Stephanie M. Juice, Melannie D. Hartman, Adam C. von Haden, William J. Parton, Edward R. Brzostek
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引用次数: 0
Abstract
Plant strategies to acquire nutrients from limited environments help shape ecosystem carbon (C) and nitrogen (N) cycling and response to environmental change. The effects of plant strategies on ecosystem dynamics are largely uncharacterized in bioenergy agroecosystems, where the impacts could determine bioenergy's ability to meet its sustainability goals of storing C and reducing N loss. We used FUN-BioCROP (Fixation and Uptake of Nitrogen-Bioenergy Carbon, Rhizosphere, Organisms and Protection), a plant–microbe interaction model of coupled plant nutrient uptake and soil organic matter decomposition, to simulate the effects of nutrient acquisition strategies on soil microbial activity and ecosystem nutrient cycling in bioenergy feedstocks miscanthus (Miscanthus × giganteus) and sorghum (Sorghum bicolor (L.) Moench). We examined the model's ability to reproduce the relative effects of belowground nutrient uptake on microbial activity using a reanalysis of empirical data showing that miscanthus root exudation provoked a larger soil microbial response than sorghum. From baseline model simulations, we found that the ability of miscanthus to retranslocate N resulted in higher N uptake at a lower C cost than the sorghum/soybean rotation and that soil C and N pools increased under perennial (miscanthus) and decreased under annual (sorghum/soybean) cultivation. The model also predicted that greater root exudation increased soil C accumulation, highlighting the role of roots in forming stable soil C. Overall, the baseline model was unable to reproduce field observations of miscanthus root exudation stimulating microbial activity more than sorghum. To improve the model, we updated the soil microbial parameters in miscanthus to have faster decomposition, a higher C/N ratio, and greater carbon use efficiency. These changes improved the simulated soil microbial response to miscanthus root exudation, supporting the hypothesis that miscanthus soils foster a microbial community that is more responsive to root exudation than that of sorghum.
植物从有限环境中获取养分的策略有助于形成生态系统碳(C)和氮(N)循环和对环境变化的响应。在生物能源农业生态系统中,植物策略对生态系统动态的影响在很大程度上是未知的,这些影响可能决定生物能源实现其储存C和减少N损失的可持续目标的能力。利用植物养分吸收与土壤有机质分解耦合的植物-微生物互作模型fun_biocrop (fixed and Uptake of Nitrogen-Bioenergy Carbon, Rhizosphere, Organisms and Protection),模拟了不同养分获取策略对生物能源原料芒草(miscanthus × giganteus)和高粱(sorghum bicolor (L.))土壤微生物活性和生态系统养分循环的影响。Moench)。通过对经验数据的重新分析,我们检验了该模型再现地下养分吸收对微生物活动的相对影响的能力,结果表明,芒草根渗出液比高粱引起了更大的土壤微生物反应。从基线模型模拟中,我们发现与高粱/大豆轮作相比,芒草转运N的能力以更低的C成本导致更高的N吸收,并且多年生(芒草)种植下土壤C和N库增加,而一年生(高粱/大豆)种植下土壤C和N库减少。该模型还预测,根系分泌物的增加增加了土壤C的积累,突出了根系在形成稳定土壤C方面的作用。总体而言,基线模型无法再现芒草根系分泌物对微生物活动的刺激大于高粱的现场观测结果。为了改进模型,我们更新了芒草土壤微生物参数,使其分解速度更快,C/N比更高,碳利用效率更高。这些变化改善了模拟土壤微生物对芒草根系分泌物的响应,支持了芒草土壤培养的微生物群落比高粱对根系分泌物更敏感的假设。
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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