Experimental study on the hydrological performance of green roofs in the application of novel biochar

Experimental study on the hydrological performance of green roofs in the application of novel biochar

Biochar has the potential to be a soil amendment in green roofs owing to its water retention, nutrient supply, and carbon sequestration application. The combined effects of biochar and vegetated soil on hydraulic performance (e.g., saturated hydraulic conductivity, retention and detention, and runof...

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Bibliographic Details
Published in:Hydrological processes Vol. 34; no. 23; pp. 4512 - 4525
Main Authors: Huang, Shan, Garg, Ankit, Mei, Guoxiong, Huang, Disheng, Chandra, Rahul Balaji, Sadasiv, Shaji Gayathri
Format: Journal Article
Language:English
Published: Hoboken, USA John Wiley & Sons, Inc 15-11-2020
Wiley Subscription Services, Inc
Subjects:
biochar
Carbon sequestration
Charcoal
detention
Green buildings
green roof
Green roofs
Heavy rainfall effects
Hydraulic conductivity
Hydraulic performance
Hydraulics
Hydrologic processes
Hydrologic studies
Hydrology
Moisture content
Nutrient cycles
Nutrient retention
Parameter estimation
Permeability
Ponding
Rain
Rainfall
Rainfall simulators
Rainmaking
Retention
Roofs
Runoff
Soil
Soil amendment
Soil columns
Soil improvement
Soil investigations
Soil permeability
Soil suction
Soil water
Soil water potential
Soils
Sustainable design
vegetation
Water content
Water potential
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Summary:Biochar has the potential to be a soil amendment in green roofs owing to its water retention, nutrient supply, and carbon sequestration application. The combined effects of biochar and vegetated soil on hydraulic performance (e.g., saturated hydraulic conductivity, retention and detention, and runoff delay) are the crucial factor for the application of the novel biochar in green roofs. Recent studies investigated soil water potential (i.e., suction) either on vegetated soil or on biochar‐amended soil but rarely focused on their integrated application. With the purpose of investigating the hydraulic performance of green roofs in the application of biochar, the combined effect of biochar and vegetated soil on hydrological processes was explored. Artificial rainfall experiments were conducted on the four types of experimental soil columns, including natural soil, biochar‐amended soil, vegetated natural soil, and vegetated biochar‐amended soil. The surface ponding, bottom drainage and the volumetric water content were measured during the rainfall test. Simulation method by using HYDRUS‐1D was adopted for estimating hydraulic parameters and developing modelling analysis. The results indicated that the saturated hydraulic conductivity of vegetated soil columns were higher than bare soil columns. The addition of biochar decreased the saturated hydraulic conductivity, and the magnitude of decrease was much significant in the case of vegetated soil. The influence of vegetation on permeability is more prominent than biochar. The vegetated biochar‐amended soil has the highest retention and detention capacity, and shows a preferable runoff delay effect under heavy rain among the four soil columns. The results from the present study help to understand the hydrological processes in the green roof in the application of biochar, and imply that biochar can be an alternative soil amendment to improve the hydraulic performance. The hydrological performance of green roofs in the application of novel biochar was evaluated and discussed in context on the basis of the experimental study and simulation analysis.
Bibliography:Funding information
Bagui Scholars Program, Grant/Award Number: 2016A31; Innovative Research Team Program of Guangxi Natural Science Foundation, Grant/Award Number: 2016GXNSFGA380008; National Natural Science Foundation of China, Grant/Award Numbers: 41672296, 41867034, 51878185
This work had been supported by the National Natural Science Foundation of China (Grant No. 41672296, 51878185, 41867034), the Innovative Research Team Program of Guangxi Natural Science Foundation (Grant No. 2016GXNSFGA380008), the Bagui Scholars Program (Grant No. 2016A31) and the China Scholarship Council (CSC) (Grant No. 201906660001, 201808455023).
ISSN:0885-6087
1099-1085
DOI:10.1002/hyp.13881