磁铁矿与接种物特性在加速甲烷生产动力学中的相互作用

IF 5.9 3区 工程技术 Q1 AGRONOMY
Ethar M. Al-Essa, Ricardo Bello-Mendoza, David G. Wareham
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引用次数: 0

摘要

磁铁矿纳米颗粒可通过种间直接电子传递促进甲烷生成。然而,人们对接种物和颗粒特性对磁铁矿刺激甲烷生成的综合影响知之甚少。在此,我们在批次厌氧消化实验中研究了接种物类型、颗粒大小和颗粒浓度对磁铁矿加速甲烷生成能力的影响。新鲜和脱气的中温消化污泥被用作接种物,分别代表处于指数或静止生长阶段和内生衰变阶段的甲烷生成群落。使用了两种不同浓度(2 毫摩尔和 7 毫摩尔)的磁铁矿颗粒,粒径范围分别为小(50-150 纳米)、中(168-490 纳米)和大(800 纳米-4.5 微米)。在脱气污泥中,磁铁矿对甲烷产生率的影响较弱,且取决于颗粒大小和浓度。与不含磁铁矿的对照组相比,只有 2 毫摩尔和 7 毫摩尔的中等粒度磁铁矿能使甲烷生产率显著提高 12%。与对照组相比,只有 2 毫摩尔的中小型磁铁矿才会使滞后期减少 17%。相反,与对照组相比,在新鲜污泥中添加磁铁矿可显著提高甲烷生产率,平均提高 32%,同时将滞后期减少 15%-40%,这与磁铁矿的大小和浓度无关。甲烷生产的刺激作用取决于磁铁矿和接种物的特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Interaction between magnetite and inoculum characteristics in accelerating methane production kinetics

Interaction between magnetite and inoculum characteristics in accelerating methane production kinetics

Magnetite nanoparticles can boost methane production via direct interspecies electron transfer. However, the combined effect of inoculum and particle characteristics on magnetite's methanogenesis stimulation is poorly understood. Here, the influence of inoculum type, particle size, and particle concentration on the ability of magnetite to accelerate methanogenesis was studied in batch anaerobic digestion experiments. Fresh and degassed mesophilic digester sludge was used as inoculum, representing methanogenic communities in the exponential or stationary growth and endogenous decay phases, respectively. Three magnetite particle size ranges, small (50–150 nm), medium (168–490 nm), and large (800 nm–4.5 μm), at two different concentrations (2 and 7 mM) were used. With degassed sludge, the effect of magnetite on the methane production rate was weak and depended on the particle size and concentration. Only magnetite of medium size at both 2 and 7 mM significantly increased the methane production rate by 12% compared to the control with no magnetite. The lag phase was reduced by 17% compared to the control, only with 2 mM of both small and medium size magnetite. Conversely, adding magnetite into fresh sludge significantly increased the methane production rate by an average of 32% while simultaneously decreasing the lag phase by 15%–40%, as compared to the control, independently of the magnetite's size and concentration. The stimulation of methane production depends on magnetite and inoculum characteristics.

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来源期刊
Global Change Biology Bioenergy
Global Change Biology Bioenergy AGRONOMY-ENERGY & FUELS
CiteScore
10.30
自引率
7.10%
发文量
96
审稿时长
1.5 months
期刊介绍: GCB Bioenergy is an international journal publishing original research papers, review articles and commentaries that promote understanding of the interface between biological and environmental sciences and the production of fuels directly from plants, algae and waste. The scope of the journal extends to areas outside of biology to policy forum, socioeconomic analyses, technoeconomic analyses and systems analysis. Papers do not need a global change component for consideration for publication, it is viewed as implicit that most bioenergy will be beneficial in avoiding at least a part of the fossil fuel energy that would otherwise be used. Key areas covered by the journal: Bioenergy feedstock and bio-oil production: energy crops and algae their management,, genomics, genetic improvements, planting, harvesting, storage, transportation, integrated logistics, production modeling, composition and its modification, pests, diseases and weeds of feedstocks. Manuscripts concerning alternative energy based on biological mimicry are also encouraged (e.g. artificial photosynthesis). Biological Residues/Co-products: from agricultural production, forestry and plantations (stover, sugar, bio-plastics, etc.), algae processing industries, and municipal sources (MSW). Bioenergy and the Environment: ecosystem services, carbon mitigation, land use change, life cycle assessment, energy and greenhouse gas balances, water use, water quality, assessment of sustainability, and biodiversity issues. Bioenergy Socioeconomics: examining the economic viability or social acceptability of crops, crops systems and their processing, including genetically modified organisms [GMOs], health impacts of bioenergy systems. Bioenergy Policy: legislative developments affecting biofuels and bioenergy. Bioenergy Systems Analysis: examining biological developments in a whole systems context.
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