Influences of stream ecosystem respiration on stream network denitrification: Results from a simulation modeling experiment

IF 1.7 4区 环境科学与生态学 Q3 ECOLOGY Freshwater Science Pub Date : 2022-05-31 DOI:10.1086/720720
S. Carlson, G. Poole
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Abstract

Denitrification can remove substantial amounts of NO3− from stream networks, but controls on the magnitude and distribution of network-scale denitrification remain poorly understood. Prior research using an empirical relationship between stream [NO3−] and denitrification efficiency to construct a stream network denitrification model suggested that smaller, lower order streams contributed disproportionately to whole-network NO3− removal when NO3− loads were low. We expanded this model by incorporating an empirical relationship between whole-stream aerobic respiration rate and denitrification efficiency, which decreased the simulated sensitivity of NO3− removal to [NO3−] and displayed additional heterogeneity in NO3− removal associated with variation in respiration rates. We explored the sensitivity of the expanded model across a set of scenarios representing variation in stream respiration and NO3−-loading rates. Stream respiration rates used in these scenarios were determined from a theoretical relationship between aerobic respiration rate and stream temperature and were calculated for model scenarios representing warm (high respiration rate) and cool (low respiration rate) conditions. Our results indicated that reach- and network-scale denitrification is apt to be strongly influenced by respiration rates when NO3− supplies are high relative to removal rates. Therefore, the distribution of respiration rates across stream networks likely plays a more important role in determining spatial patterns of denitrification rates than previously described, highlighting a mechanism by which larger (higher order) streams may contribute substantially to whole-network denitrification.
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河流生态系统呼吸对河网反硝化作用的影响——模拟模拟实验结果
反硝化作用可以从河流网络中去除大量的NO3−,但对网络规模反硝化作用的大小和分布的控制仍然知之甚少。先前的研究利用流[NO3−]与反硝化效率之间的经验关系构建了一个流网络反硝化模型,结果表明,当NO3−负荷较低时,较小的低阶流对整个网络NO3−去除的贡献不成比例。我们通过纳入全流程有氧呼吸速率和反硝化效率之间的经验关系扩展了该模型,这降低了模拟NO3 -去除对[NO3 -]的敏感性,并显示了与呼吸速率变化相关的NO3 -去除的额外异质性。我们探索了扩展模型在一系列代表河流呼吸和NO3−负荷率变化的情景中的敏感性。这些情景中使用的河流呼吸速率是根据有氧呼吸速率和河流温度之间的理论关系确定的,并根据代表温暖(高呼吸速率)和凉爽(低呼吸速率)条件的模型情景进行计算。我们的研究结果表明,当NO3−供应相对于去除率较高时,到达和网络尺度的反硝化容易受到呼吸速率的强烈影响。因此,在确定反硝化速率的空间格局方面,跨河流网络的呼吸速率分布可能比之前描述的更重要,突出了更大(高阶)的河流可能对整个网络反硝化做出重大贡献的机制。
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来源期刊
Freshwater Science
Freshwater Science ECOLOGY-MARINE & FRESHWATER BIOLOGY
CiteScore
4.10
自引率
0.00%
发文量
49
审稿时长
6-12 weeks
期刊介绍: Freshwater Science (FWS) publishes articles that advance understanding and environmental stewardship of all types of inland aquatic ecosystems (lakes, rivers, streams, reservoirs, subterranean, and estuaries) and ecosystems at the interface between aquatic and terrestrial habitats (wetlands, riparian areas, and floodplains). The journal regularly features papers on a wide range of topics, including physical, chemical, and biological properties of lentic and lotic habitats; ecosystem processes; structure and dynamics of populations, communities, and ecosystems; ecology, systematics, and genetics of freshwater organisms, from bacteria to vertebrates; linkages between freshwater and other ecosystems and between freshwater ecology and other aquatic sciences; bioassessment, conservation, and restoration; environmental management; and new or novel methods for basic or applied research.
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