Abstract
Fine particulate organic matter (FPOM) accumulated in streambeds is a major component of organic matter budgets in headwater streams and greatly affects productivity and metabolism of stream communities. The spatiotemporal distribution of benthic FPOM in the stream, as well as its quantity and quality, depend on inputs from different source types. These can be natural such as soils, streambanks and riparian vegetation, or anthropogenic such as effluents from wastewater treatment plants (WWTP). In addition, stream flow is a key driver of FPOM dynamics, which influences the balance between its transport and accumulation in the streambed. Yet, the link between FPOM dynamics and its effects on stream metabolism is still largely unknown. The aim of this study was to investigate the influence of stream channel hydromorphology on water transport and streambed accumulation of fine particulate matter (FPM) (mineral and organic fractions), FPOM (organic fraction) and its quality (characterized by %OM, %C, %N and the C:N molar ratio). In addition, we quantified the metabolic activity associated with FPM at the habitat scale, and its potential contribution to whole-reach ecosystem respiration using the resazurin-resorufin bioreactive tracer as a proxy for aerobic respiration. We also characterized water transport and metabolic activity with combined additions of hydrological and bioreactive tracers at the reach scale. The study was conducted in the Cànoves stream (Catalonia, NE Spain) downstream of a WWTP that contains three reaches that were hydromorphologically modified using bioengineering techniques. Slower local velocities at the habitat scale increased accumulation of FPM, but did not influence the spatial variability of its quality. Instead, FPM quality declined further downstream from the WWTP. Accumulation of FPM did not increase metabolic activity, but higher %OM of FPM and lower C:N ratios favored the microbial metabolic activity efficiency (normalized by the gram of FPM). Reach-scale metabolic activity was higher in reaches with higher water exchange rate and longer relative travel times, highlighting hydromorphology as an important driver of microbial metabolic activity at the reach-scale. This demonstrates that the interplay of hydrologic exchange and residence time in streambed sediments associated with the microbial metabolic activity of FPOM can ultimately influence reach-scale metabolic activity.
Highlights
The hyporheic zone (HZ) is a region of the streambed sediments that exchanges water, solutes and fine particles with the overlying water column in streams (Boano et al, 2014)
Based on the differences in hydromorphological characteristics among the 3 experimental reaches, we predicted that (i) quantity of fine particulate matter (FPM) accumulated in streambed sediments would increase with higher water residence time within the reach, (ii) microbial metabolic activity associated with FPM would be influenced by the quantity and quality of FPM, and (iii) the influence of FPM microbial activity on reach-scale ecosystem respiration would vary among the 3 experimental reaches due to differences in water transport and the interaction between surface stream water and streambed sediments, and the influence of FPM would be higher in the reach with higher water residence time
This study aimed to investigate the influence of stream hydromorphological characteristics on water transport and the accumulation of FPM in the streambed
Summary
The hyporheic zone (HZ) is a region of the streambed sediments that exchanges water, solutes and fine particles with the overlying water column in streams (Boano et al, 2014) In headwater streams, these vertical hydrologic interactions promote the biogeochemical processing of organic matter and nutrients in the HZ, which can substantially contribute to overall surface water quality and whole-reach ecosystem metabolism (Grimm and Fisher, 1984; Brunke and Gonser, 1997; Boulton et al, 2010; Tank et al, 2010; Boano et al, 2014). FPM in the streambed, especially the OM fraction, has a high potential to contribute to in-stream heterotrophic activity (i.e., ecosystem respiration), influencing the balance between gross primary production and respiration at the whole-reach scale
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