4.1 Article

Nutrient processing domains: Spatial and temporal patterns of material retention in running waters

期刊

FRESHWATER SCIENCE
卷 41, 期 2, 页码 195-214

出版社

UNIV CHICAGO PRESS
DOI: 10.1086/719991

关键词

nutrients; domains; uptake; load; source; sink; processing

资金

  1. Upper Clark Fork River National Science Foundation (NSF) Long Term Research in Environmental Biology Program [DEB 1655197]
  2. Montana NSF Established Program to Stimulate Competitive Research [OIA-1757351]
  3. United States Department of Agriculture National Institute of Food and Agriculture, Hatch Project [1015745]
  4. Natural Resources Damage Program [2.42]

向作者/读者索取更多资源

This study introduces the concept of nutrient processing domains (NPDs), which integrates routing and local processes to explain the longitudinal patterns of lotic biogeochemical function in rivers.
Reaches are a fundamental unit for lotic biogeochemical characterization, yet a functional classification of nutrient processing at the reach scale is currently lacking. Here, we introduce nutrient processing domains (NPDs) to integrate routing (nutrient delivery) and local (benthic uptake and transformation) processes that dictate longitudinal patterns of lotic biogeochemical function. An NPD is defined as a realm in functional space occupied by reaches that share similar biogeochemical character. Occupation of a given NPD reflects characteristic net material balance (NMB), exchange potential, and availability, associated with changes in solute load, the extent of hydrologic gain or loss, and changes in concentration from the head to the base of a reach, respectively. Using a mass-balance approach, we represent NMB as the effective solute flux (F-eff, M L-2 T-1, where M = mass, L = length, and T = time), designating reaches as sources (+F-eff) or sinks (-F-eff). Discharge change along a reach is measured as the change in hydraulic load (Delta H-L, L/T), reflecting the potential for import and export to influence solute loads. Finally, the ratio of downstream-to-upstream concentration (C-dwn:up) represents the net effect that processes have on nutrient availability. Using a 20-y historical record for N and P in the Upper Clark Fork River, Montana, USA, we employed this approach to 3 consecutive reaches covering nearly 90 km of channel length to address spatial and temporal dynamics in NPD behavior in a nutrient-rich, productive river system. For total N and total P, reaches typically occupied compiler or enhancer NPDs, displaying load increases without or with concomitant increases in concentration, respectively. In contrast, reaches were NO3- consumers, acting as sinks for NO3-N during summer and autumn. NO3- load reductions were typically accompanied by striking declines in concentration, despite positive exchange potential (i.e., +Delta H-L). Measured F-eff magnitudes for NO3- (-1.2 to -60.0 mg N m(-2) d(-1)) were similar to those reported in the literature associated with autotrophic N demand. Individual reaches occupied contrasting NPDs for NO3-N and soluble reactive P by simultaneously serving as a sink for one and a source for the other. Hence, alternating reaches acted as enhancers or consumers, sequentially along the river, reflecting geologic and biological influences with implications for whole river behavior. The NPD approach combines routing influences of material exchange and local biological stream processes to provide a biogeochemical taxonomy for stream reaches with application to theory and practice.

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