Physical and stoichiometric controls on stream respiration in a headwater stream

IF 3.9 2区地球科学 Q1 ECOLOGY Biogeosciences Pub Date : 2023-08-11 DOI:10.5194/bg-20-3353-2023

J. Dorley, J. Singley, T. Covino, K. Singha, M. Gooseff, David Van Horn, R. González‐Pinzón

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Abstract

Abstract. Many studies in ecohydrology focusing on hydrologic transport argue that longer residence times across a stream ecosystem should consistently result in higher biological uptake of carbon, nutrients, and oxygen. This consideration does not incorporate the potential for biologically mediated reactions to be limited by stoichiometric imbalances. Based on the relevance and co-dependences between hydrologic exchange, stoichiometry, and biological uptake and acknowledging the limited amount of field studies available to determine their net effects on the retention and export of resources, we quantified how microbial respiration is controlled by the interactions between and the supply of essential nutrients (C, N, and P) in a headwater stream in Colorado, USA. For this, we conducted two rounds of nutrient experiments, each consisting of four sets of continuous injections of Cl− as a conservative tracer, resazurin as a proxy for aerobic respiration, and one of the following nutrient treatments: (a) N, (b) N+C, (c) N+P, or (d) C+N+P. Nutrient treatments were considered to be known system modifications that alter metabolism, and statistical tests helped identify the relationships between reach-scale hydrologic transport and respiration metrics. We found that as discharge changed significantly between rounds and across stoichiometric treatments, (a) transient storage mainly occurred in pools lateral to the main channel and was proportional to discharge, and (b) microbial respiration remained similar between rounds and across stoichiometric treatments. Our results contradict the notion that hydrologic transport alone is a dominant control on biogeochemical processing and suggest that complex interactions between hydrology, resource supply, and biological community function are responsible for driving in-stream respiration.

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源水流呼吸的物理和化学计量学控制

摘要许多关注水文运输的生态水文学研究认为，在河流生态系统中停留时间越长，生物对碳、营养物质和氧气的吸收就越高。这种考虑没有考虑到生物介导的反应可能受到化学计量不平衡的限制。基于水文交换、化学计量学和生物吸收之间的相关性和相互依赖性，并认识到可用于确定其对资源保留和输出的净效应的实地研究数量有限，我们量化了美国科罗拉多州源头流中必需营养素(C、N和P)之间的相互作用和供应如何控制微生物呼吸。为此，我们进行了两轮营养实验，每轮包括四组连续注射Cl -作为保守示踪剂，resazurin作为有氧呼吸的代理，以及以下营养处理之一:(a) N， (b) N+C，(C) N+P或(d) C+N+P。营养处理被认为是改变代谢的已知系统修改，统计测试有助于确定河段水文运输和呼吸指标之间的关系。我们发现，由于各轮之间和不同化学计量处理之间的流量发生了显著变化，(a)瞬时储存主要发生在主河道侧面的池中，并与流量成正比，(b)微生物呼吸在各轮之间和不同化学计量处理之间保持相似。我们的研究结果反驳了水文运输是生物地球化学过程的主要控制因素的观点，并表明水文、资源供应和生物群落功能之间的复杂相互作用是驱动河流呼吸的原因。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Biogeosciences 环境科学-地球科学综合

CiteScore

8.60

自引率

8.20%

发文量

258

审稿时长

4.2 months

期刊介绍： Biogeosciences (BG) is an international scientific journal dedicated to the publication and discussion of research articles, short communications and review papers on all aspects of the interactions between the biological, chemical and physical processes in terrestrial or extraterrestrial life with the geosphere, hydrosphere and atmosphere. The objective of the journal is to cut across the boundaries of established sciences and achieve an interdisciplinary view of these interactions. Experimental, conceptual and modelling approaches are welcome.