Aging of colloidal contaminants and pathogens in the soil environment: Implications for nanoplastic and COVID‐19 risk mitigation

Wang, Liuwei; Hu, Zhongtao; Yin, Hanbing; Bradford, Scott A.; Luo, Jian; Hou, Deyi

doi:10.1111/sum.12849

Cited by 15 publications

(3 citation statements)

References 196 publications

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“…The temporal changes in metal(loid) immobilization performances add complexity when assessing the long‐term effectiveness of immobilization (Hou et al., 2021; Wang, Hu, et al., 2023; Zhao et al., 2020). On the one hand, we observed that the amended soil underwent a decline in pH over time, which promoted the immobilization of As and Sb but was not favourable for the long‐term immobilization of Cd.…”

Section: Resultsmentioning

confidence: 99%

Biochar amendment gradually immobilized soil As and Sb over 2 years

Hu,

Wang,

Mašek

et al. 2024

Soil Use and Management

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Biochar is a promising candidate for the sustainable remediation of soils, especially those contaminated with cationic heavy metals, because of its liming effect and tunable surface functionality. Despite its potential, prior studies have highlighted biochar's limitations in immobilizing soil oxyanions, such as arsenic (As) and antimony (Sb), particularly in the short term. This shotcoming is primarily attributed to an increase of soil pH following biochar amendment, and factors like competition with phosphate. In this study, biochar amendments were applied to three soils with varying levels of oxyanions including As and Sb, and cations including cadmium (Cd) and lead (Pb). These treatments generally resulted in short‐term failure of oxyanion immobilization. However, a noteworthy phenomenon unfolded over a 2‐year period, where biochars gradually transitioned from initial mobilization or poor immobilization to eventual successful immobilization of oxyanions (up to 87.0% for As and 100% for Sb). Temporal changes in Cd and Pb differed from As and Sb, exhibiting no improvement in immobilization rates over time. Potential mechanisms driving this process were investigated, suggesting a decline in soil pH, progressive oxidation of soil carbon fractions, and direct adsorption effects as contributing factors. This study sheds light on the temporal shift in biochar's immobilization performance, highlighting a gradual increase in the efficacy in oxyanion immobilization. The findings offer valuable insights into the dynamic nature of biochar's remediation capabilities.

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Section: Resultsmentioning

confidence: 99%

Biochar amendment gradually immobilized soil As and Sb over 2 years

Hu,

Wang,

Mašek

et al. 2024

Soil Use and Management

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“…Both positive and negative priming could occur for biochar amended soils. The former one refers to the process where carbon mineralization is stimulated, while the latter one refers to the process where the mineralization rate is lowered (thus leading to suppressed CO 2 emissions) (Maestrini et al 2015;Wang et al 2022c). Positive priming is induced via the addition of fresh labile carbon which can stimulate the activities of soil microorganisms, thus accelerating the carbon mineralization process (Fang et al 2019;Keith et al 2011;Zimmerman and Ouyang 2019).…”

Section: Co 2 Emissionsmentioning

confidence: 99%

Role of biochar toward carbon neutrality

et al. 2023

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Carbon neutrality by the mid-twenty-first century is a grand challenge requiring technological innovations. Biochar, a traditional soil amendment which has been used for fertility improvement and contaminant remediation, has revealed new vitality in this context. In this review we highlight the huge potential of biochar application in different fields to mitigate as high as 2.56 × 109 t CO2e total greenhouse gas (GHG) emissions per year, accounting for 5.0% of the global GHG emissions. Soil applications of biochar as either a controlled-release fertilizer or an immobilization agent offer improved soil health while simultaneously suppressing the emissions of CH4 and N2O. Non-soil applications of biochar also contribute to carbon neutrality in unique ways. Firstly, biochar application as a ruminant feed decreases CH4 emissions via physical sorption and enhanced activities of methanotrophs. Secondly, biochar can be used as a green catalyst for biorefinery. Besides, biochar as an additive to Portland cement and low impact development (LID) infrastructure lowers the carbon footprint and builds resilience to climate change. Furthermore, biochar can be used as novel batteries and supercapacitors for energy storage purposes. Finally, the high CO2 adsorption capacity makes it possible for biochar being used as a sorbent for carbon capture, utilization, and storage (CCUS). We advocate that future research should further explore the effectiveness of biochar systems for climate change mitigation in large scale applications, and assess the economic and social viability of local biochar systems to combat climate change. Graphical Abstract

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“…Weathering of plastics is a major process responsible for the breakdown of larger plastics into micro‐ and nanoplastics (Duan et al, 2021). As‐formed MPs break into even smaller particles with progressive weathering, generating nanoplastics (NPs) whose size fall within the nanometre range (Lau et al, 2020; Wang, Hu, et al, 2022). There is some controversy about the definition of nanoplastics (NPs) (Wang, Wu, et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Nanoplastic–plant interaction and implications for soil health

Zhou

Wang

Gao

et al. 2022

Soil Use and Management

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Nanoplastics (NPs) are accumulating in the soil environment at a rapid rate, which may cause serious consequences for ecosystems and human health. However, environmental behaviour and toxicity of NPs in the soil-plant system remain poorly understood. This review summarizes current studies on NP-plant interactions to unravel uptake mechanisms and phytotoxicity of NPs. NPs could be taken up by plant roots and transported upwards through the xylem to all organs of the plant, even to the edible parts such as the grain, thereby threatening human health.The interaction of NPs with plants affects plant transport of water and nutrients.Besides, it induces significant oxidative stress leading to inhibition of physiological and biochemical activities such as photosynthesis, and thus adversely affects plant growth and development. In addition, the co-transport of NPs with other soil pollutants may induce the combined toxic effects. This study also discussed the potential mechanism of NP-plant interactions based on previous experience with engineered nanomaterials. Finally, a comprehensive assessment of the key challenges in each area was presented, and future perspectives are offered.

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Aging of colloidal contaminants and pathogens in the soil environment: Implications for nanoplastic and COVID‐19 risk mitigation

Cited by 15 publications

References 196 publications

Biochar amendment gradually immobilized soil As and Sb over 2 years

Biochar amendment gradually immobilized soil As and Sb over 2 years

Role of biochar toward carbon neutrality

Nanoplastic–plant interaction and implications for soil health

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