Biogeochemical processes controlling aquatic quality during drying and rewetting events in a Mediterranean non-perennial river reach

Desiccation and re-flooding processes play a key role on hydrological features of non-perennial rivers. This study addresses the effects of these processes on the aquatic quality and unravels underlying biogeochemical processes of an intermittent river reach in southern Greece containing a spring-fe...

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Bibliographic Details
Published in:The Science of the total environment 2017-01, Vol.575, p.378-389
Main Authors: Skoulikidis, Nikolaos Th, Vardakas, Leonidas, Amaxidis, Yorgos, Michalopoulos, Panagiotis
Format: Article
Language:English
Subjects:
Biogeochemical processes
Carbonate precipitation
Desiccation
Epsomite dissolution
Non-perennial rivers
Nutrients
Photosynthesis
Re-flooding
Respiration
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Summary:Desiccation and re-flooding processes play a key role on hydrological features of non-perennial rivers. This study addresses the effects of these processes on the aquatic quality and unravels underlying biogeochemical processes of an intermittent river reach in southern Greece containing a spring-fed pool. Combined spatio-temporal sampling for physicochemical parameters, major ions and nutrients and high frequency automatic monitoring during a hydrological year (2010–2011) indicate that during the dry period, solute variation was controlled by “concentration” processes (i.e. evaporative concentration and high dissolved ion input from base flow sources). Metabolic and “concentration” processes appear intensified during desiccation and water temperature rise. Photosynthesis induced carbonate precipitation, while respiration increased with gradual desiccation, but did not cause carbonate dissolution. In certain cases, photosynthesis and respiration may have occurred simultaneously as a result of differing microhabitat metabolism within the same water body. However, during the entire desiccation cycle, autotrophic production exceeded respiration resulting in relatively high oxygen concentrations, even during the night. With increasing desiccation, a rise in nutrient assimilation occurred as well as ammonification and/or desorption of ammonium from sediments, with simultaneous loss of nitrate. During initial floods, flushing of carbonate phases was not significant. In contrast, initial flood events were characterized by the dissolution of very soluble salts, i.e. epsomite-type (MgSO4∗7H2O) and gypsum (CaSO4∗2H2O). Regarding sediment transport and nutrients, a 1000-times increase of suspended sediments was observed during re-flooding, while the nutrient quality degraded, particularly for N-species. Results of the current research may serve to better understand the links of hydrological and biogeochemical processes in non-perennial rivers and streams towards their efficient management and conservation. [Display omitted] •Photosynthesis was the dominant metabolic process during desiccation.•Photosynthesis caused carbonate precipitation.•The “tipping point” for carbonate precipitation and respiration increase was 22°C.•In certain cases, photosynthesis and respiration may have occurred simultaneously.•Initial floods were characterized by the dissolution of an epsomite-type of salt.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2016.10.015