroofs (2020) Changi General Hospital, Greenroof Projects. Greenroofs, Toronto, Canada. Available at https://www.greenroofs.com/projects/changi-general-hospital/ (Accessed 30 June 2020).Google Scholar
Hasan, M, Zain, MFM, Hamid, R, Kaish, A and Nahar, S (2017) A comprehensive study on sustainable photocatalytic pervious concrete for storm water pollution mitigation: a review. Materials Today: Proceedings 4 97739776.Google Scholar
Hashemi, SSG, Mahmud, HB and Ashraf, MA (2015) Performance of green roofs with respect to water quality and reduction of energy consumption in tropics: a review. Renewable & Sustainable Energy Reviews 52, 669679.CrossRefGoogle Scholar
Hilten, RN (2005) An Analysis of the Energetics and Stormwater Mediation Potential of Greenroofs (MSc thesis). University of Georgia, Athens, GA, USA.Google Scholar
Hitti, Y (2018) Bio-Receptive Ground Granulated Blast-Furnace Slag Porous Concrete Substrate (MSc thesis). Department of Bioresource Engineering, McGill University, Montreal, Canada.Google Scholar
Hitti, Y, Chapelat, J, Wu, BS and Lefsrud, M (2021) Design and testing of bioreceptive porous concrete: a new substrate for soilless plant growth. ACS Agricultural Science & Technology 1, 285-293.CrossRefGoogle Scholar
Huang, YY, Chen, CT and Tsai, YC (2016) Reduction of temperatures and temperature fluctuations by hydroponic green roofs in a subtropical urban climate. Energy and Buildings 129, 174185.CrossRefGoogle Scholar
Inden, H and Torres, A (2001) Comparison of four substrates on the growth and quality of tomatoes. ISHS Acta Horticulturae 644: International Symposium on Growing Media and Hydroponics, Alnarp, Sweden. https://doi.org/10.17660/ActaHortic.2004.644.27CrossRefGoogle Scholar
Ioannidou, VG and Arthur, S (2020) Experimental results of the hydrological performance of a permeable pavement laboratory rig. Journal of Water Supply: Research Technology – AQUA 69, 210223.CrossRefGoogle Scholar
Jiang, L and O'Neill, BC (2017) Global urbanization projections for the shared socioeconomic pathways. Global Environmental Change 42, 193199.CrossRefGoogle Scholar
Jianming, G, Xu, G and Lu, X (2008) Experimental study on eco-environmental effect of porous concrete. Journal of Southeast University 38, 794798.Google Scholar
Jones, JB Jr (2016) Hydroponics: A Practical Guide for the Soilless Grower. Boca Raton, FL, USA: CRC press.CrossRefGoogle Scholar
Kim, G, Jang, J, Khalid, HR and Lee, H-K (2017) Water purification characteristics of pervious concrete fabricated with CSA cement and bottom ash aggregates. Construction and Building Materials 136, 18.CrossRefGoogle Scholar
Kotsiris, G, Nektarios, PA, Ntoulas, N and Kargas, G (2013) An adaptive approach to intensive green roofs in the Mediterranean climatic region. Urban Forestry & Urban Greening 12, 380392.CrossRefGoogle Scholar
Koupai, JA, Nejad, SS, Mostafazadeh-Fard, S and Behfarnia, K (2016) Reduction of urban storm-runoff pollution using porous concrete containing iron slag adsorbent. Journal of Environmental Engineering 142, 04015072.CrossRefGoogle Scholar
Kuruppu, U, Rahman, A and Rahman, MA (2019) Permeable pavement as a stormwater best management practice: a review and discussion. Environmental Earth Sciences 78, 327.CrossRefGoogle Scholar
Lackhoff, M, Prieto, X, Nestle, N, Dehn, F and Niessner, R (2003) Photocatalytic activity of semiconductor-modified cement – influence of semiconductor type and cement ageing. Applied Catalysis B: Environmental 43, 205216.CrossRefGoogle Scholar
Lian, C and Zhuge, Y (2010) Optimum mix design of enhanced permeable concrete – an experimental investigation. Construction and Building Materials 24, 26642671.CrossRefGoogle Scholar
Liang, X, Cui, S, Li, H, Abdelhady, A, Wang, H and Zhou, H (2019) Removal effect on stormwater runoff pollution of porous concrete treated with nanometer titanium dioxide. Transportation Research Part D: Transport Environmental Earth Sciences 73, 3445.CrossRefGoogle Scholar
Lin, W, Ryu, S and Cho, Y-H (2016) Performance of permeable block pavements in accelerated pavement test and rainfall simulation. Journal of Performance of Constructed Facilities 30, 04014186.CrossRefGoogle Scholar
Liu, Y, Li, T and Yu, L (2020) Urban heat island mitigation and hydrology performance of innovative permeable pavement: a pilot-scale study. Journal of Cleaner Production 244, 118938.CrossRefGoogle Scholar
Lundholm, JT, Weddle, BM and MacIvor, JS (2014) Snow depth and vegetation type affect green roof thermal performance in winter. Energy and Buildings 84, 299307.CrossRefGoogle Scholar
MacIvor, JS, Margolis, L, Puncher, CL and Matthews, BJC (2013) Decoupling factors affecting plant diversity and cover on extensive green roofs. Journal of Environmental Management 130, 297305.CrossRefGoogle ScholarPubMed
MacIvor, JS, Margolis, L, Perotto, M and Drake, JA (2016) Air temperature cooling by extensive green roofs in Toronto Canada. Ecological Engineering 95, 3642.CrossRefGoogle Scholar
Mahdiyar, A, Mohandes, SR, Durdyev, S, Tabatabaee, S and Ismail, S (2020) Barriers to green roof installation: an integrated fuzzy-based MCDM approach. Journal of Cleaner Production 269, 122365.CrossRefGoogle Scholar
Ministry of Housing and Urban-Rural Development-China (2012) GB50009: Load Code for the Design of Building Structures. Beijing, China: Ministry of Housing and Urban-Rural Construction of the People's Republic of China.Google Scholar
Moran, A, Hunt, B and Jennings, G (2003) A North Carolina field study to evaluate greenroof runoff quantity, runoff quality, and plant growth. World Water & Environmental Resources Congress, June 23-26, 2003 | Philadelphia, Pennsylvania, United States. https://doi.org/10.1061/40685(2003)335Google Scholar
Niu, H, Clark, C, Zhou, J and Adriaens, P (2010) Scaling of economic benefits from green roof implementation in Washington, DC. Environmental Science & Technology 44, 43024308.CrossRefGoogle ScholarPubMed
Ntoulas, N, Nektarios, PA, Kapsali, TE, Kaltsidi, MP, Han, L and Yin, S (2015) Determination of the physical, chemical, and hydraulic characteristics of locally available materials for formulating extensive green roof substrates. Horttechnology 25, 774784.CrossRefGoogle Scholar
Oh, RO, Cha, SS, Park, SY, Lee, HJ, Park, SW and Park, CG (2014) Mechanical properties and water purification characteristics of natural jute fiber-reinforced non-cement alkali-activated porous vegetation blocks. Paddy and Water Environment 12, 149156.CrossRefGoogle Scholar
Ouldboukhitine, SE, Belarbi, R and Djedjig, R (2012) Characterization of green roof components: measurements of thermal and hydrological properties. Building and Environment 56, 7885.CrossRefGoogle Scholar
Pandey, S, Hindoliya, D and Mod, R (2013) Experimental investigation on green roofs over buildings. International Journal of Low-Carbon Technologies 8, 3742.Google Scholar
Park, SB and Tia, M (2004) An experimental study on the water-purification properties of porous concrete. Cement and Concrete Research 34, 177184.CrossRefGoogle Scholar
Roseen, RM, Ballestero, TP, Houle, JJ, Briggs, JF and Houle, KM (2012) Water quality and hydrologic performance of a porous asphalt pavement as a storm-water treatment strategy in a cold climate. Journal of Environmental Engineering 138, 8189.CrossRefGoogle Scholar
Rosenzweig, C, Solecki, W and Slosberg, R (2006) Mitigating New York City's Heat Island with Urban Forestry, Living Roofs, and Light Surfaces. A report to the New York State Energy Research Development Authority.Google Scholar
Sailor, D (2008) A green roof model for building energy simulation programs. Energy and Buildings 40, 14661478.CrossRefGoogle Scholar
Sailor, D, Hutchinson, D and Bokovoy, L (2008) Thermal property measurements for ecoroof soils common in the western US. Energy and Buildings 40, 12461251.CrossRefGoogle Scholar
Sansalone, J and Teng, Z (2004) In situ partial exfiltration of rainfall runoff. I: quality and quantity attenuation. Journal of Environmental Engineering 130, 9901007.CrossRefGoogle Scholar
Santamouris, M, Pavlou, C, Doukas, P, Mihalakakou, G, Synnefa, A, Hatzibiros, A and Patargias, P (2007) Investigating and analysing the energy and environmental performance of an experimental green roof system installed in a nursery school building in Athens, Greece. Energy 32, 17811788.CrossRefGoogle Scholar
Sañudo-Fontaneda, LA, Andres-Valeri, VC, Costales-Campa, C, Cabezon-Jimenez, I and Cadenas-Fernandez, F (2018) The long-term hydrological performance of permeable pavement systems in northern Spain: an approach to the ‘end-of-life’ concept. Water Quality Research Journal of Canada 10, 497.Google Scholar
Shafique, M, Kim, R and Rafiq, M (2018) Green roof benefits, opportunities and challenges – a review. Renewable & Sustainable Energy Reviews 90, 757773.CrossRefGoogle Scholar
She, N and Pang, J (2010) Physically based green roof model. Journal of Hydrologic Engineering 15, 458464.CrossRefGoogle Scholar
Song, U, Kim, E, Bang, JH, Son, DJ, Waldman, B and Lee, EJ (2013) Wetlands are an effective green roof system. Building and Environment 66, 141147.CrossRefGoogle Scholar
Sperling, LH (2005) Introduction to Physical Polymer Science. Hoboken, NJ, USA: John Wiley & Sons.CrossRefGoogle Scholar
Stovin, V (2010) The potential of green roofs to manage urban stormwater. Water Environment Journal 24, 192199.CrossRefGoogle Scholar
Sun, Y, Gao, P, Geng, F, Li, H, Zhang, L and Liu, H (2017) Thermal conductivity and mechanical properties of porous concrete materials. Materials Letters 209, 349352.CrossRefGoogle Scholar
Suripin, S, Sangkawati, SS, Pranoto, SA, Sutarto, E, Hary, B and Dwi, K (2018) Reducing stormwater runoff from parking lot with permeable pavement. E3S Web of Conferences, 73, 05016. https://doi.org/10.1051/e3sconf/20187305016CrossRefGoogle Scholar
Susca, T (2019) Green roofs to reduce building energy use? A review on key structural factors of green roofs and their effects on urban climate. Building and Environmental 162, 106273.CrossRefGoogle Scholar
Tala, S, Al-Ajlouni, MG, Ayad, JY, Othman, YA and Hilaire, RS (2020) Performance of six different soilless green roof substrates for the Mediterranean region. Science of the Total Environment 730, 139182.Google Scholar
Tanaka, Y, Kawashima, S, Hama, T and Nakamura, K (2017) Thermal mitigation of hydroponic green roof based on heat balance. Urban Forestry & Urban Greening 24, 92100.CrossRefGoogle Scholar
Tang, W, Mohseni, E and Wang, Z (2018) Development of vegetation concrete technology for slope protection and greening. Construction and Building Materials 179, 605613.CrossRefGoogle Scholar
Teemusk, A and Mander, Ü (2007) Rainwater runoff quantity and quality performance from a greenroof: the effects of short-term events. Ecological Engineering 30, 271277.CrossRefGoogle Scholar
Teymouri, E, Mousavi, SF, Karami, H, Farzin, S and Kheirabad, MH (2020) Reducing urban runoff pollution using porous concrete containing mineral adsorbents. Journal of Environmental Treatment Techniques 8, 429436.Google Scholar
van der Meulen, SH (2019) Costs and benefits of green roof types for cities and building owners. Journal of Sustainable Development of Energy, Water Environment Systems 7, 5771.CrossRefGoogle Scholar
Van Mechelen, C, Dutoit, T and Hermy, M (2015) Adapting green roof irrigation practices for a sustainable future: a review. Sustainable Cities Society 19, 7490.CrossRefGoogle Scholar
Vijayaraghavan, K (2016) Green roofs: a critical review on the role of components, benefits, limitations and trends. Renewable & Sustainable Energy Reviews 57, 740752.CrossRefGoogle Scholar
Williams, KJ, Lee, KE, Sargent, L, Johnson, KA, Rayner, J, Farrell, C, Miller, RE and Williams, NS (2019) Appraising the psychological benefits of green roofs for city residents and workers. Urban Forestry & Urban Greening 44, 126399.CrossRefGoogle Scholar
Winston, RJ, Arend, K, Dorsey, JD and Hunt, WF (2020) Water quality performance of a permeable pavement and stormwater harvesting treatment train stormwater control measure. Blue-Green Systems 2, 91111.CrossRefGoogle Scholar
Wolf, D and Lundholm, J (2008) Water uptake in green roof microcosms: effects of plant species and water availability. Ecological Engineering 33, 179186.CrossRefGoogle Scholar
Wong, JKW and Lau, LSK (2013) From the ‘urban heat island’ to the ‘green island’? A preliminary investigation into the potential of retrofitting green roofs in Mongkok district of Hong Kong. Habitat International 39, 2535.CrossRefGoogle Scholar
Xu, L, Yang, S, Zhang, Y, Jin, Z, Huang, X, Bei, K, Zhao, M, Kong, H and Zheng, X (2020 a) A hydroponic green roof system for rainwater collection and greywater treatment. Journal of Cleaner Production 261, 121132.CrossRefGoogle Scholar
Xu, Y, Jin, R, Hu, L, Li, B, Chen, W, Shen, J, Wu, P and Fang, J (2020 b) Studying the mix design and investigating the photocatalytic performance of pervious concrete containing TiO2-Soaked recycled aggregates. Journal of Cleaner Production 248, 119281.CrossRefGoogle Scholar
Yang, J, Yu, Q and Gong, P (2008) Quantifying air pollution removal by green roofs in Chicago. Atmospheric Environment 42, 72667273.CrossRefGoogle Scholar
Yao, L, Chini, A and Zeng, R (2020) Integrating cost–benefits analysis and life cycle assessment of green roofs: a case study in Florida. Human Ecological Risk Assessment: An International Journal 26, 443458.Google Scholar
Zhang, R, Kanemaru, K and Nakazawa, T (2015) Purification of river water quality using precast porous concrete products. Journal of Advanced Concrete Technology 13, 163168.Google Scholar
Zhao, M, Jia, Y, Yuan, L, Qiu, J and Xie, C (2019) Experimental study on the vegetation characteristics of biochar-modified vegetation concrete. Construction and Building Materials 206, 321328.CrossRefGoogle Scholar