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Biochar Affects Greenhouse Gas Emissions from Urban Forestry Waste

A peer-reviewed version of this preprint was published in:
Land 2025, 14(8), 1605. https://doi.org/10.3390/land14081605

Submitted:

24 June 2025

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25 June 2025

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Abstract
Urban forests are vital to cities as they provide a range of ecosystem services, including carbon (C) sequestration, air purification, and urban cooling. However, urban forestry also generates significant quantities of organic waste, such as grass clippings, pruned tree branches, and fallen tree leaves and woody debris, contributing to the release of greenhouse gases (GHGs) if those organic wastes are improperly managed. We studied the effect of wheat straw biochar produced at 500 °C on GHG emissions from two common types of urban forestry waste: green waste (GW) and yard waste (YW), using a 100-day laboratory incubation experiment. Compared to YW, GW consistently emitted more CO₂ throughout the incubation period, but biochar addition reduced CO₂ emissions by 9.8% and 17.6% from GW and YW, respectively, by day 100. Biochar application increased CH₄ emissions from GW, peaking on day 70 at a rate of 80.2 mg C kg⁻¹. The YW and biochar-amended YW exhibited negative cumulative CH₄ emissions, acting as CH₄ sinks; however, the addition of biochar weakened the CH₄ sink of YW. Biochar addition increased N₂O emissions from GW by 94.3% but decreased its emissions from YW by 61.4% by day 100. The global warming potential was highest in GW added with biochar, at 125.3 g CO₂-eq kg⁻¹, resulting from biochar addition exacerbating GHG emissions from GW. Our findings emphasize the importance of evaluating the effect of biochar on GHG emissions for specific urban forestry waste. Different biochars need to be tested to find one that can mitigate GHG emissions from GW.
Keywords: 
Urbanization
;  
Urban waste
;  
Climate change
;  
Urban green space
;  
GHG emissions
Subject: 
Environmental and Earth Sciences  -   Environmental Science

1. Introduction

Urban forests are important to cities and provide a range of ecosystem services, including carbon (C) sequestration, air purification, and urban cooling, which enhance the quality of life for urban populations (Ariluoma et al., 2021; Shafique et al., 2020). As urbanization accelerates globally, urban forests are increasingly recognized as critical components of sustainable urban ecosystems (Reyes-Riveros et al., 2021). However, urban forests also generate significant quantities of organic waste, including grass clippings, pruned branches, leaf litter, and fallen woody debris, primarily resulting from landscaping and maintenance activities. Those organic wastes, often sent to dump sites, pose significant environmental challenges if improperly managed (Lan et al., 2022). When waste materials undergo microbial decomposition, they release greenhouse gases (GHGs), including carbon dioxide (CO₂), methane (CH₄), and nitrous oxide (N₂O) —which all contribute to the global warming potential (GWP), although some have a much stronger effect than others. A study conducted in five municipalities of Paraíba state, northeast Brazil, revealed that improper disposal of urban tree pruning waste resulted in emissions of >1 Mt CO2 equivalent over a ten-year period (Araujo et al., 2024). These emissions contribute to global warming and exacerbate other forms of climate change, underscoring the urgent need for sustainable waste management strategies tailored to urban contexts.
While considerable research has been conducted on GHG emissions from soils or soil systems amended with organic waste (Chataut et al., 2023; Gross et al., 2022), relatively few studies have directly examined GHG emissions from decomposing urban forestry waste. The decomposition dynamics of organic material in soil differ significantly from those of urban forestry waste, which is often piled at open dumping sites (Osra et al., 2024). Soil emissions are primarily driven by microbial processes that decompose organic matter and are influenced by factors such as soil type, moisture content, temperature, and the quantity and quality of organic inputs (Davidson & Janssens, 2006; Wang et al., 2020). In contrast, greenhouse gas emissions from urban forestry waste are mainly influenced by the chemical composition of the waste (e.g., C:N ratio, lignin content) as well as by exposure to air and fluctuating moisture and temperature conditions (Sánchez et al., 2015). These factors can lead to markedly different emission profiles compared to those observed in soil systems.
Despite the growing volume of urban forestry waste, a notable research gap remains regarding its direct GHG emissions and how those emissions might be mitigated. This gap is critical to address given the unique chemical composition of urban forestry waste compared to agricultural or municipal waste and the increasing quantities generated due to rapid urbanization. For instance, urban forestry waste typically contains higher proportions of recalcitrant organic matter such as lignin, cellulose, and hemicellulose, which decompose more slowly and affect microbial metabolism and gas fluxes differently than typical soil organic matter or food-based municipal waste. Understanding the GHG emissions and environmental impacts of this waste and identifying strategies to reduce those emissions are important. For example, biochar—a carbon-rich material produced through pyrolysis—has been shown to reduce GHG emissions in various organic substrates and soils (Duan et al., 2020; Gross et al., 2022). Recent studies have shown that incorporating biochar into urban green infrastructure increases nutrient availability, enhances water retention, stimulates microbial activity, promotes plant growth, and improves carbon sequestration (Liao et al., 2023; Senadheera et al., 2024). A mesocosm experiment demonstrated that biochar can enhance CH₄ uptake and alter CO₂ fluxes when applied with mulched urban forestry waste, such as woodchips and bark, by modifying microbial activity, pH, and C:N ratios, as well as improving substrate aeration and reducing water loss (Kayes et al., 2025). These findings highlight the multifaceted role of biochar in modulating GHG fluxes from organic waste systems, including its capacity to influence microbial communities and substrate conditions. However, studies investigating the effects of biochar on greenhouse gas emissions and the underlying physicochemical and microbial changes during the decomposition of urban forestry waste are still limited.
In this study, we examined the effects of biochar on GHG emissions from two common types of urban forestry waste: green waste, which is composed primarily of grass clippings, fresh leaves, and small branches from pruning operations, and yard waste, which includes wood debris, composted urban forestry waste, and soil that has mixed in during collection or processing. We hypothesized that biochar influences GHG emissions by altering extracellular enzyme activity and the physicochemical properties of urban forestry waste, thereby reducing GHG production during decomposition. The objectives of this study were to (i) assess CO₂, CH₄, and N₂O emissions from green waste and yard waste, (ii) examine the impact of biochar addition on extracellular hydrolytic enzyme activities and the physicochemical properties of these wastes, and (iii) evaluate how these changes influence GHG emissions and GWP. The findings can support local policymakers, urban planners, and environmental managers in identifying more sustainable strategies for managing urban forestry waste, with potential contributions to regional sustainability and climate action efforts.2. Materials and Methods
The Materials and Methods should be described with sufficient details to allow others to replicate and build on the published results. Please note that the publication of your manuscript implicates that you must make all materials, data, computer code, and protocols associated with the publication available to readers. Please disclose at the submission stage any restrictions on the availability of materials or information. New methods and protocols should be described in detail while well-established methods can be briefly described and appropriately cited.
Research manuscripts reporting large datasets that are deposited in a publicly available database should specify where the data have been deposited and provide the relevant accession numbers. If the accession numbers have not yet been obtained at the time of submission, please state that they will be provided during review. They must be provided prior to publication.
Interventionary studies involving animals or humans, and other studies that require ethical approval, must list the authority that provided approval and the corresponding ethical approval code.

2. Materials and Methods

2.1. Study Materials

Green waste and yard waste were collected from an urban forestry waste dumping site located in Ambleside (53°25'35.5" N, 113°34'20.3" W), Edmonton, Alberta, Canada, one of the city's designated sites for urban forestry waste disposal. Green waste mostly consists of grass clippings and some fresh leaves. Yard waste consists of compost, wood debris, and soil, which are primarily used for home gardens. The collected materials were homogenized before conducting the incubation experiment. Subsamples were taken to determine the chemical properties of the materials. The initial moisture contents of the green waste and yard waste were 4.6% and 54.3% (w/w), respectively. The C, nitrogen (N) concentrations and C/N ratio were 36.9%, 3.5%, and 10.5, respectively, for the green waste, and 29.1%, 1.5%, and 19.3, respectively, for the yard waste. The biochar used in this study was supplied by Innotech Alberta (Vegreville, AB, CA) and pyrolyzed from wheat (Triticum aestivum) straw at 450-500 °C. The pH, electrical conductivity, C%, N%, and C/N ratio of the biochar were 9.1, 2.4 dS m-1, 56.5%, 0.96%, and 59.1, respectively.

2.2. Experimental Design and Incubation Procedure

The experiment used a completely randomized block design with four treatments and five replications. Two types of organic waste— green waste and yard waste —were each treated with and without biochar, resulting in four treatment combinations. The treatments included green waste without biochar (GW), green waste amended with 2% (w/w) wheat straw biochar (GWB), yard waste without biochar (YW), and yard waste amended with 2% (w/w) wheat straw biochar (YWB). The green waste was cut into small (2–5 cm) pieces to make them more uniform and fit into the jars used for the incubation. Before being used in the incubation, each waste material type was thoroughly mixed and homogenized. The initial moisture content of green waste was very low (4.6%). Since decomposition of organic waste typically begins when the moisture content is between 40% and 60%, we adjusted the moisture content to 50% by adding distilled water. This adjustment was performed to increase microbial activity and initiate the degradation process. When the initial moisture content of the yard waste was 54.3%, the moisture content was maintained at the initial value. For the GW and YW treatments, 50 g and 100 g of fresh material, respectively, were placed into 1 L Mason jars. For the GWB and YWB treatments, each material was mixed with biochar at a rate of 2% (w/w) on an oven-dry weight basis before being placed into 1 L Mason jars. The materials were compacted to a specific depth in all treatments, ensuring a consistent bulk density. The moisture content of all treatments was adjusted by adding distilled water every three days based on the weight loss observed throughout incubation. Since destructive sampling affects GHG measurements, two separate incubation experiments (for each waste type) were set up in parallel: one for measuring GHG emissions and the other for analyzing enzyme activities and physicochemical properties on days 1, 10, 50, and 100. The Mason jars were covered with aluminum foil, and pin holes were punctured in the foil to provide ventilation while minimizing water loss throughout the incubation. All the treatments were incubated at 22 °C. To maintain a humid environment and further minimize moisture loss from the incubated materials, 10 mL of Milli-Q water was added to a beaker placed inside the incubator (Impraim et al., 2022; Li et al., 2021).

2.3. Gas and Incubation Material Sampling and Analysis

Gas samples were collected from the headspace of the Mason jars on days 1, 3, 5, 7, 10, 13, 16, 19, 22, 22, 25, 30, 35, 40, 45, 50, 55, 60, 70, 80, 90, and 100. The GHG concentrations were determined via a gas chromatograph (Varian CP-3800, Mississauga, ON, Canada) equipped with a thermal conductivity detector (for detecting CO2), an electron capture detector (for detecting N2O), and a flame ionization detector (for detecting CH4) (Li et al., 2021; Li et al., 2022). The incubated waste materials were destructively sampled from the Mason jars on days 1, 10, 50, and 100 to determine their enzyme activities and physicochemical properties.

2.4. Analysis of Enzyme Activities and Physicochemical Properties of the Incubated Materials

The activities of extracellular hydrolytic enzymes, including β-1,4-glucosidase (BG) and β-1,4-N-acetyl glucosaminidase (NAG), were analyzed in moist waste samples using a fluorometric method following the methods described in Sinsabaugh et al. (2003). For each sample, enzyme activity was determined using fluorogenic substrates: 4-methylumbelliferyl-β-D-glucopyranoside for BG and 4-methylumbelliferyl-N-acetyl-β-D-glucosaminide for NAG. Upon enzymatic hydrolysis, these substrates released 4-methylumbelliferone (MUB), a fluorescent product. Fluorescence in the aliquots was measured using a microplate reader (Synergy HT, Bio-Tek Instruments, Winooski, VT, USA) with 365 nm excitation and 450 nm emission filters. Fresh waste samples were oven-dried at 105 °C for ~24 hours to determine the moisture content. The pH and electrical conductivity of the waste materials were measured at a 1:10 (w:v) waste-to-water ratio via a pH meter (DMP-2 mV, Thermo Orion, USA). To determine the available N content in the waste materials, the samples were extracted with 0.01 M K₂SO₄ solution at a 1:20 (w:v) ratio and analyzed for NO₃⁻ and NH4+ via a colorimetric method (Keeney & Nelson, 1982; Mulvaney, 1996). The samples were extracted with 0.01 M K₂SO₄ solution at a 1:20 (w:v) ratio to determine the extractable C and N concentrations using a TOC-VCSN analyzer (Shimadzu, Kyoto, Japan). The extractable C concentration represents dissolved organic C (DOC), and the difference between the extractable N and available N (total inorganic N: TIN = NO₃⁻ + NH4+) represents dissolved organic N (DON) (Wu et al., 2020). The total C (TC) and total N (TN) contents of the waste materials were determined via a CHN elemental analyzer (Vario MICRO cube, Elementar Analysensysteme GmbH, Germany). The C/N ratio was determined as the mass ratio of TC to TN.

2.5. Statistical Analyses

All data analysis was conducted via SPSS v.26 software. Before statistical analysis, all data were tested for normality of distribution using the Shapiro-Wilk test and for homogeneity of variance using Levene's test. Enzyme activity and physicochemical property data were log- or square-root-transformed as necessary to account for unequal variances and then back-transformed after statistical analyses for presentation purposes. The effects of biochar on enzyme activities and physicochemical properties of green waste and yard waste were tested separately for each sampling time (after 1, 10, 50, and 100 days of incubation) via one-way ANOVA. The statistical significance of differences in all treatment effects was set at α = 0.05 in all analyses, and the means were separated among the treatments via Tukey's test.

3. Results and Discussion

3.1. Biochar Effects on Physicochemical Properties

The TC in GW and GWB decreased over time (Figure 1a), reflecting microbial decomposition of C and subsequent C loss. GWB showed a more rapid decline, suggesting biochar may enhance microbial activity or alter decomposition dynamics by increasing nutrient availability or serving as a microbial habitat (Ebrahimi et al., 2024; Li et al., 2018). TN increased in both treatments (Figure 1b), likely due to microbial N immobilization or the formation of stable N compounds (Kauser et al., 2020; Tian et al., 2023). GWB consistently had a higher C/N ratio than GW (Figure 1c), possibly because biochar slowed decomposition or retained N during early stages. As decomposition progressed, the C/N ratios of both treatments gradually converged (Alarefee et al., 2023). In contrast, TC remained relatively stable in YW and YWB (Figure 1a), indicating slower decomposition, possibly due to more resistant C or lower microbial activity. TN increased slightly (Figure 1b), and C/N ratios remained stable (Figure 1c), suggesting consistent nutrient dynamics. These patterns suggest that biochar had a lesser influence on yard waste than on green waste. Yard waste’s high fixed C content (Fetene et al., 2018) and a larger proportion of slowly hydrolysable C in leaves and branches (Komilis, 2006) contribute to its slower decomposition. Green waste, including grass clippings, decomposes more rapidly due to a lower proportion of recalcitrant C.
DOC levels were significantly higher (p < 0.05) in GWB than GW on day 1 (Figure 2a), indicating that biochar stimulated early soluble C release. DOC peaked at day 10 in both treatments, followed by a steady decline due to microbial consumption and stabilization of labile organic matter (Godlewska et al., 2017; Wang et al., 2019). DON also peaked on day 10 (Figure 2b), reflecting active microbial decomposition and N release (Belias et al., 2007; El Barnossi et al., 2019). Despite early differences, DON levels in GW and GWB were similar by day 100, suggesting biochar’s limited long-term effect on total DON dynamics. In YW and YWB, DOC significantly increased (p < 0.05) on days 50 and 100 (Figure 2c), and DON peaked on day 50 (Figure 2d). These increases likely result from the gradual decomposition of more complex organic matter and the release of soluble C and N (Błońska et al., 2023). Biochar did not significantly affect the trends in DOC or DON in yard waste, indicating a limited role in influencing the release of C and N from more recalcitrant materials. GW and GWB showed stable pH values throughout the incubation period (Table 1), indicating consistent alkalinity. Electrical conductivity (EC) increased gradually due to the release of mineral salts during decomposition (Chen et al., 2024; Sharma et al., 2021). In GW, NH₄⁺ levels declined significantly (p < 0.05), consistent with ammonification followed by volatilization or nitrification (Manga et al., 2021; Zhu et al., 2023). In GWB, NH₄⁺ initially increased and then declined slightly, suggesting that biochar helped retain NH₄⁺. NO₃⁻ concentrations in both treatments increased significantly by day 100, indicating nitrification. The TIN was consistently higher in GWB, indicating that biochar enhanced overall N retention. In YW and YWB, pH remained stable with minimal fluctuations (Table 2), while EC steadily increased, reflecting ongoing mineralization. NH₄⁺ levels declined, and NO₃⁻ levels increased progressively, a typical pattern of aerobic decomposition in organic matter (Zhang et al., 2002). These changes reflect the conversion of organic N to NH₄⁺ and its subsequent oxidation to NO₃⁻. The observed trends align with the composting literature, showing a reduction in NH₄⁺ and an increase in NO₃⁻ over time (Cardoso et al., 2022). Biochar had little impact on these patterns in yard waste, possibly due to the more stable nature of its organic matter.

3.2. Biochar Effects on Enzyme Activities

In GW, BG activity declined significantly over time (Figure 3a), dropping by 42.9% on day 10, 80.4% on day 50, and 84.1% on day 100 relative to day 1. This suggests reduced cellulose availability and microbial activity as decomposition progressed (Daunoras et al., 2024; Xu et al., 2024). GWB showed a more gradual decline, with significant reductions (p < 0.05) only after day 10. In YW, BG activity was relatively stable, with a significant decrease observed only on day 50 (Figure 3b), indicating slower decomposition and more resilient enzyme dynamics. In YWB, a significant reduction occurred only on day 100.
For NAG, GW showed a significant decline by days 50 and 100 (Figure 3c), reflecting the diminishing availability of N-containing substrates over time (Sun et al., 2023). GWB peaked on day 10 but declined significantly thereafter, suggesting that biochar may temporarily stimulate enzyme activity before decomposition advances (Hardy et al., 2019; Zaid et al., 2024). YW displayed consistently low NAG activity (Figure 3d), while YWB showed minimal activity on day 10 and a peak on day 50. These trends emphasize the influence of substrate quality and biochar on enzyme activity and nitrogen cycling during decomposition.

3.3. Biochar Effects on Greenhouse Gas Emissions and Global Warming Potential

Compared with YW, GW consistently emitted more CO₂ throughout the 100-day incubation (Figure 4a), likely due to its higher content of easily degradable compounds such as cellulose (25.3%) and hemicellulose (46.3%) (Zhang & Sun, 2014), as well as its higher nitrogen content. In contrast, yard waste contained more lignin (Komilis and Ham (2003), which is more resistant to microbial decomposition. As a result, GW emitted over three times more CO₂ than YW on day 1 and continued to emit substantially more by day 100. Adding biochar significantly reduced CO₂ emissions in both waste types, suggesting a stabilizing effect on organic matter (Bekchanova et al., 2024; Kalu et al., 2024). GW also produced notable CH₄ emissions, peaking at day 30 (Figure 4b). Interestingly, CH₄ emissions were even higher in GWB, suggesting that biochar may stimulate methanogenic activity in GW (Gao et al., 2022). In contrast, both YW and YWB showed negative cumulative CH₄ emissions (Figure 4b), indicating net CH₄ uptake driven by methanotrophic activity. Similarly, Li et al. (2021) reported a net CH₄ uptake (i.e., negative CH₄ emissions) in soils amended with biochar. The N₂O emissions were substantially higher in GWB than in GW (Figure 4c), possibly due to biochar inhibiting N₂O-reducing microbes and increasing nitrate and ammonium availabilities for N₂O production through nitrification and denitrification (Cayuela et al., 2014; Escuer-Gatius et al., 2020; Li et al., 2024). Conversely, biochar addition reduced N₂O emissions in YWB compared to YW (Figure 4c), emphasizing that biochar’s effects vary with the waste type. As a result of elevated CH₄ and N₂O emissions, GWB exhibited the highest global warming potential (GWP: 125.3 g CO₂-eq kg⁻¹) (Figure 4d). In contrast, YW and YWB showed significantly lower (p < 0.05) GWPs (29.7 and 23.6 g CO₂-eq kg⁻¹, respectively) as compared to GWB, with no significant difference between YW and YWB. These findings underscore that biochar’s impact on GHG emissions and GWP is highly dependent on the type of waste material.

3.4. Factors Affecting GHG Emissions from Green Waste Under Biochar Application

On Day 100, Pearson correlation analysis revealed key relationships between GHG emissions and several variables (Table 3). CO₂ emissions were positively correlated with TC (r = 0.73, p < 0.05) and TN (r = 0.76, p < 0.05), but negatively correlated with NH₄⁺ (r = -0.83, p < 0.01) and TIN (r = -0.73, p < 0.05). Cumulative CO₂ emissions were lower in GWB than in GW (Figure 4a), suggesting biochar moderated emissions by stabilizing organic matter and slowing decomposition (Hassan et al., 2024; Spokas et al., 2009). Wu et al. (2020) similarly observed that increased TIN availability reduced CO₂ emissions. Biochar's retention of NH₄⁺ and NO₃⁻ may suppress microbial activity responsible for CO₂ production by altering N availability and microbial communities (Liang et al., 2019; Zhai et al., 2023; Zhang et al., 2021)
CH₄ emissions were negatively correlated with TC (r = -0.79, p < 0.01) and TN (r = -0.78, p < 0.01), but positively correlated with NO₃⁻ (r = 0.77, p < 0.01) and TIN (r = 0.89, p < 0.01). CH₄ emissions were higher in GWB, possibly due to elevated TIN (1083.1 mg N g⁻¹), which may have promoted methanogenesis. The positive correlation with NO₃⁻ suggests that N availability supported methanogenic microbial activity. Biochar's ability to store nutrients may indirectly facilitate CH₄ production (Pant & Rai, 2021; Xiao et al., 2021). While some studies report CH₄ suppression by biochar through enhanced methanotrophy (Huang et al., 2023; Nandipamu et al., 2024), high organic N in green waste may override this effect.
N₂O emissions were negatively correlated with TC (r = -0.69, p < 0.05) and TN (r = -0.72, p < 0.05), but positively correlated with NH₄⁺ (r = 0.705, p < 0.05), NO₃⁻ (r = 0.69, p < 0.05), and TIN (r = 0.88, p < 0.01). GWB emitted significantly more N₂O than GW (Figure 4c), likely due to the increased availability of NH₄⁺ and NO₃⁻ (Table 1), which are key substrates for nitrification and denitrification (Guo et al., 2023). These findings align with previous studies, which have shown that biochar can increase N₂O emissions under high N availability and labile C conditions (Edwards et al., 2018; Wang et al., 2023).
GWP was positively correlated with NO₃⁻ (r = 0.71, p < 0.05) and TIN (r = 0.86, p < 0.01), and negatively with TN (r = -0.65, p < 0.05). It also showed a negative correlation with CO₂ emissions (r = -0.66, p < 0.01) and strong positive correlations with CH₄ (r = 0.90, p < 0.01) and N₂O (r = 0.98, p < 0.01), highlighting the dominant role of these gases in determining the total GWP. Although biochar application led to a reduction in CO₂ emissions—likely due to its stabilization of labile carbon and suppression of microbial respiration—the concurrent increases in CH₄ and N₂O emissions resulted in an overall rise in GWP. This is primarily due to the much higher global warming potentials of CH₄ and N₂O, which are 25 and 298 times greater than that of CO₂, respectively (Chen et al., 2019). These findings suggest that the benefits of CO₂ mitigation through biochar are offset by enhanced emissions of more potent greenhouse gases. Therefore, while biochar has potential as a carbon management strategy, its use in organic waste systems may pose a trade-off, and strategies to mitigate CH₄ and N₂O emissions must be considered to optimize its environmental performance.

3.5. Factors Affecting GHG Emissions from Yard Waste Under Biochar Application

Carbon dioxide emissions were positively correlated with NAG activity (r = 0.68, p < 0.05) (Table 3), indicating that higher CO₂ emissions are associated with increased microbial N cycling. NAG is involved in chitin degradation, contributing to N mineralization and stimulating microbial respiration, which releases CO₂ (Uwituze et al., 2022; Wang et al., 2025). Methane emissions were positively correlated with NO₃⁻ (r = 0.74, p < 0.05) and TIN (r = 0.71, p < 0.05) and negatively with DON (r = −0.65, p < 0.05). These results suggest that greater N availability promotes methanogenesis as microbial activity increases with available N (Bodelier & Laanbroek, 2004; Liu et al., 2024b). In contrast, higher DON may suppress CH₄ production by promoting denitrifiers or limiting labile C for methanogens (Chen et al., 2009; Euler et al., 2020; Riyaz & Khan, 2024).
Nitrous oxide emissions were negatively correlated with EC (r = -0.77, p < 0.05) and TIN (r = -0.74, p < 0.05). The increased EC from biochar amendment may inhibit microbial processes involved in N₂O production, thereby reducing emissions (Liu et al., 2024a; Yuan et al., 2019). Enhancing biochar’s electrochemical properties, such as specific capacitance and electrical conductivity, has been shown to mitigate N₂O emissions (Liu et al., 2024a). The negative correlation with TIN suggests that biochar may alter N cycling by shifting denitrification pathways or reducing excess N availability (Liao et al., 2021). On the other hand, N₂O emissions were positively correlated with BG activity (r = 0.68, p < 0.05), indicating that biochar’s influence on C degradation also affects N transformations. Yan et al. (2024) reported similar findings linking N₂O emissions with BG activity. Reduced BG activity due to biochar likely limited cellulose decomposition and glucose release, decreasing energy availability for microbial growth. Since denitrification relies on both NO₃⁻ and labile C (Yang et al., 2019), lower C availability restricts this process, thereby reducing N₂O emissions (Gao et al., 2019; Liu et al., 2018).
The GWP was negatively correlated with pH (r = -0.66, p < 0.05). Biochar’s alkalinity can buffer acidity, influencing microbial community structure and enzymatic activity related to GHG emissions (Criscuoli et al., 2024; Duan et al., 2024). These results support previous findings that increasing soil pH through biochar can suppress GHG production by altering N cycling pathways (Saharan et al., 2024; Wang et al., 2023). GWP also showed a strong positive correlation with CO₂ emissions (r = 0.99, p < 0.01), underscoring the dominant role of CO₂ in contributing to global warming potential.

4. Conclusions

Biochar has dual effects on GHG emissions and waste decomposition in urban forestry waste. Biochar addition reduced CO₂ emissions in green waste and yard waste, highlighting biochar’s potential for C stabilization. The increased CH₄ and N₂O emissions in GWB underscore the complex interplay between biochar and changes in microbial communities and substrate availability. The YW and YWB exhibited negative cumulative CH₄ emissions, and YWB exhibited lower N2O emissions than YW. The GWP was highest in GWB at 125.3 g CO₂-eq kg⁻¹, indicating that biochar application exacerbated the overall GHG impact of green waste. Our findings highlight the influence of the chemical composition of waste materials on the effectiveness of biochar in mitigating GHG emissions. Green waste, rich in labile organic C, exhibited faster decomposition and greater microbial activity, amplifying the effects of biochar on CH₄ and N₂O production. In contrast, yard waste, characterized by its high concentrations of recalcitrant compounds, was more affected by biochar application, which reduced overall GHG emissions. Our findings emphasize the need for a tailored approach to biochar application, as well as the importance of considering the specific properties of the waste material. Further research should explore strategies, such as combining biochar with complementary amendments or fine-tuning application rates, to maximize biochar’s potential for sustainable waste management.

Acknowledgments

This work was funded by an NSERC (Natural Science and Engineering Research Council of Canada) Alliance grant (grant No. ALLRP 577155-2022).

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. The effects of biochar on (a) total carbon, (b) total nitrogen, and (c) the C/N ratio in green waste and yard waste. Error bars denote means ± standard errors (n=5). Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar.
Figure 1. The effects of biochar on (a) total carbon, (b) total nitrogen, and (c) the C/N ratio in green waste and yard waste. Error bars denote means ± standard errors (n=5). Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar.
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Figure 2. The effects of biochar amendments on dissolved organic carbon in (a) green waste and (b) yard waste, and on dissolved organic nitrogen in (c) green waste and (d) yard waste. Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar. Error bars denote means ± standard errors (n=5). Different lowercase letters indicate significant differences among green waste/yard waste treatment incubation days, whereas uppercase letters indicate significant differences among incubation days for the GWB/YWB treatment (P < 0.05). The asterisk (*) represents a significant difference between GW and GWB/YW and YWB for each incubation day (P < 0.05).
Figure 2. The effects of biochar amendments on dissolved organic carbon in (a) green waste and (b) yard waste, and on dissolved organic nitrogen in (c) green waste and (d) yard waste. Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar. Error bars denote means ± standard errors (n=5). Different lowercase letters indicate significant differences among green waste/yard waste treatment incubation days, whereas uppercase letters indicate significant differences among incubation days for the GWB/YWB treatment (P < 0.05). The asterisk (*) represents a significant difference between GW and GWB/YW and YWB for each incubation day (P < 0.05).
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Figure 3. The effects of biochar amendments on β-1,4-glucosidase activities in (a) green waste and (b) yard waste, and on β-1,4-N-acetyl glucosaminidase activities in (c) green waste and (d) yard waste. Error bars denote means ± standard errors (n=5). Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar. Different lowercase letters indicate significant differences among YW/GW treatment incubation days, whereas uppercase letters indicate significant differences among incubation days for the GWB/YWB treatment (P < 0.05). The asterisk (*) represents a significant difference between GW and GWB/YW and YWB for each incubation day (P < 0.05).
Figure 3. The effects of biochar amendments on β-1,4-glucosidase activities in (a) green waste and (b) yard waste, and on β-1,4-N-acetyl glucosaminidase activities in (c) green waste and (d) yard waste. Error bars denote means ± standard errors (n=5). Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar. Different lowercase letters indicate significant differences among YW/GW treatment incubation days, whereas uppercase letters indicate significant differences among incubation days for the GWB/YWB treatment (P < 0.05). The asterisk (*) represents a significant difference between GW and GWB/YW and YWB for each incubation day (P < 0.05).
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Figure 4. Effects of biochar amendments on cumulative emissions of (a) CO₂, (b) CH₄, and (c) N₂O, and (d) global warming potential (GWP) from green waste and yard waste. The inset in Figure (c) shows the effect of biochar on cumulative N₂O emissions from yard waste. Error bars denote means ± standard errors (n=5). Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar. Different lowercase letters in Figure (d) indicate significant differences among treatments (P < 0.05). .
Figure 4. Effects of biochar amendments on cumulative emissions of (a) CO₂, (b) CH₄, and (c) N₂O, and (d) global warming potential (GWP) from green waste and yard waste. The inset in Figure (c) shows the effect of biochar on cumulative N₂O emissions from yard waste. Error bars denote means ± standard errors (n=5). Treatment codes: GW = green waste without biochar; GWB = green waste + biochar; YW = yard waste without biochar; YWB = yard waste + biochar. Different lowercase letters in Figure (d) indicate significant differences among treatments (P < 0.05). .
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Table 1. Physicochemical properties of green waste (GW) and biochar-treated green waste (GWB) at four incubation intervals.
Table 1. Physicochemical properties of green waste (GW) and biochar-treated green waste (GWB) at four incubation intervals.
Property Treatment Incubation day
Day 1 Day 10 Day 50 Day 100
pH GW 7.69 (0.1)a 7.8 (0.1)a 7.3 (0.0)b 7.73 (0.0)a
GWB 7.65 (0.1)ab 7.94 (0.1)a 7.47 (0.0)b 7.79 (0.0)ab
EC
(dS m-1)		 GW 2.38 (0.1)c 3.36 (0.1)bc 3.86 (0.1)ab 4.04 (0.2)a
GWB 2.24 (0.1)c 3.6 (0.1)b 4.08 (0.1)a 3.94 (0.1)ab
NH4+
(mg kg-1)		 GW 552.13 (43)a* 534.95 (28)a* 100.75 (2.2)b 93.46 (3.8)b*
GWB 732.53 (35)a* 835.58 (53)a* 205.34 (4.2)b 263.47 (8.9)b*
NO₃⁻
(mg kg-1)		 GW 237.83 (15)c 298.91 (6.8)b 282.74 (11)b 696.52 (16)a
GWB 231.86 (18)c 235.67 (15)c 372.63 (5.7)b 819.62 (38)a
TIN
(mg kg-1)		 GW 789.96 (43)a* 833.86 (26)a* 383.49 (13)b* 789.98 (15)a*
GWB 964.39 (47)a* 1071.25 (49)a* 577.97 (8.9)b* 1083.09 (33)a*
The values are means with standard errors in parentheses (n=5). Different lowercase letters indicate significant differences among incubation days within each treatment (P < 0.05). The asterisk (*) represents a significant difference between GW and GWB for each incubation day (P < 0.05). Abbreviations: EC= electrical conductivity, NH4+ = ammonium, NO₃⁻ = nitrate, and TIN= total inorganic N = NH4+ + NO₃⁻.
Table 2. Physicochemical properties of yard waste (YW) and biochar-treated yard waste (YWB) at the four incubation intervals.
Table 2. Physicochemical properties of yard waste (YW) and biochar-treated yard waste (YWB) at the four incubation intervals.
Property Treatment Incubation days
Day 1 Day 10 Day 50 Day 100
pH YW 7.62 (0.0)a 7.55 (0.0)a 7.38 (0.1)a 7.5 (0.0)a
YWB 7.69 (0.0)a 7.73 (0.0)a 7.43 (0.0)b 7.61 (0.1)ab
EC
(dS m-1)		 YW 0.33 (0.0)b* 0.36 (0.0)ab 0.38 (0.0)a 0.38 (0.0)a
YWB 0.41 (0.0)b* 0.41 (0.0)b 0.42 (0.0)ab 0.44 (0.0)a
NH4+
(mg kg-1)		 YW 160.09 (2.3)a 104.23 (6.1)b 40.69 (1.4)c 20.78 (0.2)d*
YWB 168.15 (6.9)a 131.33 (4.4)b 71.75 (6.5)c 38.73 (2.5)d*
NO₃⁻
(mg kg-1)		 YW 24.65 (2.5)d 38.86 (4.3)c 102.82 (4.7)b 143.01 (6.7)a
YWB 31.95 (1)c 42.81 (4.3)c 114.1 (6.5)b 183.43 (15.9)a
TIN
(mg kg-1)		 YW 184.74 (4.1)a 143.08 (9.2)b 143.51 (6)b* 163.79 (6.8)ab*
YWB 200.1 (6.5)ab 174.14 (7)b 185.86 (4.7)ab* 222.16 (14.7)a*
The values are means with standard errors in parentheses (n=5). Different lowercase letters indicate significant differences among incubation days within each treatment (P < 0.05). The asterisk (*) represents a significant difference between YW and YWB for each incubation day (P < 0.05). Abbreviations: EC= electrical conductivity, NH4+ = ammonium, NO₃⁻ = nitrate, and TIN= total inorganic N = NH4+ + NO₃⁻.
Table 3. Pearson correlation coefficient and significance among greenhouse gas emissions and chemical properties in green waste and yard waste.
Table 3. Pearson correlation coefficient and significance among greenhouse gas emissions and chemical properties in green waste and yard waste.
Green waste
TC TN NH4+ NO₃⁻ TIN CO2 CH4 N2O
CO2 0.73* 0.76* -0.83** -0.46 -0.73*
CH4 -0.79** -0.78** 0.65 0.77** 0.89** -0.69*
N2O -0.69* -0.72* 0.705* 0.69* 0.88** -0.80** 0.91**
GWP -0.63 -0.65* 0.61 0.71* 0.86** -0.66* 0.90** 0.98**
Yard waste
pH EC NO₃⁻ TIN DON BG NG CO2 CH4 N2O
CO2 -0.63 -0.35 -0.22 -0.35 0.28 0.56 0.68*
CH4 -0.20 0.56 0.74* 0.71* -0.65* -0.57 -0.30 -0.05
N2O -0.41 -0.77* -0.63 -0.74* 0.53 0.68* 0.26 0.69* -0.33
GWP -0.66* -0.29 -0.13 -0.26 0.20 0.48 0.63 0.99** 0.10 0.65
TC = total carbon; TN = total nitrogen; NH4+ = ammonium; NO₃⁻ = nitrate; TIN= total inorganic nitrogen; EC = electrical conductivity; DON = dissolved organic nitrogen; BG: β-1,4-glucosidase; NAG: β-1,4-N-acetyl glucosaminidase; GWP = global warming potential. ⁎ =P < 0.05; ⁎⁎ =P < 0.01.
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