Biochar granulation reduces substrate erosion on green roofs

Liao, Wenxi; Sifton, Melanie A; Thomas, Sean C.

doi:10.1007/s42773-022-00186-7

Cited by 8 publications

(5 citation statements)

References 55 publications

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“…Substrate water retention capacity (WRC) (ln RR = 0.211 ± 0.043, p < 0.001) and plant available water (PAW) (ln RR = 0.288 ± 0.064, p < 0.001) increased with biochar amendment by 23 and 33%, respectively (Figure 2a). Consistent patterns were also reported in the qualitative summary, with Liao et al 44 also revealing that biochar reduced substrate erosion loss (Table 1). 45−79 Biochar showed no mean effect on substrate saturated hydraulic conductivity (ln RR = −0.285 ± 0.505), total porosity (ln RR = −0.079 ± 0.104), or air-filled porosity (ln RR = −0.015 ± 0.067).…”

Section: ■ Resultssupporting

confidence: 84%

“…The highly variable effects of biochar on saturated hydraulic conductivity (Figure a) are likely associated with a large variation of GI substrate composition and texture. Although biochar erosion loss is a concern on green roofs, a recent study showed a reduction of total substrate erosion losses from biochar-amended green roofs due to increased moisture retention and vegetation cover . Losses of biochar particles in discharge water are also a concern; in the meta-analysis, we found a variable but increasing trend of TSS concentrations in discharge with biochar application (Figure b), likely due to fragmentation of friable biochars …”

Section: Discussionmentioning

confidence: 60%

“…Although biochar erosion loss is a concern on green roofs, a recent study showed a reduction of total substrate erosion losses from biochar-amended green roofs due to increased moisture retention and vegetation cover. 44 Losses of biochar particles in discharge water are also a concern; in the meta-analysis, we found a variable but increasing trend of TSS concentrations in discharge with biochar application (Figure 2b), likely due to fragmentation of friable biochars. 60 Biochar increased substrate nutrient content on GI, in part due to high biochar concentrations of P 83 and K, 84 as well as enhanced nutrient retention.…”

Section: ■ Discussionmentioning

confidence: 83%

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Biochar Benefits Green Infrastructure: Global Meta-Analysis and Synthesis

Liao,

Halim,

Kayes

et al. 2023

Environ. Sci. Technol.

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Urbanization has degraded ecosystem services on a global scale, and cities are vulnerable to long-term stresses and risks exacerbated by climate change. Green infrastructure (GI) has been increasingly implemented in cities to improve ecosystem functions and enhance city resilience, yet GI degradation or failure is common. Biochar has been recently suggested as an ideal substrate additive for a range of GI types due to its favorable properties; however, the generality of biochar benefits the GI ecosystem function, and the underlying mechanisms remain unclear.Here, we present a global meta-analysis and synthesis and demonstrate that biochar additions pervasively benefit a wide range of ecosystem functions on GI. Biochar applications were found to improve substrate water retention capacity by 23% and enhance substrate nutrients by 12−31%, contributing to a 33% increase in plant total biomass. Improved substrate physicochemical properties and plant growth together reduce discharge water volume and improve discharge water quality from GI. In addition, biochar increases microbial biomass on GI by ∼150% due to the presence of biochar pores and enhanced microbial growth conditions, while also reducing CO 2 and N 2 O emissions. Overall results suggest that biochar has great potential to enhance GI ecosystem functions as well as urban sustainability and resilience.

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Section: ■ Resultssupporting

confidence: 84%

Section: Discussionmentioning

confidence: 60%

Section: ■ Discussionmentioning

confidence: 83%

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Biochar Benefits Green Infrastructure: Global Meta-Analysis and Synthesis

Liao,

Halim,

Kayes

et al. 2023

Environ. Sci. Technol.

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“…As compared to fine particles, larger particles are more resistant to biochar loss caused by wind and water [59]. Medium to large biochar particles or heavy biochar (processed biochar) were suggested to be used to limit the biochar loss [60,65,76].…”

Section: Biochar Variables: Application Method Amendment Rate and Par...mentioning

confidence: 99%

A Field Study to Investigate the Hydrological Characteristics of Newly Established Biochar-Amended Green Roofs

Nguyen,

Chau,

Muttil

2024

Water

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Green roofs (GRs) have been researched for decades, yet their implementation remains constrained due to several reasons, including their limited appeal to policymakers and the public. Biochar, a carbon-rich material, has been recently introduced as an amendment to GR substrate to enhance the performance of GRs through reduced runoff volume, improved runoff quality, and increased soil fertility. This paper aims to investigate the impact of biochar amendment on the hydrological performance of newly established GRs. Six 1 m × 1 m GR test beds were constructed, comprising of five biochar-amended GR test beds, and one conventional test bed (without any biochar in its substrate). The water retention capacity and runoff outflow delay of the six test beds were studied with the application of artificial rainfall using a nozzle-based simulator. Biochar was found to increase the water retention capacity and effectively delay runoff outflow in the biochar-amended GRs. After nine artificial rainfall events of 110.7 mm rainfall in total, 39.7 to 58.9 L of runoff was retained by the biochar-amended GRs as compared to 37.9 L of runoff retained by the conventional GR. Additionally, the test bed without biochar quickly started releasing runoff after 300 to 750 s, whereas test beds with fine biochar particles could delay runoff outflow by 700 to 1100 s. The performance of the non-biochar and biochar-amended test beds varies according to the values of biochar-related variables such as biochar particle sizes, amendment rates, and application methods. The observational data illustrated that the GR test bed with medium biochar particles applied to the bottom layer of the GR substrate was the optimal biochar-GR design. This selection was determined by the combined performance of high retention rates, long runoff outflow delays, and few other factors, such as lesser loss of biochar caused by wind and/or water.

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“…In addition, a shadowing effect may appear in the photocatalytic reaction of a wood biochar-based photocatalyst [159,160]. This phenomenon is usually due to the fact that the light cannot fully penetrate the thick or dense part of the photocatalyst, thus reducing the effective light absorption on the surface of the catalyst, resulting in some areas not being irradiated by light and affecting the catalytic reaction [161][162][163]. The shadowing effect can be reduced by the following strategies: (1) Adjusting the structure of the catalyst [164]: by designing the catalyst structure with a larger pore size and lower density, the penetration depth of light can be increased and the shadowing effect can be reduced.…”

Section: Limitation Of Woody Biochar-based Photocatalysts In Water Tr...mentioning

confidence: 99%

A Wooden Carbon-Based Photocatalyst for Water Treatment

Zhang,

Ge-Zhang,

Wang

et al. 2024

IJMS

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Due to a large number of harmful chemicals flowing into the water source in production and life, the water quality deteriorates, and the use value of water is reduced or lost. Biochar has a strong physical adsorption effect, but it can only separate pollutants from water and cannot eliminate pollutants fundamentally. Photocatalytic degradation technology using photocatalysts uses chemical methods to degrade or mineralize organic pollutants, but it is difficult to recover and reuse. Woody biomass has the advantages of huge reserves, convenient access and a low price. Processing woody biomass into biochar and then combining it with photocatalysts has played a complementary role. In this paper, the shortcomings of a photocatalyst and biochar in water treatment are introduced, respectively, and the advantages of a woody biochar-based photocatalyst made by combining them are summarized. The preparation and assembly methods of the woody biochar-based photocatalyst starting from the preparation of biochar are listed, and the water treatment efficiency of the woody biochar-based photocatalyst using different photocatalysts is listed. Finally, the future development of the woody biochar-based photocatalyst is summarized and prospected.

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Biochar granulation reduces substrate erosion on green roofs

Cited by 8 publications

References 55 publications

Biochar Benefits Green Infrastructure: Global Meta-Analysis and Synthesis

Biochar Benefits Green Infrastructure: Global Meta-Analysis and Synthesis

A Field Study to Investigate the Hydrological Characteristics of Newly Established Biochar-Amended Green Roofs

A Wooden Carbon-Based Photocatalyst for Water Treatment

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