Your search keyword '"Robinson, Christopher T."' showing total 294 results

251. Severely burned wood from wildfires has low functional potential in streams.

Author

Vaz, Pedro Gonçalves, Merten, Eric C., Robinson, Christopher T., and Pinto, Paulo

Subjects

*FIRE management, *STREAM restoration, *RESTORATION ecology, *FORESTS & forestry, *STREAM function

Abstract

More frequent and more severe forest fires mean more severely burned wood in streams. Instream wood provides habitat complexity, alters geomorphology, retains organic and inorganic material, promotes hyporheic flow and acts as substrate for biofilm and invertebrates. However, little is known about instream wood functions in fire‐prone biomes and how they combine with wood burning levels to guide postfire management efforts.Over 3 years, we tracked instream wood following forest fires in central Portugal. We examined for the first time the influence of burning level, season and a large suite of driving factors on the likelihood of four different functions having primary ecological consequences—retention of organic matter, serving as substrate for aquatic biota, being key pieces forming wood jams and deflecting flow including pool habitat formation.One of the main ecological functions of wood in rivers is to provide substrate for vegetation, periphyton, biofilm and oviposition. Our results show that this can be negatively affected when the wood is severely burned.Except for jam formation, the probability of each stream wood function changed markedly with season and the probability of non‐function was nearly twice as high in the Euro‐Mediterranean dry season than in the wet season.More anchored and decayed wood increased the probability of all functions, whereas the effect of submergence depended on the function. Challenging the 'size paradigm' that larger sized pieces provide more function, our data suggest that the effect of size is function‐specific.Synthesis and applications. We show how postfire stream restoration success can be maximized by selecting the most appropriate wood and taking advantage of attribute‐function relationships. We urge managers to refrain from removing wood or to selectively remove the most severely carbonized only, allowing the persistence of great potential to provide substrate for stream biota. The non‐attraction of severely burned wood as substrate can be compensated for by other wood with attributes enhancing this function, such as wood deeper within the bankfull area, and with large diameters. These results will help to inform successful management, as is increasingly asked from restoration ecology. [ABSTRACT FROM AUTHOR]

Published

2021

252. Riparian hunting spiders do not rely on aquatic subsidies from intermittent alpine streams.

Author

Siebers, Andre R., Paillex, Amael, and Robinson, Christopher T.

Abstract

Drying in alpine streams might decrease aquatic-terrestrial trophic linkages by reducing terrestrial predation on aquatic prey. We tested this hypothesis by investigating whether a common riparian predator (hunting spiders) in alpine environments assimilated a lower proportion of aquatic prey with increasing stream intermittency. We used high temporal-resolution data from electrical resistance sensors to map patterns of naturally-occurring flow intermittency across 30 headwater streams of Val Roseg, a glacierized catchment in the Swiss Alps. We collected riparian hunting spiders, as well as potential terrestrial and aquatic macroinvertebrate prey, from streams and their associated riparian zones across two seasons (Alpine spring and summer). We estimated aquatic contributions to spider diets (pA) using (i) a gradient approach with aquatic invertebrate and spider carbon stable isotope ratio values (δ13C), and (ii) Bayesian carbon and nitrogen (δ15N) isotope mixing models. Spider pA from the gradient method were not statistically different from zero in spring (0.08 ± 0.10) and low in summer (0.16 ± 0.04). Mixing models also estimated low dependence on aquatic prey in both seasons, although with potentially higher contributions in summer. Spider diet did not vary with increasing flow intermittency in either season. Our results suggested that alpine hunting spiders obtain most of their carbon from terrestrial prey. The slight increase in spider pA during summer may correlate with peak emergence periods for aquatic insects, indicating opportunistic feeding by this riparian predator. [ABSTRACT FROM AUTHOR]

Published

2021

253. Exploring and Quantifying River Thermal Response to Heatwaves.

Author

Piccolroaz, Sebastiano, Toffolon, Marco, Robinson, Christopher T., and Siviglia, Annunziato

Subjects

WATER temperature, ECOLOGY, STREAMFLOW, RUNOFF, WATER power

Abstract

Most of the existing literature on river water temperature focuseds on river thermal sensitivity to long-term trends of climate variables, whereas how river water temperature responds to extreme weather events, such as heatwaves, still requires in-depth analysis. Research in this direction is particularly relevant in that heatwaves are expected to increase in intensity, frequency, and duration in the coming decades, with likely consequences on river thermal regimes and ecology. In this study we analyzed the long-term temperature and streamflow series of 19 Swiss rivers with different hydrological regime (regulated, low-land, and snow-fed), and characterized how concurrent changes in air temperature and streamflow concurred to affect their thermal dynamics. We focused on quantifying the thermal response to the three most significant heatwave events that occurred in Central Europe since 1950 (July–August 2003, July 2006, and July 2015). We found that the thermal response of the analyzed rivers contrasted strongly depending on the river hydrological regime, confirming the behavior observed under typical weather conditions. Low-land rivers were extremely sensitive to heatwaves. In sharp contrast, high-altitude snow-fed rivers and regulated rivers receiving cold water from higher altitude hydropower reservoirs or diversions showed a damped thermal response. The results presented in this study suggest that water resource managers should be aware of the multiple consequences of heatwave events on river water temperature and incorporate expected thermal responses in adaptive management policy. In this respect, additional efforts and dedicated studies are required to deepen our knowledge on how extreme heatwave events can affect river ecosystems. [ABSTRACT FROM AUTHOR]

Published

2018

254. Evaluation of Restoration and Flow Interactions on River Structure and Function: Channel Widening of the Thur River, Switzerland.

Author

Martín, Eduardo J., Ryo, Masahiro, Doering, Michael, and Robinson, Christopher T.

Subjects

RIVER channels, ECOSYSTEM management, GROUNDWATER, BODIES of water, APPLIED ecology

Abstract

Removal of lateral constraints to restore rivers has become increasingly common in river resource management, but little is known how the interaction of de-channelization with flow influences ecosystem structure and function. We evaluated the ecosystem effects of river widening to improve sediment relations in the Thur River, Switzerland, 12 years after implementation. We tested if restored and non-restored reaches differed in water physico-chemistry, hyporheic function, primary production, and macroinvertebrate density and composition in relation to the flow regime. Our results showed that (i) spatio-temporal variation in sediment respiration and macroinvertebrate taxonomic richness were driven by interactions between restoration and flow; (ii) riverbed conditions including substrate size, organic matter content, and groundwater–surface water exchange changed due to restoration, but (iii) physico-chemistry, hydraulic conditions, and primary production were not altered by restoration. Importantly, our study revealed that abiotic conditions, except channel morphology, changed only marginally, whereas other ecosystem attributes responded markedly to changes in flow-restoration interactions. These results highlight integrating a more holistic ecosystem perspective in the design and monitoring of restoration projects such as river widening in resource management, preferably in relation to flow-sediment regimes and interactions with the biotic components of the ecosystem. [ABSTRACT FROM AUTHOR]

Published

2018

255. Preface and Acknowledgements

Author

Tockner, Klement and Robinson, Christopher T.

Published

2009

256. Nonlinear higher order abiotic interactions explain riverine biodiversity.

Author

Ryo, Masahiro, Harvey, Eric, Robinson, Christopher T., and Altermatt, Florian

Subjects

*ABIOTIC environment, *AQUATIC biodiversity, *RIVER ecology, *ECOSYSTEM health, *BIOGEOGRAPHY

Abstract

Abstract: Aim: Theory and experiments strongly support the importance of interactive effects of multiple factors shaping biodiversity, although their importance rarely has been investigated at biogeographically relevant scales. In particular, the importance of higher order interactions among environmental factors at such scales is largely unknown. We investigated higher order interactions of environmental factors to explain diversity patterns in a metacommunity of aquatic invertebrates at a biogeographically relevant scale and discuss the findings in an environmental management context. Location: All major drainage basins in Switzerland (Rhine, Rhone, Ticino and Inn; 41,285 km2). Methods: Riverine α‐diversity patterns at two taxonomic levels (family richness of all benthic macroinvertebrates and species richness of Ephemeroptera, Plecoptera and Trichoptera) were examined at 518 sites across the basins. We applied a novel machine learning technique to detect key three‐way interactions of explanatory variables by comparing the relative importance of 1,140 three‐way combinations for family richness and 680 three‐way combinations for species richness. Results: Relatively few but important three‐way interactions were meaningful for predicting biodiversity patterns among the numerous possible combinations. Specifically, we found that interactions among elevational gradient, prevalence of forest coverage in the upstream basin and biogeoclimatic regional classification were distinctly important. Main conclusion: Our results indicated that a high prevalence of terrestrial forest generally sustains riverine benthic macroinvertebrate diversity, but this relationship varies considerably with biogeoclimatic and elevational conditions likely due to community composition of forests and macroinvertebrates changing along climatic and geographical gradients. An adequate management of riverine ecosystems at relevant biogeographical scales requires the identification of such interactions and a context‐dependent implementation. [ABSTRACT FROM AUTHOR]

Published

2018

257. Using artificial floods for restoring river integrity

Author

Robinson, Christopher T. and Uehlinger, Urs

Published

2003

258. Effects of burn status and conditioning on colonization of wood by stream macroinvertebrates

Author

Vaz, Pedro G., Dias, Susana, Pinto, Paulo, Merten, Eric C., Robinson, Christopher T., Warren, Dana R., and Rego, Francisco C.

Published

2014

259. Evolutionary ecology, systematics, speciation, and phylogeography in benthology—preface

Author

Monaghan, Michael T., Pauls, Steffen U., Hughes, Jane M., and Robinson, Christopher T.

Published

2010

260. Spatial scaling in the phylogeography of an alpine caddisfly, Allogamus uncatus, within the central European Alps

Author

Kubow, Karen B., Robinson, Christopher T., Shama, Lisa N. S., and Jokela, Jukka

Published

2010

261. Immediate and habitat-specific responses of macroinvertebrates to sequential, experimental floods

Author

Robinson, Christopher T., Aebischer, Stefan, and Uehlinger, Urs

Published

2004

262. Nutrient enrichment influences the responses of stream macroinvertebrates to disturbance

Author

Gafner, Karin and Robinson, Christopher T.

Published

2007

263. Large-Scale Flow Experiments for Managing River Systems

Author

Konrad, Christopher P., Olden, Julian D., Lytle, David A., Melis, Theodore S., Schmidt, John C., Bray, Erin N., Freeman, Mary C., Gido, Keith B., Hemphill, Nina P., Kennard, Mark J., McMullen, Laura E., Mims, Meryl C., Pyron, Mark, Robinson, Christopher T., and Williams, John G.

Published

2011

264. Flow intermittency affects structural and functional properties of macroinvertebrate communities in alpine streams.

Author

Chanut, Pierre C. M., Drost, Annemieke, Siebers, Andre Robert, Paillex, Amael, and Robinson, Christopher T.

Subjects

*COMMUNITIES, *CLIMATE change, *BIOTIC communities, *AQUATIC biodiversity, *AQUATIC insects

Abstract

Flow regime is a major determinant of the structure and functioning of aquatic ecosystems. Under climate change, flow intermittency is becoming more prevalent in glaciated alpine catchments, but the effects of increasing dryness on aquatic biodiversity remain largely unknown.We characterised flow intermittency patterns in 30 streams of a glaciated alpine catchment over 15 months and separated these streams into four intermittency categories: perennial streams, winter‐drying streams, moderately intermittent streams with occasional drying in summer, and periodically intermittent streams with extensive dry periods throughout the year. We then examined how these drying patterns affected structural and functional properties of benthic macroinvertebrate communities, and whether these changes were primarily deterministic or stochastic.At the taxonomic level, we observed a response at the highest intermittency levels, with α diversity lower and β diversity higher in periodically intermittent streams than in other stream types. This result suggested that local biota were well adapted to intermediate intermittency levels (mostly during winter) but not to high intermittency during summer. In contrast, functional diversity indices at the α and β levels (based on trait abundances) did not differ across intermittency categories. Considering the moderate level of functional redundancy, we interpreted this as an indication that changes in taxonomic diversity may have resulted primarily from stochastic processes.Analysis of community and trait composition indicated that deterministic selection may indeed have occurred with increased intermittency, but this process was likely to be minor in comparison to stochastic extinctions. Notably, community evenness was highest in periodically intermittent streams and lowest in perennial streams, suggesting that frequent drying prevented competitive exclusion.Our results suggested that most macroinvertebrate populations are resilient to intermediate intermittency levels but are filtered at high intermittency, irrespective of their resilience capacities. However, more research is needed to clarify the specific roles of different facets of flow regimes, specifically frequency, duration, and timing of intermittency. Understanding the consequences of responses in diversity and community evenness with increasing intermittency on the functional properties of communities will allow better prediction of the future ecological status of alpine stream networks to ongoing environmental change. [ABSTRACT FROM AUTHOR]

Published

2023

265. Long-term response of diatoms in high-elevation streams influenced by rock glaciers.

Author

Peszek, Łukasz, Kawecka, Barbara, and Robinson, Christopher T.

Subjects

*FOSSIL diatoms, *ROCK glaciers, *DIATOMS, *WATERSHEDS, *ENVIRONMENTAL indicators, *SCANNING electron microscopy

Abstract

• Cirque comprises two main drainage basins differing in the physico-chemistry of surface waters. • Reduced rock glacier inputs in one basin caused basin waters to become more similar over the study period (2001–2020). • Periphyton biomass decreased twofold from Pre-2010 to Post-2010 in the catchment. • Diatom assemblages differed between basins, reflecting differences in surface water physico-chemistry. • Diatom composition shifted Post-2010, suggesting a tipping point occurred in the system in response to changes in environmental conditions. In this study, we monitored diatom assemblages at various sites along a stream-lake network draining a glaciated alpine cirque landscape (2600 m asl) in the Swiss National Park over 19 years (2001–2020). The primary goal of this study was to examine the long-term changes in diatom assemblages in the running waters at high-elevation influenced by rock glaciers, and particularly the use of diatoms as indicators of environmental change. Because streams in the catchment are interconnected with lakes, another objective was to compare diatom assemblages between lake inlets and lake outlets as well as along the chain of lakes. The Macun cirque comprises two main drainage basins with one influenced by waters from rock glaciers. Lakes are interconnected by stream segments in both basins before merging at an outflow lake. We expected changes in diatom assemblages would reflect changes in long-term physico-chemistry of surface waters between basins, between lake inlets and outlets, and along lake chains. The novelty of this work is that covers a unique heterogeneous aquatic environment in the Alps affected by climate change, an area where the temperature has increased over twofold more than other regions in the northern hemisphere. This long-term study provides the opportunity of forecasting how other alpine freshwater ecosystems globally may change in the future. We combined a classical taxonomic approach and scanning electron microscopy (SEM) along with physico-chemical data across a broad spatio-temporal scale. Diatom assemblages showed distinct spatial differences between basins, reflecting basin-wide differences in water physico-chemistry. Diatoms in both basins displayed a major temporal shift in composition between samples collected pre-2010 with those collected post-2010 that also followed temporal changes in physico-chemistry, suggesting a tipping point occurred in the system. There were subtle differences in diatom assemblages between lake inlets and outlets, most evident in the precipitation/groundwater fed north basin. Lastly, a clear lake order effect was detected in both basins with upper basin sites differing from lower basin sites at similar altitude. We conclude that diatoms were effective in documenting the environmental changes that occurred in these alpine waters, specifically reflecting the abrupt change in physico-chemistry (concurrent tipping point in diatom assemblages) and the concomitant increase in surface water homogeneity and similarity of diatom assemblages over the study period. [ABSTRACT FROM AUTHOR]

Published

2022

266. Long-lasting effects of experimental flow intermittency on alpine stream macroinvertebrates (Val Roseg, Switzerland).

Author

Drost, Annemieke M., Siebers, Andre R., Paillex, Amael, Misteli, Benjamin, Peeters, Edwin T. H. M., and Robinson, Christopher T.

Subjects

*STREAMFLOW, *INVERTEBRATES, *CHANNEL flow, *LONGEVITY, *EPHEMERAL streams

Abstract

Changing weather patterns and receding glaciers are predicted to increase flow intermittency in alpine streams. If aquatic macroinvertebrate communities largely comprise taxa adapted to perennial flows, an increase in flow intermittency substantially reduces biodiversity and affects functional processes. We conducted a before-after-control-impact field experiment to examine how macroinvertebrate communities in an alpine headwater stream responded to and recovered from a repeated experimental increase in flow intermittency. Flow in one channel was manipulated to simulate increased summer intermittency (June–September) over two consecutive years, whilst an adjacent channel served as a control. We monitored the density of benthic macroinvertebrates, periphyton and organic matter at approximately monthly intervals over three years during the snow-free period. Before manipulation, both channels had similar ecological properties. The flow manipulation reduced the overall macroinvertebrate density, and especially the proportional rheophile density, across both years. Recovery of the macroinvertebrate community following experimental flow intermittency took more than a year, and longer than our study period. This could be due to long aquatic life stages, dispersal limitation and biotic interactions. We conclude that climate-induced changes in alpine stream flow regimes can lead to a fundamental shift in macroinvertebrate assemblages through local extinctions, mostly of rheophilic species. [ABSTRACT FROM AUTHOR]

Published

2022

267. Effects of an experimental increase in flow intermittency on an alpine stream.

Author

Siebers, Andre R., Paillex, Amael, Misteli, Benjamin, and Robinson, Christopher T.

Subjects

*AQUATIC invertebrates, *GLACIAL melting, *ALPINE glaciers, *RIVERS, *ORGANIC compounds, *INVERTEBRATES, *MEASUREMENT of runoff

Abstract

Flow intermittency occurs naturally in alpine streams. However, changing rainfall patterns and glacier retreat are predicted to increase the occurrence of flow intermittency in alpine catchments, with largely unknown effects on ecosystem structure and function. We conducted a flow manipulation experiment within a headwater stream of Val Roseg, a glacierized alpine catchment, to determine the effects of increased flow intermittency on aquatic macroinvertebrates, periphyton, benthic organic matter, and trophic structure. Compared to an adjacent reference channel, an increase in flow intermittency reduced macroinvertebrate density, taxa richness, and the proportion of rheophilic taxa. Density and richness remained low in the manipulated channel after resumption of natural flow. Flow intermittency did not affect organic matter standing stocks, but increased assimilation of periphyton by aquatic macroinvertebrates. Predation on aquatic invertebrates by riparian spiders also increased. We attribute many of these patterns to the timing of drying, which likely excluded summer-growing cohorts of rheophilic, aerial dispersers. This study suggests that reductions in summer glacial melt and rainfall events might increase flow intermittency and lead to fundamental changes in diversity and function of alpine fluvial networks. [ABSTRACT FROM AUTHOR]

Published

2020

268. High stream intermittency in an alpine fluvial network: Val Roseg, Switzerland.

Author

Paillex, Amael, Siebers, Andre R., Ebi, Christian, Mesman, Jorrit, and Robinson, Christopher T.

Subjects

*GLACIERS, *ALPINE glaciers, *PRINCIPAL components analysis, *RIVERS, *LOW temperatures, *STREAMFLOW, *FLOW sensors

Abstract

More than one‐third of the world's rivers cease to flow and go dry on a periodic basis—so‐called intermittent rivers. The frequency and duration of flow intermittency in running waters are increasing due to climate change and water demands for human use. Intermittency effects on stream biodiversity and ecosystem functioning are dramatic and are expected to become increasingly prevalent in alpine landscapes in the near future. This project used modified field sensors to measure flow intermittency, temperature, and water origin (groundwater, precipitation, glacier) at high spatio‐temporal resolution throughout an alpine fluvial network (Val Roseg, Switzerland). We continuously recorded water presence in 30 tributary streams and validated sensor performance with field‐collected measures. Three different flow regimes were observed in the network, including periodically intermittent, seasonally intermittent, and permanently flowing streams. Twenty‐four streams (80% of recorded streams) dried at least once during the sampling period. Principal components analysis along with generalized additive models showed alpine streams with low average temperature and high conductivity (groundwater‐fed) were prone to permanent flow, whereas streams with higher average temperature and low conductivity (glacier‐fed) typically had intermittent flow. The field sensors proved precise for simultaneously measuring flow intermittency, temperature, and water origin at high resolution throughout the river network. Overall, this approach provides an effective way to develop eco‐hydrological models that examine the effects of flow intermittency on biodiversity and ecosystem functioning in riverine networks. [ABSTRACT FROM AUTHOR]

Published

2020

269. A conceptual framework for understanding the biogeochemistry of dry riverbeds through the lens of soil science.

Author

Arce, María Isabel, Mendoza-Lera, Clara, Almagro, María, Catalán, Núria, Romaní, Anna M., Martí, Eugènia, Gómez, Rosa, Bernal, Susana, Foulquier, Arnaud, Mutz, Michael, Marcé, Rafael, Zoppini, Annamaria, Gionchetta, Giulia, Weigelhofer, Gabriele, del Campo, Rubén, Robinson, Christopher T., Gilmer, Alan, Rulik, Martin, Obrador, Biel, and Shumilova, Oleksandra

Subjects

*SOIL science, *BIOGEOCHEMISTRY, *RIVER channels, *SOIL horizons, *EPHEMERAL streams, *SOIL crusting

Abstract

Abstract Intermittent rivers and ephemeral streams (IRES) encompass fluvial ecosystems that eventually stop flowing and run dry at some point in space and time. During the dry phase, channels of IRES consist mainly of dry riverbeds (DRBs), prevalent yet widely unexplored ecotones between dry and wet phases that can strongly influence the biogeochemistry of fluvial networks. DRBs are often overlooked because they do not strictly belong to either domain of soil or freshwater science. Due to this dual character of DRBs, we suggest that concepts and knowledge from soil science can be used to expand the understanding of IRES biogeochemistry. Based on this idea, we propose that DRBs can be conceptually understood as early stage soils exhibiting many similarities with soils through two main forces: i) time since last sediment transport event, and ii) the development status of stabilizing structures (e.g. soil crusts and/or vascular plants). Our analysis suggests that while DRBs and soils may differ in master physical attributes (e.g. soil horizons vs fluvial sedimentary facies), they become rapidly comparable in terms of microbial communities and biogeochemical processes. We further propose that drivers of DRBs biogeochemistry are similar to those of soils and, hence, concepts and methods used in soil science are transferable to DRBs research. Finally, our paper presents future research directions to advance the knowledge of DRBs and to understand their role in the biogeochemistry of intermittent fluvial networks. [ABSTRACT FROM AUTHOR]

Published

2019

270. Glacier shrinkage driving global changes in downstream systems.

Author

Milner, Alexander M., Khamis, Kieran, Battin, Tom J., Brittain, John E., Barrand, Nicholas E., Füreder, Leopold, Cauvy-Fraunié, Sophie, Gíslason, Gísli Már, Jacobsen, Dean, Hannah, David M., Hodson, Andrew J., Hood, Eran, Lencioni, Valeria, Ólafsson, Jón S., Robinson, Christopher T., Tranter, Martyn, and Brown, Lee E.

Subjects

*GLACIERS, *CLIMATE change, *RIVERINE operations, *SEDIMENTS, *WATER power

Abstract

Glaciers cover ~10% of the Earth's land surface, but they are shrinking rapidly across most parts of the world, leading to cascading impacts on downstream systems. Glaciers impart unique footprints on river flow at times when other water sources are low. Changes in river hydrology and morphology caused by climate-induced glacier loss are projected to be the greatest of any hydrological system, with major implications for riverine and near-shore marine environments. Here, we synthesize current evidence of how glacier shrinkage will alter hydrological regimes, sediment transport, and biogeochemical and contaminant fluxes from rivers to oceans. This will profoundly influence the natural environment, including many facets of biodiversity, and the ecosystem services that glacier-fed rivers provide to humans, particularly provision of water for agriculture, hydropower, and consumption. We conclude that human society must plan adaptation and mitigation measures for the full breadth of impacts in all affected regions caused by glacier shrinkage. [ABSTRACT FROM AUTHOR]

Published

2017

271. Stream degradation affects aquatic resource subsidies to riparian ground-dwelling spiders.

Author

Kowarik, Carmen, Martin-Creuzburg, Dominik, Mathers, Kate L., Weber, Christine, and Robinson, Christopher T.

Published

2023

272. Fire meets inland water via burned wood: and then what?

Author

Vaz, Pedro G., Merten, Eric C., Warren, Dana R., Durscher, Kelsie, Tapp, Megan, Robinson, Christopher T., Rego, Francisco C., and Pinto, Paulo

Subjects

*FRESHWATER habitats, *WOOD, *FOREST fires, *INVERTEBRATES, *RIPARIAN ecology, *STREAM restoration, *EUCALYPTUS

Abstract

Wood is a key structural element in aquatic ecosystems. Wood provides habitat complexity, alters geomorphology, retains organic and inorganic material, promotes hyporheic flow, and acts as substrate for biofilms and invertebrates. Fire is an important disturbance promoting wood recruitment into inland waters, but most studies have focused on streams in western North America. Less is known about fire-derived wood dynamics on other continents or in lake environments. Here, we review fire effects on the recruitment, distribution, and function of in-stream wood, with emphasis on a series of studies from the Euro-Mediterranean. The amount of large wood in these streams was low and is expected to decline in the future because of wildfire. Wildfire engendered inputs of wood with low structural complexity, probably reducing habitat heterogeneity for aquatic organisms. Fire also provided wood with greater diameter than wood recruited by other means, but its longevity may be shorter because burned wood was more decayed and less anchored in the channel than unburned wood. Wood delivery processes are important because macroinvertebrate colonization differed between fire-derived wood that fell directly into the river and wood conditioned first on the forest floor. We present a case study describing wood dynamics in a lake after a wildfire in northern Minnesota, USA. In this study, wildfire created an area of lake shoreline with disproportionately more wood than areas unaffected by wildfire. In contrast to streams, burned wood was more complex than unburned wood in the lake system. One of the explanations may be greater scouring, abrasive action by stream flows, which breaks down burned wood faster than in lakes. Given the expected increase in the probability and severity of fire around the world, information in our review can be used to help manage riparian zones of streams and lakes. [ABSTRACT FROM AUTHOR]

Published

2015

273. Analysis of the temperature dynamics of a proglacial river using time-lapse thermal imaging and energy balance modeling.

Author

Cardenas, M. Bayani, Doering, Michael, Rivas, Denny S., Galdeano, Carlos, Neilson, Bethany T., and Robinson, Christopher T.

Subjects

*GLACIAL climates, *INFRARED imaging, *BIOGEOCHEMISTRY, *FLOODPLAINS, *SNOWMELT, *COOLING, *HYDROLOGY

Abstract

Summary Understanding the temperature dynamics of rivers is critical for their management and for ecological and biogeochemical aquatic processes. In proglacial rivers, there is typically a paucity of thermal observations which in turn limits the understanding of these sensitive and evolving environments. Here we collected ground-based thermal images, with approximately meter resolution and imaged every half hour for 24 h, of a proglacial river and 2 km 2 of its floodplain and interpret the observations using a numerical energy balance model. The images revealed the longitudinal thermal pattern of the Urbach River in Switzerland – there was gradual cooling in the upstream half of the study section and then warming in the remaining downstream portion. This pattern persisted through the diurnal warming and cooling cycle. The spatio-temporal thermal pattern was explained by a model that included distributed thermal inputs of cooler water in the upstream half coming from alluvial fans and warmer water in the downstream half running off steep cliffs that warm snowmelt. The warm inputs from the cliffs were confirmed by the thermal imaging. These data and the associated modeling illustrated that distributed inflows can overwhelm the influence of atmospheric fluxes, and that their knowledge is critical for understanding stream temperatures. The combination of modeling and detailed time-lapse thermal imaging allowed for identification and quantification of processes critical to in-stream temperature dynamics in a proglacial river. [ABSTRACT FROM AUTHOR]

Published

2014

274. Which stream wood becomes functional following wildfires?

Author

Vaz, Pedro G., Merten, Eric C., Warren, Dana R., Robinson, Christopher T., Pinto, Paulo, and Rego, Francisco C.

Subjects

*WILDFIRES, *BIOTIC communities, *WOOD, *HYDRAULICS, *GEOMORPHOLOGY, *STRUCTURAL equation modeling

Abstract

Abstract: Large wood is a critical element in stream ecosystems, but only a subset of wood pieces actually provide hydraulic, geomorphic, and ecological functions. We test the current paradigm that larger pieces provide more function, and examine the role wildfires may play in affecting functionality of recruited wood. We conducted a cross-basin analysis in nine central Portugal watersheds, obtaining a variety of measurements on 1483 wood pieces (diameter≥0.05m; length≥0.5m) in 27 streams burned within six years prior. We examined nonlinear relationships and indirect effects on function using Generalized Additive Modeling and Structural Equation Modeling. Variables with direct effects on function were piece diameter, rootwads, anchoring, position (bridging, ramping, loose), longitudinal distance along the stream continuum, and the ratio of piece length to channel width. The effect of length ratio on function was nonlinear. Relatively long pieces were more likely to be functional until they were ∼3 times the channel width, at which point longer pieces became less likely to be functional. Post-fire wood likely lacked complexity and longer pieces were more likely to be bridging; both conditions may have prohibited them from interacting with the wetted area. Wildfires had indirect effects on function. Burned pieces were more likely to be large in diameter (thus more likely functional) but not anchored (thus less likely functional); these antagonistic effects may be the reason burned status had no direct effect on function. Our results challenge the well-established idea that the function of wood in streams is simply a matter of wood size, along with indicators of longevity (e.g. stability and decay status). Relatively long pieces may in fact provide less function to the stream, at least until they break or are transported further downstream. Practitioners installing wood to streams should consider pieces with wide diameter and rootwads, approximately 3 times the channel width, and anchored but not bridging the channel. [Copyright &y& Elsevier]

Published

2013

275. Response of lotic microbial communities to altered water source and nutritional state in a glaciated alpine floodplain.

Author

Freimann, Remo, Bürgmann, Helmut, Findlay, Stuart E. G., and Robinson, Christopher T.

Subjects

*BIOTIC communities, *ECOLOGICAL research, *MICROBIAL ecology, *SEDIMENTS, *GLACIERS, *FLOODPLAIN ecology, *GROUNDWATER

Abstract

Factors driving bacterial community composition (BCC) and linkages to ecosystem function (EF) are a fundamental interest in microbial ecology. Climate warming is expected to cause a shift from glacial- to groundwater-dominated water sources in alpine catchments due to receding glaciers, which is likely accompanied by a shift in BCC and EF. In this context, we performed a reciprocal transplant experiment of hyporheic sediments within a Swiss alpine floodplain. We assessed the influence of water source (groundwater = krenal, glacial water = kryal) and nutritional state (C, N, and P) on BCC and EF. Experimental response was tested using automated ribosomal intergenic spacer amplification and potential activities of eight different enzymes. BCC from both kryal and krenal systems was highly resistant to changes in water source, yet exhibited pronounced EF flexibility. Major factors determining BCC and EF response were sediment origin followed by seasonal variation in BCC. The gradient in seasonal change in BCC showed different strengths in the two water systems. Krenal BCC was more seasonally stable compared with kryal BCC, although functional plasticity showed the same extent in both. This difference in connectivity between BCC and EF suggests that krenal BCC was dominated by generalists, whereas kryal BCC was dominated by specialists. The weak effect of altered nutritional state on BCC and EF indicates a complex but hierarchically structured relationship among these factors. We conclude that microbial communities in alpine catchments are able to rapidly buffer the effect of shifts in water source on ecosystem functioning. [ABSTRACT FROM AUTHOR]

Published

2013

276. Effects of forest type and stream size on volume and distribution of stream wood: legacies of wildfire in a Euro-Mediterranean context.

Author

Vaz, Pedro G., Warren, Dana R., Merten, Eric C., Robinson, Christopher T., Pinto, Paulo, and Rego, Francisco C.

Subjects

*SILVICULTURAL systems, *LOGGING & the environment, *TIMBER rafting, *FOREST management, *LUMBER transportation

Abstract

Downed wood pieces are key links between terrestrial and aquatic ecosystems. They promote organic matter retention, create habitat, and potentially increase stream productivity. The stock of downed wood in a river system is a product of the interaction between wood supply, transport, in situ losses, and retention characteristics of the system. Fire and forest management are important disturbances that influence the amount and organization of stream wood with boom-and-bust periods of recruitment and fluvial transport processes. We examined 1st - through 3rd-order Portuguese streams flowing through 3 common silvicultural systems in southern Europe: forests of cork oak, eucalyptus, and maritime pine. Our data set included 1483 pieces of wood in 27 streams, all of which had experienced extensive wildfires within the previous 6 y. We used binned neighbor-k analysis to assess wood organization (segregated, random, or aggregated). We then used linear mixed-effects modeling to evaluate the effects of stream order, forest type, and their interaction on wood volume and organization. The best predictor of wood volume and organization was the interaction between forest type and stream order. Most wood pieces were burned and organization was low, suggesting that arrangement of wood was largely a product of input dynamics rather than transport processes at this time. Potential drivers of across-system variability included vegetation obstructions, wood length:channel width ratios, management actions, and effects of fire. Climate models predict more droughts in the Euro-Mediterranean region in the future, with implications for wood volume, transport, and function as terrestrial vegetation invades intermittent stream channels and plant communities shift from managed forests to shrublands with few trees. [ABSTRACT FROM AUTHOR]

Published

2013

277. Tributary effects on the ecological responses of a regulated river to experimental floods.

Author

Consoli, Gabriele, Haller, Rudolf M., Doering, Michael, Hashemi, Saman, and Robinson, Christopher T.

Subjects

*RIVER sediments, *FLOODS, *ADAPTIVE natural resource management, *ENVIRONMENTAL management, *DAMS

Abstract

Rivers regulated by dams display several ecosystem alterations due to modified flow and sediment regimes. Downstream from a dam, ecosystem degradation occurs because of reduced disturbance, mostly derived from limitations on flow variability and sediment supply. In the last decade, most flow restoration/dam impact mitigation was oriented towards the development of environmental flows. Flow variability (and consequent disturbance) can be reintroduced by releasing artificial high flows (experimental floods). Flow-sediment interactions during experimental floods represent strong ecosystem drivers, influencing nutrient dynamics, and metabolic and functional properties. In river networks, sediment and water inputs from tributaries generate points of discontinuity that can drive major changes in environmental conditions, affecting habitat structure and determining functional differences between upstream and downstream. However, despite the relevance for management, flow/sediment relations during environmental flows − and more importantly during experimental floods − remain poorly understood, mostly due to the lack of empirical evidence. In this study, we examined how a major tributary (source of water and sediments) modified the physical habitat template of a regulated river, thereby influencing ecological and geomorphological responses to experimental floods. Methods combined high-resolution drone mapping techniques with a wide range of biological samples collected in field surveys before, during, and after experimental floods in an alpine river. Data were used to quantify changes in relevant functional and structural ecosystem properties, relating ecological responses to geomorphological dynamics. Results highlight the importance of tributaries in restoring ecosystem properties lost after damming, enhancing the resilience of the system. In addition, we observed that disturbance legacy played a fundamental role in determining ecological conditions of a river prior to experimental floods, thus confirming that considering flow variability and sediment availability is crucial in adaptive dam management and environmental flows design. • Experimental floods mitigate dam impacts restoring flow variability and disturbance. • Sediment supply and disturbance legacy shape eco-morphological responses to floods. • Tributaries can modify the effect of experimental floods on ecosystem properties. [ABSTRACT FROM AUTHOR]

Published

2022

278. Risk Assessment of Hydropower in Switzerland: Uncertainty Quantification in the Modelling of Dam-Break Consequences

Author

Kalinina, Anna, Robinson, Christopher T., Patt, Anthony, Burgherr, Peter, Spada, Matteo, and Gunn, Russell M.

Subjects

Civil engineering, FOS: Civil engineering, ddc:624

Published

2019

279. The effects of sediment traps on instream habitat and macroinvertebrates of mountain streams.

Author

Mathers, Kate L., Kowarik, Carmen, Rachelly, Cristina, Robinson, Christopher T., and Weber, Christine

Subjects

*HABITATS, *SEDIMENT transport, *PARTICLE size distribution, *SEDIMENTS, *ECOLOGICAL resilience, *INVERTEBRATES

Abstract

Sediment transport in mountain streams can be a major hazard to downstream infrastructure. Consequently, sediment traps are a common feature in many high gradient streams to retain large volumes of sediment and protect settlements from major sediment transport events. Despite the wide application of these instream structures, there is little knowledge regarding the environmental and ecological effects on streams. Here, we investigated the hydromorphological effects of sediment traps on instream habitats and associated macroinvertebrate communities in four impacted and three non-impacted streams in Switzerland. Sediment traps significantly disrupted the sediment regime homogenising grain size percentiles compared to the natural stepwise downstream fining in control streams. This disruption in the sediment regime resulted in finer grain size distributions upstream of the sediment trap, and reduced substrate diversity in the sediment retention basin and just downstream of the trap. The reductions in substrate diversity resulted in an altered macroinvertebrate community composition. Further, the disconnection in sediment transport led to a lack of longitudinal correlation in macroinvertebrate communities. Refugia provision downstream of the sediment trap, and resource availability within the retention basin, were diminished, potentially reducing resilience of macroinvertebrate assemblages to instream disturbances. The effects of sediment traps were most likely localised in three of the four streams with substrate diversity recovering to comparable control values within 8 wetted widths (ca. 50 m) downstream of the trap associated with natural longitudinal fining. In contrast, ecological and environmental effects propagated downstream in one impacted stream with no recovery being evident. Sediment retention basins in the impacted streams provided a local artificially unique habitat of dynamic-braided channels. Our results indicate that sediment traps can significantly disrupt the sediment regime with important consequences for instream ecology and environmental conditions, although these effects can be system specific. Further work is needed to fully understand the effects of sediment traps in mountain streams to assist resource managers in the mitigation and future construction of these structures. • Sediment traps disrupt sediment transport processes. • Sediment traps can reduce habitat diversity within and downstream of the trap. • Sediment traps can reduce refugia provision and ecological resilience downstream. • Local effects were found in 3 of 4 impacted streams but propagated downstream in 1 stream. • Retention basins themselves may offer an artificially unique localized habitat. [ABSTRACT FROM AUTHOR]

Published

2021

280. Microbial communities in floodplain ecosystems in relation to altered flow regimes and experimental flooding.

Author

Doering, Michael, Freimann, Remo, Antenen, Nadine, Roschi, Alexia, Robinson, Christopher T., Rezzonico, Fabio, Smits, Theo H.M., and Tonolla, Diego

Published

2021

281. Flow Sediment Interactions in Managed Rivers: Influence on Ecosystem Structure and Function

Author

Martín Sanz, Eduardo Javier, Robinson, Christopher T., Jokela, Jukka, and Jähnig, Sonja

Subjects

Macroinvertebrates, Flow regime, Sediment regime, Reservoirs, Enviromental Impact, Sediment Respiration, Sediment Bypass Tunnel, Life sciences, Earth sciences, ddc:570, ddc:550, Civil engineering, FOS: Civil engineering, ddc:624

Abstract

Flow and sediment regimes are two of the main abiotic factors driving riverine ecosystems, interacting at different temporal and spatial scales. These interactions have a strong influence on habitat composition, ecosystem processes and community composition. Nowadays, flow and sediment regimes are highly altered due to anthropogenic modifications of rivers and floodplains, such as dams or river channelization, which disrupt the main properties of both regimes. The primary goal of this thesis was to understand the role of flow and sediment interactions on ecosystem structure and function in managed rivers and evaluate different techniques that mitigate the impact of rivers regulation. Hyporheic sediment respiration, periphyton biomass and chlorophyll-a were used as indicators of ecosystem function, whereas macroinvertebrates assemblages were used as a structural indicator. The first chapter studied the variability of different indicators of ecosystem structure and function under different flow and geomorphology conditions. The study took place in a section of the river Thur, where a widening restoration was implemented by removing 1 km of lateral protections. This widening section characterized by newly established habitats such as gravel bars is fringed upstream and downstream by channelized sections. Channelized sites showed higher rates of sediment respiration, periphyton and macroinvertebrates compared to restored sites. Restored sites showed a greater temporal and spatial variability in the measured indicators due to the influence of flow disturbance, which was lower in channelized sites. Overall, sediment respiration and macroinvertebrate richness were related to flow variability and geomorphology, whereas periphyton and macroinvertebrate density was influenced mainly by flow variability. The second chapter investigated the influence of flow regulation (residual flows and hydropeaking) on aquatic life stages that can persist in sediments during dry phases (i.e. macroinvertebrate seedbanks). Gravel bars affected by hydropeaking showed greater densities of organisms due to the high frequency of inundations, which increased the drift of animals onto gravel bars. The opposite trend was found in residual flow rivers, where there is a lack of flood occurrence. The third chapter assessed the ecological impact of a Sediment Bypass Tunnel, a structure that routes upstream sediment input around dams, reducing the accumulation of sediments in the dam. Operations of the tunnel create a general decrease in measured indicators (sediment respiration, periphyton and macroinvertebrates), the decrease being related to the magnitude of flow and sediment released at the tunnel. The fourth chapter described the interactions of flow and sediment inputs in two rivers with contrasting management programs (experimental floods and sediment bypass tunnel). Sediment lateral inputs caused local interactions with flow, generating morphological and biotic heterogeneity in the streambed, whereas upstream sediment inputs together with high flows by sediment bypass tunnel created a general decrease in biotic indicators in the system, reducing spatial variability. The results from this thesis showed that each of the measured ecosystem properties is influenced in a specific way by flow-sediment interactions. The results indicated that different techniques can be used to mitigate the negative consequences of flow and sediment regime alterations on ecosystem functioning and structure, highlighting the important role of integrative objectives in river management.

Published

2017

282. On biological evolution and environmental solutions.

Author

Matthews, Blake, Jokela, Jukka, Narwani, Anita, Räsänen, Katja, Pomati, Francesco, Altermatt, Florian, Spaak, Piet, Robinson, Christopher T., and Vorburger, Christoph

Abstract

Drawing insights from multiple disciplines is essential for finding integrative solutions that are required to tackle complex environmental problems. Human activities are causing unprecedented influence on global ecosystems, culminating in the loss of species and fundamental changes in the selective environments of organisms across the tree of life. Our collective understanding about biological evolution can help identify and mitigate many of the environmental problems in the Anthropocene. To this end, we propose a stronger integration of environmental sciences with evolutionary biology. Unlabelled Image • Evolutionary theory is not widely used to address environmental problems. • Evolutionary processes can both ameliorate and exacerbate environmental problems. • Evolution can be informative about disease dynamics, biofuel production, adaptation to pollution, and harmful algal blooms. • We propose a stronger integration of evolutionary biology with environmental sciences to help solve environmental problems. [ABSTRACT FROM AUTHOR]

Published

2020

283. Evolutionary ecology of the alpine mayfly Baetis alpinus (Ephemeroptera): new perspectives from cryptic lineages

Author

Leys, Marie, Robinson, Christopher T., Jokela, Jukka, and Pauls, Steffen U.

Subjects

ANIMAL DETERMINATION (ZOOLOGY AND PALAEOZOOLOGY), BAETIDAE (ZOOLOGIE), EVOLUTIONARY ECOLOGY + POPULATION EVOLUTION (BIOLOGICAL EVOLUTION), TIERBESTIMMUNG (ZOOLOGIE UND PALÄOZOOLOGIE), POPULATIONSGENETIK (ZOOLOGIE), POPULATION GENETICS (ZOOLOGY), EVOLUTIONÄRE ÖKOLOGIE + POPULATIONSEVOLUTION (BIOLOGISCHE EVOLUTION), BAETIDAE (ZOOLOGY), ddc:590, Zoological sciences

Published

2016

284. Rivers of the Central European Highlands and Plains

Author

Leonard Sandin, Morten Lauge Pedersen, Hans Estrup Andersen, Aleksandra Gancarczyk, Brian Kronvang, Matthias Scholten, Justyna Hachol, Nikolai Friberg, Ewa Wnuk-Glawdel, L.M. Svendsen, Sonja Stendera, Helmut Fischer, Franz Schöll, Martin T. Pusch, Jürgen Bäthe, Carl Christian Hoffmann, Franciszek Nowacki, Christian Wolter, H. Behrendt, Tockner, K., Uehlinger, U., Robinson, C., Peter, F., Tonolla, D., Siber, R., Tockner, Klement, Uehlinger, Urs, Robinson, Christopher T., Zarfl, Christiane, and T. Robinson, Christopher

Subjects

Hydrology, Elbe, Irrigation, geography.geographical_feature_category, business.industry, Drainage basin, Sewage, River bed, Weser, Europe, Geography, Ecoregion, Fauna, Habitat, Rivers, Flora, Drawa, Tributary, Skjern, business, Oder, Hydropower

Abstract

Some of the main rivers of the Central European Highlands and Plains flow into the Baltic and North Seas, including the rivers Weser, Elbe, and Oder, drain the ecoregion of the central European highlands and plains. In addition to these rivers, this chapter describes some smaller but peculiar rivers such as the Em (Sweden), Skjern (Denmark), Spree (Germany), and Drawa (Poland). Much of the landscape is dominated by glacial and periglacial geomorphic elements such as moraines, outwash plains adjacent to terminal moraines, different types of lakes (ice-scour lakes, moraine-dammed ribbon lakes, kettle lakes, and glacial drift-plain lakes formed under the ice sheet), large glacial valleys, and large lowland plains consisting of glaciofluvial deposits. The different retreat stages of the glacial sheet produced a sequence of glacial valleys forcing meltwaters toward the North Sea. These valleys are used partially by some rivers today, including the Elbe, Spree, Warta, and Skjern. As river sediments mainly consist of sand, sediment transport occurs nearly continuously, creating ripples or subaqueous sand dunes often reaching a crest height of up to 1.5m. Regional ecological characteristics of flowing waters in the ecoregion were summarized. This chapter summarizes the hydrology, biochemistry, geomorphology, flora and fauna, and economic importance of each of these rivers. Human intervention to conserve and manage these rivers is also discussed.

285. How effective are ecological metrics in supporting conservation and management in degraded streams?

Author

Mathers KL, Robinson CT, Hill M, Kowarik C, Heino J, Deacon C, and Weber C

Abstract

Biodiversity loss is increasing worldwide, necessitating effective approaches to counteract negative trends. Here, we assessed aquatic macroinvertebrate biodiversity in two river catchments in Switzerland; one significantly degraded and associated with urbanisation and instream barriers, and one in a near-natural condition. Contrary to our expectations, environmental heterogeneity was lower in the near-natural stream, with enhanced productivity in the degraded system resulting in a greater range of environmental conditions. At face value, commonly employed alpha, beta and gamma biodiversity metrics suggested both catchments constituted healthy systems, with greater richness or comparable values recorded in the degraded system relative to the near-natural one. Further, functional metrics considered to be early indicators for anthropogenic disturbance, demonstrated no anticipated differences between degraded and near-natural catchments. However, investigating the identity of the taxa unique to each river system showed that anthropogenic degradation led to replacement of specialist, sensitive species indicative of pristine rivers, by generalist, pollution tolerant species. These replacements reflect a major alteration in community composition in the degraded system compared with the near-natural system. Total nitrogen and fine sediment were important in distinguishing the respective communities. We urge caution in biodiversity studies that employ numerical biodiversity metrics alone. Assessing just one aspect of diversity, such as richness, is not sufficient to track biodiversity changes associated with environmental stress. We advocate that biodiversity monitoring for conservation and management purposes must go beyond traditional richness biodiversity metrics, to include indices that incorporate detailed nuances of biotic communities that relates to taxon identity., Supplementary Information: The online version contains supplementary material available at 10.1007/s10531-024-02933-7., Competing Interests: Conflict of interestThe authors declare no conflict of interest., (© The Author(s) 2024.)

Published

2024

286. Importance of artificial high flows in maintaining the ecological integrity of a regulated river.

Author

Robinson CT, Consoli G, and Ortlepp J

Subjects

Animals, Insecta, Floods, Weather, Rivers, Ecosystem

Abstract

Artificial high flows attempt to simulate natural flood pulses in flow-regulated rivers with the intent to improve their ecological integrity. The long-term use of such high flow events have shown beneficial ecological effects on various rivers globally. However, such responses are often non-linear and characterized by underlying feedback mechanisms among ecosystem components. The question arises as to what happens when such high flow releases are disrupted or even discontinued. Here, we used the long-term (22 years) monitoring dataset from the river Spöl to examine whether discontinuation (2016-2021) of the flood program (annual artificial high flows from 2000 to 2016) resulted in the ecological degradation of the river. We used monitoring data of physico-chemistry, periphyton, benthic organic matter, macroinvertebrates and fish (brown trout, Salmo trutta fario L.) in the analysis. The flood program had no long-term effect on water physico-chemistry with most parameters showing typical variations associated with season and inter-annual weather patterns. The floods were effective at mobilizing bed sediments that reduced periphyton biomass and benthic organic matter following each flood. Increases in periphyton biomass and benthic organic matter occurred between floods, but both parameters showed no significant increase with discontinuation of the flood program. Floods reduced macroinvertebrate densities, but with density increases occurring between floods. The pulsed disturbances, and the progressive change in the habitat template, resulted in shifts in community assembly by reducing densities of Gammarus fossarum, a dominant crustacean, which allowed other taxa to colonize the system. Macroinvertebrate densities remained low after discontinuation of the floods, although G. fossarum densities have increased substantially while other taxa, especially some stoneflies, remained low in abundance. Notably, community assembly returned to a pre-flood composition with discontinuation of the floods. The abundance of brown trout increased substantially during the flood program but returned to low pre-flood numbers with discontinuation of the floods. We conclude that the flood program was beneficial to the ecology of the river Spöl and discontinuation of the floods resulted in degradation of the system after a relatively short lag period. However, the system showed high resilience to an earlier perturbation, a sediment spill in 2013, suggesting a rapid positive response by biota with resumption of the flood program., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2023

287. Author Correction: Functional diversity and community assembly of river invertebrates show globally consistent responses to decreasing glacier cover.

Author

Brown LE, Khamis K, Wilkes M, Blaen P, Brittain JE, Carrivick JL, Fell S, Friberg N, Füreder L, Gislason GM, Hainie S, Hannah DM, James WHM, Lencioni V, Olafsson JS, Robinson CT, Saltveit SJ, Thompson C, and Milner AM

Published

2023

288. Mercury levels in sediment, fish and macroinvertebrates of the Boroo River, northern Mongolia, under the legacy of gold mining.

Author

Udodenko YG, Robinson CT, Choijil J, Badrakh R, Munkhbat J, Ivanova ES, and Komov VT

Subjects

Animals, Ecosystem, Environmental Monitoring, Geologic Sediments, Gold, Mining, Mongolia, Rivers, Ephemeroptera, Mercury analysis, Water Pollutants, Chemical analysis

Abstract

Gold mining is currently one of the main anthropogenic sources of mercury in the environment. In this study, the total mercury content was measured in bottom sediments, benthic macroinvertebrates (mayfly larvae), and fish (Siberian dace) along the Boroo River in northern Mongolia. There was a gold recovery plant in the middle reaches of the river until the mid-twentieth century; an accident there in the 1950s caused a mercury spill. We found an increased content of mercury in measured ecosystem components near the plant compared to the upper reaches of the river. The mercury content in sediments varied from trace amounts in the upper Boroo to 2200 ng/g dry weight (dw) in the vicinity of the plant ruins. The mercury content in mayfly larvae ranged from 50 to 2940 ng/g dw and had a spatial pattern as sediments, with the highest concentrations near the plant. The mercury content in sediments was lower at the mouth of the Boroo River than near the plant, reflecting the lower boundary of the mercury spill. Maximum values of mercury content in fish muscle were found at the river's mouth and were several times higher than in other rivers of northern Mongolia. Median mercury content in muscles of dace from the lower Boroo in 2016 has doubled since studies in 2010-2012, which may be the result of current mercury releases from gold mining., (© 2021. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2022

289. Summer is in winter: Disturbance-driven shifts in macroinvertebrate communities following hydroelectric power exploitation.

Author

Gabbud C, Robinson CT, and Lane SN

Subjects

Animals, Seasons, Switzerland, Biodiversity, Ecosystem, Geologic Sediments analysis, Invertebrates physiology, Power Plants, Rivers

Abstract

In Alpine streams, humans have strongly modified the interactions between hydraulic processes, geomorphology and aquatic life through dams, flow abstraction at water intakes and river channel engineering. To mitigate these impacts, research has addressed both minimum flows and flow variability to sustain aquatic ecosystems. Whilst such environmental flows might work downstream of dams, this may not be the case for water intakes. Intakes, generally much smaller than dams, are designed to abstract water and to leave sediment behind. Sediment accumulation then results in the need to flush intakes periodically, often more frequently than daily in some highly glaciated basins. Sediment delivery downstream is then maintained through short duration floods with very high sediment loads. Here we tested the hypothesis that sediment flushing, and the associated high frequency of bed disturbance, controls in-stream habitat and macroinvertebrate assemblages. We collected macroinvertebrates over a 17-month period from an Alpine stream as well as a set of lateral unperturbed tributaries that served as controls. In contrast to established conceptual models, our results showed that the stream is largely void of life during summer, but that populations recover rapidly as the frequency of intake flushing falls in early autumn, producing richer and larger populations in winter and early spring. The recovery in autumn may be due to the recruitment of individuals from tributaries. We conclude that intake flushing in summer inverts expected summer-winter macroinvertebrate abundances, and questions the extent to which environmental flows in intake-impacted Alpine streams will lead to improvements in instream macrofauna unless sediment also is managed., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2019

290. Global patterns and drivers of ecosystem functioning in rivers and riparian zones.

Author

Tiegs SD, Costello DM, Isken MW, Woodward G, McIntyre PB, Gessner MO, Chauvet E, Griffiths NA, Flecker AS, Acuña V, Albariño R, Allen DC, Alonso C, Andino P, Arango C, Aroviita J, Barbosa MVM, Barmuta LA, Baxter CV, Bell TDC, Bellinger B, Boyero L, Brown LE, Bruder A, Bruesewitz DA, Burdon FJ, Callisto M, Canhoto C, Capps KA, Castillo MM, Clapcott J, Colas F, Colón-Gaud C, Cornut J, Crespo-Pérez V, Cross WF, Culp JM, Danger M, Dangles O, de Eyto E, Derry AM, Villanueva VD, Douglas MM, Elosegi A, Encalada AC, Entrekin S, Espinosa R, Ethaiya D, Ferreira V, Ferriol C, Flanagan KM, Fleituch T, Follstad Shah JJ, Frainer Barbosa A, Friberg N, Frost PC, Garcia EA, García Lago L, García Soto PE, Ghate S, Giling DP, Gilmer A, Gonçalves JF Jr, Gonzales RK, Graça MAS, Grace M, Grossart HP, Guérold F, Gulis V, Hepp LU, Higgins S, Hishi T, Huddart J, Hudson J, Imberger S, Iñiguez-Armijos C, Iwata T, Janetski DJ, Jennings E, Kirkwood AE, Koning AA, Kosten S, Kuehn KA, Laudon H, Leavitt PR, Lemes da Silva AL, Leroux SJ, LeRoy CJ, Lisi PJ, MacKenzie R, Marcarelli AM, Masese FO, McKie BG, Oliveira Medeiros A, Meissner K, Miliša M, Mishra S, Miyake Y, Moerke A, Mombrikotb S, Mooney R, Moulton T, Muotka T, Negishi JN, Neres-Lima V, Nieminen ML, Nimptsch J, Ondruch J, Paavola R, Pardo I, Patrick CJ, Peeters ETHM, Pozo J, Pringle C, Prussian A, Quenta E, Quesada A, Reid B, Richardson JS, Rigosi A, Rincón J, Rîşnoveanu G, Robinson CT, Rodríguez-Gallego L, Royer TV, Rusak JA, Santamans AC, Selmeczy GB, Simiyu G, Skuja A, Smykla J, Sridhar KR, Sponseller R, Stoler A, Swan CM, Szlag D, Teixeira-de Mello F, Tonkin JD, Uusheimo S, Veach AM, Vilbaste S, Vought LBM, Wang CP, Webster JR, Wilson PB, Woelfl S, Xenopoulos MA, Yates AG, Yoshimura C, Yule CM, Zhang YX, and Zwart JA

Subjects

Human Activities, Humans, Carbon Cycle physiology, Ecosystem, Environmental Monitoring methods, Rivers microbiology, Temperature

Abstract

River ecosystems receive and process vast quantities of terrestrial organic carbon, the fate of which depends strongly on microbial activity. Variation in and controls of processing rates, however, are poorly characterized at the global scale. In response, we used a peer-sourced research network and a highly standardized carbon processing assay to conduct a global-scale field experiment in greater than 1000 river and riparian sites. We found that Earth's biomes have distinct carbon processing signatures. Slow processing is evident across latitudes, whereas rapid rates are restricted to lower latitudes. Both the mean rate and variability decline with latitude, suggesting temperature constraints toward the poles and greater roles for other environmental drivers (e.g., nutrient loading) toward the equator. These results and data set the stage for unprecedented "next-generation biomonitoring" by establishing baselines to help quantify environmental impacts to the functioning of ecosystems at a global scale.

Published

2019

291. Ecological influence of sediment bypass tunnels on macroinvertebrates in dam-fragmented rivers by DNA metabarcoding.

Author

Serrana JM, Yaegashi S, Kondoh S, Li B, Robinson CT, and Watanabe K

Subjects

Animals, DNA Barcoding, Taxonomic, Invertebrates classification, Rivers, Water Resources, Biodiversity, Ecological Parameter Monitoring methods, Invertebrates genetics

Abstract

Sediment bypass tunnels (SBTs) are guiding structures used to reduce sediment accumulation in reservoirs during high flows by transporting sediments to downstream reaches during operation. Previous studies monitoring the ecological effects of SBT operations on downstream reaches suggest a positive influence of SBTs on riverbed sediment conditions and macroinvertebrate communities based on traditional morphology-based surveys. Morphology-based macroinvertebrate assessments are costly and time-consuming, and the large number of morphologically cryptic, small-sized and undescribed species usually results in coarse taxonomic identification. Here, we used DNA metabarcoding analysis to assess the influence of SBT operations on macroinvertebrates downstream of SBT outlets by estimating species diversity and pairwise community dissimilarity between upstream and downstream locations in dam-fragmented rivers with operational SBTs in comparison to dam-fragmented (i.e., no SBTs) and free-flowing rivers (i.e., no dam). We found that macroinvertebrate community dissimilarity decreases with increasing operation time and frequency of SBTs. These factors of SBT operation influence changes in riverbed features, e.g. sediment relations, that subsequently effect the recovery of downstream macroinvertebrate communities to their respective upstream communities. Macroinvertebrate abundance using morphologically-identified specimens was positively correlated to read abundance using metabarcoding. This supports and reinforces the use of quantitative estimates for diversity analysis with metabarcoding data.

Published

2018

292. Functional diversity and community assembly of river invertebrates show globally consistent responses to decreasing glacier cover.

Author

Brown LE, Khamis K, Wilkes M, Blaen P, Brittain JE, Carrivick JL, Fell S, Friberg N, Füreder L, Gislason GM, Hainie S, Hannah DM, James WHM, Lencioni V, Olafsson JS, Robinson CT, Saltveit SJ, Thompson C, and Milner AM

Subjects

Animals, Ecosystem, Europe, New Zealand, North America, Biodiversity, Global Warming, Ice Cover, Invertebrates physiology, Rivers

Abstract

Global change threatens invertebrate biodiversity and its central role in numerous ecosystem functions and services. Functional trait analyses have been advocated to uncover global mechanisms behind biodiversity responses to environmental change, but the application of this approach for invertebrates is underdeveloped relative to other organism groups. From an evaluation of 363 records comprising >1.23 million invertebrates collected from rivers across nine biogeographic regions on three continents, consistent responses of community trait composition and diversity to replicated gradients of reduced glacier cover are demonstrated. After accounting for a systematic regional effect of latitude, the processes shaping river invertebrate functional diversity are globally consistent. Analyses nested within individual regions identified an increase in functional diversity as glacier cover decreases. Community assembly models demonstrated that dispersal limitation was the dominant process underlying these patterns, although environmental filtering was also evident in highly glacierized basins. These findings indicate that predictable mechanisms govern river invertebrate community responses to decreasing glacier cover globally.

Published

2018

293. Hydrologic linkages drive spatial structuring of bacterial assemblages and functioning in alpine floodplains.

Author

Freimann R, Bürgmann H, Findlay SE, and Robinson CT

Abstract

Microbial community assembly and microbial functions are affected by a number of different but coupled drivers such as local habitat characteristics, dispersal rates, and species interactions. In groundwater systems, hydrological flow can introduce spatial structure and directional dependencies among these drivers. We examined the importance of hydrology in structuring bacterial communities and their function within two alpine floodplains during different hydrological states. Piezometers were installed in stream sediments and surrounding riparian zones to assess hydrological flows and also were used as incubation chambers to examine bacterial community structures and enzymatic functions along hydrological flow paths. Spatial eigenvector models in conjunction with models based on physico-chemical groundwater characteristics were used to evaluate the importance of hydrologically-driven processes influencing bacterial assemblages and their enzymatic activities. Our results suggest a strong influence (up to 40% explained variation) of hydrological connectivity on enzymatic activities. The effect of hydrology on bacterial community structure was considerably less strong, suggesting that assemblages demonstrate large functional plasticity/redundancy. Effect size varied between hydrological periods but flow-related mechanisms always had the most power in explaining both bacterial structure and functioning. Changes in hydrology should be considered in models predicting ecosystem functioning and integrated into ecosystem management strategies for floodplains.

Published

2015

294. Long-term changes in community assembly, resistance, and resilience following experimental floods.

Author

Robinson CT

Subjects

Animals, Rivers, Time Factors, Ecosystem, Environmental Monitoring methods, Floods, Invertebrates classification, Invertebrates physiology

Abstract

This study examined the long-term changes in community assembly, resistance, and resilience of macroinvertebrates following 10 years of experimental floods in a flow regulated river. Physico-chemistry, macroinvertebrates, and periphyton biomass were monitored before and sequentially after each of 22 floods, and drift/seston was collected during six separate floods over the study period. The floods reduced the density and taxon richness of macroinvertebrates, and a nonmetric dimensional scaling (NMDS) analysis distinguished temporal shifts in community assembly. Resistance (measured as the relative lack of loss in density) tofloods varied among taxa, and the abundance of resistant taxa was related to the temporal changes in community assembly. Community resistance was inversely related to flood magnitude with all larger floods (> 25 m3/s, > 16-fold over baseflow) reducing densities by > 75% regardless of flood year, whereas smaller floods (< 20 m3/s) reduced taxon richness approximately twofold less than larger floods. No relationship was found between flood magnitude and the relative loss in periphyton biomass. Resilience was defined as the recovery slope (positive slope of a parameter with time following each flood) and was unrelated to shifts in community assembly or resistance. Macroinvertebrate drift and seston demonstrated hysteresis (i.e., a temporal response in parameter quantity with change in discharge) during each flood, although larger floods typically had two peaks in both parameters. The first peak was a response to the initial increases in flow, whereas the second peak was associated with streambed disturbance (substrate mobility) and side-slope failure causing increased scour. Drift density was 3-9 times greater and that of seston 3-30 times greater during larger floods than smaller floods. These results demonstrate temporal shifts in macroinvertebrate community assembly toward a pre-dam assemblage following sequential floods in this flow regulated river, thus confirming the ecological role of habitat filtering in organism distribution and abundance. Community resistance and resilience were unrelated to shifts in community assembly, suggesting that they are mostly evolutionary properties of ecosystems as populations adapt to changing environmental (disturbance regimes) and biotic (novel colonists) conditions. As these systems show behaviors similar to dispersal-limited ecosystems, a long-term perspective is required for management actions targeted toward regulated and fragmented rivers.

Published

2012