José Pedro Ramião scite author profile

Our study aimed to analyze the effects of chronic nutrient loading on the capacity of headwater streams to retain phosphorus and ammonium pulses of different duration. For this purpose, we selected nine headwater streams located across a gradient of increasing agricultural land use and eutrophication. In each stream, we performed sequential plateau additions with increasing nutrient concentrations in summer 2015 and instantaneous slug additions in summer 2016 under similar hydrological conditions. We modelled kinetic uptake curves from the slug additions via the Tracer Additions for Spiraling Curve Characterization method and calculated ambient uptake parameters. Ambient uptake rates generally increased (1.4-20.8 lg m-2 s-1 for NH 4-N and 0.3-10.3 lg m-2 s-1 for SRP, respectively), while ambient uptake velocities decreased from oligotrophic to polytrophic streams (1.8-14.0 mm min-1 for NH 4-N and 1.6-9.9 mm min-1 for SRP, respectively). However, correlations between ambient uptake parameters and background concentrations were weak. Concentration-dependent uptake rates followed either a linear or a Michaelis-Menten saturation model, regardless of the degree of nutrient loading. Uptake rate curves showed counterclockwise hysteresis in oligotrophic streams and clockwise hysteresis in streams of higher trophic states, indicating a reduced significance of hyporheic uptake with increasing nutrient loading. Comparisons of slug and plateau additions revealed that oligotrophic streams were most efficient in uptake during short nutrient pulses, while eutrophic streams profited from longer pulse duration. The results indicate that nutrient uptake is increasingly transport-controlled in polluted streams where increased biofilm thickness and clogging of sediments restrict nutrient transport to reactive sites.

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Riparian land use and stream habitat regulate water quality

Ramião

Cássio

Pascoal

2020

Limnologica

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The European Water Framework Directive facing current challenges: recommendations for a more efficient biological assessment of inland surface waters

et al. 2018

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High quality water is vital for human life, and ensuring its availability is a basic requirement and a major societal aim. The Water Framework Directive (WFD; 2000/60/EC) is a key piece of legislation for the protection and sustainable use of water in the European Union. In this work we briefly review the WFD directive and the current status of European inland surface waters. Additionally, we summarize major challenges and threats for the biological assessment of inland surface waters under climate change effects and invasion by alien species, and highlight the emerging tools and approaches that might help improve biological assessments, including molecular indices based on environmental DNA (eDNA), to new data from the Earth Observation programmes, and data-sharing platforms. Finally, we present recommendations to improve monitoring systems and assessments in the context of the WFD. Developments in this field may increase the likelihood of assuring high quality water for society.

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Hydropower Contribution to the Renewable Energy Transition Under Climate Change

Ramião

Carvalho-Santos

Pinto

et al. 2022

Water Resour Manage

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