6 results on '"Lei, Pei"'
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2. Understanding the risks of mercury sulfide nanoparticles in the environment: Formation, presence, and environmental behaviors.
- Author
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Lei, Pei, Zou, Nan, Liu, Yujiao, Cai, Weiping, Wu, Mengjie, Tang, Wenli, and Zhong, Huan
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MERCURY sulfide , *MERCURY , *NANOPARTICLES , *BIOGEOCHEMICAL cycles , *ORGANIC compounds , *METHYLATION , *SILVER sulfide - Abstract
Mercury (Hg) could be microbially methylated to the bioaccumulative neurotoxin methylmercury (MeHg), raising health concerns. Understanding the methylation of various Hg species is thus critical in predicting the MeHg risk. Among the known Hg species, mercury sulfide (HgS) is the largest Hg reservoir in the lithosphere and has long been considered to be highly inert. However, with advances in the analytical methods of nanoparticles, HgS nanoparticles (HgS NPs) have recently been detected in various environmental matrices or organisms. Furthermore, pioneering laboratory studies have reported the high bioavailability of HgS NPs. The formation, presence, and transformation (e.g., methylation) of HgS NPs are intricately related to several environmental factors, especially dissolved organic matter (DOM). The complexity of the behavior of HgS NPs and the heterogeneity of DOM prevent us from comprehensively understanding and predicting the risk of HgS NPs. To reveal the role of HgS NPs in Hg biogeochemical cycling, research needs should focus on the following aspects: the formation pathways, the presence, and the environmental behaviors of HgS NPs impacted by the dominant influential factor of DOM. We thus summarized the latest progress in these aspects and proposed future research priorities, e.g., developing the detection techniques of HgS NPs and probing HgS NPs in various matrices, further exploring the interactions between DOM and HgS NPs. Besides, as most of the previous studies were conducted in laboratories, our current knowledge should be further refreshed through field observations, which would help to gain better insights into predicting the Hg risks in natural environment. [Display omitted] [ABSTRACT FROM AUTHOR]
- Published
- 2022
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3. Mechanisms of algal biomass input enhanced microbial Hg methylation in lake sediments.
- Author
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Lei, Pei, Nunes, Luís M., Liu, Yu-Rong, Zhong, Huan, and Pan, Ke
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LAKE sediments , *X-ray absorption near edge structure , *ALGAL blooms , *METHYLATION - Abstract
Abstract Eutrophication is a major environmental concern in lake systems, impacting the ecological risks of contaminants and drinking water safety. It has long been believed that eutrophication and thus algal blooms would reduce methylmercury (MeHg) levels in water, as well as MeHg bioaccumulation and trophic transfer (e.g., by growth dilution). In this study, however, we demonstrated that algae settlement and decomposition after algal blooms increased MeHg levels in sediments (54–514% higher), as evidenced by the results from sediments in 10 major lakes in China. These could in turn raise concerns about enhanced trophic transfer of MeHg and deterioration of water quality after algal blooms, especially considering that 9 out of the 10 examined lakes also serve as drinking water sources. The enhanced microbial MeHg production in sediments could be explained by the algal organic matter (AOM)-enhanced abundances of microbial methylators as well as the input of algae-inhabited microbes into sediments, but not Hg speciation in sediments: (1) Several AOM components (e.g., aromatic proteins and soluble microbial by product-like material with generally low molecular weights), rather than the bulk AOM, played key roles in enhancing the abundances of microbial methylators. The copies of Archaea- hgcA methylation genes were 51–397% higher in algae-added sediments; thus, MeHg production was also higher. (2) Input of algal biomass-inhabited microbial methylators contributed to 2–21% of total Archaea- hgcA in the 10 lake sediments with added algal biomass. (3) However, AOM-induced changes in Hg speciation, with implications on Hg availability to microbial methylators, played a minor role in enhancing microbial Hg methylation in sediments as seen in X-ray absorption near edge structure (XANES) data. Our results suggest the need to better understand the biogeochemistry and risks of contaminants in eutrophic lakes, especially during the period of algae settlement and decomposition following algal blooms. Graphical abstract Unlabelled Image Highlights • Algae settlement and decomposition enhanced net MeHg production in lake sediments. • Low molecular weight algal organic matter (AOM) increased the abundances of methylators. • Input of algae-inhabited microbes into sediments enhanced microbial MeHg production. • AOM-induced changes in Hg speciation played a minor role in Hg methylation. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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4. Litterfall-derived organic matter enhances mercury methylation in mangrove sediments of South China.
- Author
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Duan, Dandan, Lei, Pei, Lan, Wenlu, Li, Tianshen, Zhang, Hao, Zhong, Huan, and Pan, Ke
- Abstract
Mercury (Hg) contamination in mangrove ecosystems has received increasing attention in recent years. Although many studies have investigated methylmercury (MeHg) contamination and its relationship to a number of environmental factors in mangrove sediments, the production of MeHg in this carbon-rich ecosystem has not been fully evaluated. In this study, we measured the total mercury (THg) and MeHg concentrations in the sediments collected from seven mangrove forests in China. In addition, we examined the origin and quality of sedimentary organic matter (OM), trying to evaluate their influence on the MeHg accumulation in mangrove sediments. We found that litterfall played an important role in regulating THg and MeHg contents in mangrove sediments. THg and MeHg concentrations in the mangrove sediments were positively correlated to OM content and the labile fraction of the OM. Multiple evidence (stable carbon isotopes, monosaccharide compositions, and biogenic silica) suggested that OM in mangrove sediments was dominated by input from litterfall. THg and MeHg concentrations were elevated at the sediments with higher input of mangrove OM. We observed that addition of mangrove litter stimulated the production of MeHg under anaerobic conditions. Overall, our results suggested that litterfall acted as a source of inorganic Hg, labile carbon, and low-molecular-weight OM which greatly favor the Hg methylation. Our study provides new insights into the MeHg production in mangrove sediments. Unlabelled Image • Litterfall played an important role in regulating sedimentary THg and MeHg. • THg and MeHg contents were positively correlated to the labile fraction of OM. • THg and MeHg contents were elevated at the sediments with higher input of mangrove OM. • Mangrove litter stimulated MeHg production in sediments under anaerobic conditions. [ABSTRACT FROM AUTHOR]
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- 2021
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5. Effects and mechanisms of organic matter regulating the methylmercury dynamics in mangrove sediments.
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Liu, Jingli, Li, Yanping, Duan, Dandan, Peng, Guogan, Li, Ping, Lei, Pei, Zhong, Huan, Tsui, Martin Tsz-Ki, and Pan, Ke
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MANGROVE plants , *METHYLMERCURY , *SEDIMENTS , *ORGANIC compounds , *SULFATE-reducing bacteria , *CARBON cycle , *DIAGENESIS - Abstract
Mangrove ecosystems serve as an important carbon sink but also could be a hotspot that produces neurotoxic methylmercury (MeHg). Although many studies have focused on mercury (Hg) contamination in this carbon-rich ecosystem, our understanding of the effects and mechanisms of the organic matter (OM) regulation of MeHg production in mangrove sediments is still limited. Here, we examined the effects of Hg contamination and OM enrichment on MeHg production in anoxic mangrove sediments and identified the major microbial guilds attending this process. The mangrove sediments possessed a high potential for producing MeHg, but this was counterbalanced by its rapid degradation. Sulfate-reducing bacteria (SRB) such as Desulfobacterales , Desulfovibrionales , and Syntrophobacterales were the major methylators. OM diagenesis significantly changed the biogeochemical conditions, accelerating MeHg degradation in the sediments. The enhanced MeHg degradation could be attributed to the abundant sulfide produced during OM decomposition, which could potentially inhibit the Hg methylation by immobilization of inorganic Hg, abiotically degrade MeHg, and favor the non- mer -mediated degradation of MeHg by SRB. Our study provides both geochemical and microbial clues that can partly explain the low MeHg levels widely observed in mangrove sediments. [Display omitted] • Geochemistry and microbial analysis explain the low MeHg in mangrove sediments. • Hg methylation counterbalanced with MeHg degradation in mangrove sediments. • OM enrichment facilitated MeHg degradation in the sediments. • SRB played critical roles in both Hg methylation and MeHg demethylation. [ABSTRACT FROM AUTHOR]
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- 2022
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6. Neutral monosaccharides and their relationship to metal contamination in mangrove sediments.
- Author
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Duan, Dandan, Lan, Wenlu, Chen, Fengyuan, Lei, Pei, Zhang, Hao, Ma, Jie, Wei, Yang, and Pan, Ke
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TRACE metals , *TRACE elements , *MANGROVE forests , *SEDIMENTS , *MONOSACCHARIDES , *MASS spectrometry , *ORGANIC compounds - Abstract
Mangrove sediments act as an important natural sink and a secondary source for trace metals. The main objective of this study was to investigate metal contamination and its relationship to mangrove-derived carbohydrates in mangrove sediments. Sixteen metals (Be, V, Cr, Co, Ni, Cu, Zn, Ga, As, Sr, Cd, Sn, Sb, Ba, Tl, and Pb)were analyzed in the surface sediments from four sites at different latitudes on the southeast coastline of China. The sedimentary organic matter was characterized by Rock-Eval pyrolysis, and the neutral sugars were examined by gas chromatograph mass spectrometry. Our results from the enrichment factors indicated that the mangrove sediments were no enriched by Ga, Sr, and Ba, minor enriched by Be, V, Cr, Co, Ni, Cu, Zn, As, Sn, Sb, Tl, and Pb, and moderate enriched by Cd. Litterfall was a major source of organic matter in the mangrove sediments, and the neutral sugars were mainly derived from this litterfall. Significant correlations were detected between the total organic carbon, pyrolytic parameters, neutral sugars, and enrichment factors of V, Cr, Co, Ni, Zn, and Cd, suggesting the input of neutral carbohydrates played an important role in enhancing the metal accumulation in the mangrove sediments. The mangrove litterfall itself was a major source of metals for the sediments, and the mangrove-derived organic matter enhanced the sediment's metal accumulation. • Metal concentrations in mangrove sediments decreased from low to high latitudes. • Litterfall was the main source of organic matter in the mangrove sediments. • V, Cr, Co, Ni, Zn, Cd were strongly correlated with mangrove-derived carbohydrates. • Litterfall was both a metal source and metal storage pool in the sediments. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
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