The Role of Groundwater-Stream Interactions for Uranium Fluxes in Fluvial Systems

2005 ◽  
pp. 263-274
Author(s):  
Frank Winde
Keyword(s):  
Fluvial Systems

scholarly journals Fluvial Geomorphology and River Management

Water ◽  
2021 ◽  
Vol 13 (11) ◽  
pp. 1608
Author(s):  
Salvatore Ivo Giano
Keyword(s):  
Human Activities ◽  
River Restoration ◽  
Fluvial Geomorphology ◽  
Landscape Evolution ◽  
River Management ◽  
Special Issue ◽  
Fluvial Systems ◽  
The Impact

This Special Issue deals with the role of fluvial geomorphology in landscape evolution and the impact of human activities on fluvial systems, which require river restoration and management [...]

The role of thermal contraction crack polygons in cold-desert fluvial systems

2008 ◽  
Vol 20 (6) ◽  
pp. 565-579 ◽  
Author(s):  
Joseph S. Levy ◽  
James W. Head ◽  
David R. Marchant
Keyword(s):  
Thermal Contraction ◽  
Patterned Ground ◽  
Sediment Grain Size ◽  
Cold Desert ◽  
Fluvial Systems ◽  
Hyporheic Zones ◽  
Continuous Presence ◽  
And Storage ◽  
Composite Wedge

AbstractThermal contraction crack polygons modify the generation, transport, and storage of water in Wright Valley gullies. Water generation is contributed to by trapping of windblown snow in polygon troughs. Water transport is modified by changes to the ice-cement table and active layer topography caused by polygon trough formation. Water storage is modified by sediment grain-size distribution within polygons in gully distal hyporheic zones. Patterned ground morphological variation can serve as an indicator of fluvial modification, ranging from nearly unmodified composite-wedge polygons to polygons forming in association with gully channels. Thermal contraction crack polygons may also constrain the gully formation sequence, suggesting the continuous presence of permafrost beneath the Wright Valley gullies during the entire period of gully emplacement. This analysis provides a framework for understanding the relationships between polygons and gullies observed on Mars. If comparable stratigraphic relationships can be documented, the presence of an analogous impermeable ice-cemented layer beneath the gullies can be inferred, suggesting an atmospheric source for Martian gully-carving fluids.

Climatic Fluctuations Reflected in Slope and Fluvial Systems of Polish Carpathians and their Foreland During Upper Quaternary

2015 ◽  
Vol 49 (1) ◽  
Author(s):  
Leszek Starkel
Keyword(s):  
Spatial Differentiation ◽  
Fluvial Systems ◽  
Climatic Fluctuations ◽  
The Holocene ◽  
Leading Role ◽  
Polish Carpathians ◽  
Continuous Sedimentation ◽  
Longitudinal Profiles ◽  
River Valleys

AbstractOn continents, besides lake and bogs, we observe non-continuous sedimentation where particular layers or whole members represent time intervals of various lengths separated by breaks of different origin. Both, fluvial and slope sediments or forms carry climatic signal. By analyzing sources of sediments, factors of transfer, duration of deposition we reconstruct climatic changes (mainly temperature, precipitations and circulation of water). We order the collected records after age and tracing longitudinal profiles of slopes and river valleys. The slopes and valley floors inform us about spatial differentiation of extreme climatic-hydrological events and on their reflection in degradation or aggradation. All this information sums up the records collected in various projects or commissions like IGCP-158 and GLOCOPH (Starkel ed. 1982–1996; Starkel et al. 2007), Climatostratigraphy of the Holocene of Polish territory (Starkel et al. 2013) as well INTIMATE (Starkel et al. 2015; Gębica et al. 2015). It may be concluded that fluctuations in temperature combined with expansion of permafrost were the leading factors in transformation of landscape of analyzed area of Southern Poland during last cold stage, which is in contrary to the Holocene, when variations in humidity especially in frequency of extreme events played a leading role. The continental records very well express the role of transitional phases.

River discharge variability in the rock record? Disentangling the relative role of flow variability and morphodynamic hierarchies on bedform preservation

2021 ◽  
Author(s):  
Sinead Lyster ◽  
Alexander Whittaker ◽  
Elizabeth Hajek ◽  
Vamsi Ganti ◽  
Peter Allison
Keyword(s):  
River Discharge ◽  
Quantitative Information ◽  
Relative Role ◽  
Flow Conditions ◽  
Fluvial Systems ◽  
Flow Variability ◽  
Stratigraphic Architecture ◽  
Coefficients Of Variation ◽  
Rock Record

<p>River discharge variability is a fundamental control on fluvial morphodynamics and, in principle, stratigraphic architecture. The ability to quantitatively constrain discharge variability from fluvial stratigraphy would newly enable us to reconstruct instantaneous or interannual responses of rivers to climatic perturbation in the geologic past. However, the extent to which we can extract quantitative information about discharge variability from fluvial stratigraphy is currently unknown. Recent experimental work indicates that preserved cross-set geometries can potentially be used to inform formative flow conditions and durations. However, to date, this has not been tested on field examples of ancient fluvial systems. Here we use detailed measurements of cross-sets to assess bedform kinematics and formative flow conditions in fluvial strata of three Late Cretaceous geologic formations: the Blackhawk Formation, Castlegate Sandstone, and Ferron Sandstone, which crop out in central Utah, USA.</p><p>Unanimously low coefficients of variation (<em>CV</em>) in preserved cross-set heights of 0.25–0.5 are consistent with the hypothesis that <em>CV</em><<0.88 arises from preservation of bedforms in disequilibrium conditions, which typically occurs during rapid flood recession in a “flashy” flood hydrograph. Bedform preservation in disequilibrium conditions requires that formative flow durations are shorter than bedform turnover timescales. We reconstruct median turnover timescales of 2–3 days, with a 10–90 percentile range of ~1–10 days, which implies that formative flow durations were of order hours to a few days. These durations are consistent with storm-related flood durations in perennial discharge regimes, as opposed to the more sustained flood durations that are typical of subtropical/monsoonal climate regimes. However, it is also possible that this same <em>CV</em> signature (<em>CV</em><<0.88) can be achieved simply by the presence of morphodynamic hierarchies, e.g. concurrently migrating bedforms and bars. We explore whether it is possible to disentangle the relative role of formative flow conditions and morphodynamic hierarchies on bedform preservation using our field data, models of flood stratigraphy, and estimates of bedform preservation ratios. Moreover, we identify future steps that will further our ability to quantitatively extract formative flow variability and, ultimately, discharge variability from the rock record. </p>

The role of biostabilisation in controlling microplastic flux in rivers

2020 ◽  
Author(s):  
Pieter Fourie ◽  
Annie Ockelford ◽  
James Ebdon
Keyword(s):  
River Sediments ◽  
Surface Characteristics ◽  
Sediment Surface ◽  
Sediment Type ◽  
Growth Stages ◽  
Potential Threat ◽  
Biofilm Growth ◽  
Fluvial Systems ◽  
Sediment Mixtures

<p>Microplastic burden in aquatic environments is now recognised as a potential threat to human and environmental health.  Although microplastic transfers to the ocean from the terrestrial river network contributes up to 90% of the plastics in the oceans the factors controlling that transfer remain largely unconstrained. In rivers microplastics are stored within sediment beds and whilst they are there both the microplastic particles and the sediment grains can become colonised by biofilms.  Biofilm growth on river sediments has been shown to increase a particles resistance to entrainment but the effects of such biostabilisation on microplastic flux has not yet been considered.  This is despite the fact that biofilm growth can change the buoyancy, surface characteristics and aggregation properties of the plastic particles  such as to cause them to be deposited rather than transported and hence increase their residence time.</p><p>In order to quantify biostabilisation processes on microplastic flux a two stage experimental programme was run.  During the first stage, bricks were submerged in a gravel-bed stream and biofilms allowed to colonise the bricks for 4 weeks.  The biofilm covered bricks were then extracted and placed within a re-circulating ‘incubator’ flume which had been divided into 9 smaller channels.  Within each of the 9 channels either a uniform sand, uniform gravel or a bimodal gravel mix were placed in Perspex boxes in the flume channels.  Each sediment type was seeded with either high density PVC microplastic nurdles (D<sub>50</sub> of 3mm, density of 1.33g/cm<sup>3</sup>) or polyester fibres (5 mm long, 0.5-1 mm wide, density of 1.38 g cm<sup>3</sup>), both at a concentration of 1%.  Blanks were also run where the sediment mixtures did not contain any micropalstics.  The flume was left to run with representative day/night cycles of lighting in order to let the biofilms colonise the test sediments for either 0 (control), 2, 4 or 6 weeks.  At the end of the chosen colonisation periods the persepx boxes containing the sediment were removed from the incubator flume and placed within a glass-sided, flow-recirculating flume (8.2m x 0.6m x 0.5m); this constituted the second stage of the experiment. During this stage the samples were exposed to a series of flow steps of increasing discharge designed to establish the entrainment threshold of the D<sub>50</sub> sediment grains. Entrainment thresholds were calculated for each of the growth stages such as to establish the effect of biostabilisation on sediment and microplastic flux.  Bedload and microplastic transport rates were also measured at every flow step to establish biostabilisation effects on overall fluxes. Finally, photographs of the sediment surface were taken at each flow step in order to estimate the percentage loss of biofilm from the surface. </p><p>Discussion concentrates on linking the changes in the degree of biofilm colonisation with the entrainment threshold of the sediment and the links between biofilm colonisation and the character of the bedload and microplastic flux.   The outcome of this research is pertinent to developing understanding surrounding the role biostabilisation has to play in the residence times of microplastics within fluvial systems.</p>

Physical and geochemical characteristics of suspended solids, Wilton Creek, Ontario

1981 ◽  
Vol 18 (8) ◽  
pp. 1365-1379 ◽  
Author(s):  
E. D. Ongley ◽  
M. C. Bynoe ◽  
J. B. Percival
Keyword(s):  
Contaminant Transport ◽  
Suspended Solids ◽  
Organic Content ◽  
Fluvial Systems ◽  
Transport Dynamics ◽  
Geochemical Properties ◽  
Partial Area ◽  
Sampling Program ◽  
Changing Role

To understand the nature of sediment-associated nutrient and contaminant transport dynamics in fluvial systems, a stormflow sampling program of suspended solids is reported for one water year in a representative rural diffuse source catchment of southeastern Ontario. Bulk samples of subsieve suspended solids were obtained using field-portable continuous-flow centrifuge apparatus. The physical and geochemical properties of suspended solids show no significant intersite differences over reaches of 1500–2000 m, yet display distinctive seasonal trends. Systematic seasonal changes in particle size, organic content, and Ca, P, Mn, Al, Ti, Fe, and K appear to reflect the changing role of partial area hydrology. Ca, P, and Mn are bioaccumulated by stream algae. Mineral signature is relatively constant over the year.

Vegetation growth in rivers: influences upon sediment and nutrient dynamics

2002 ◽  
Vol 26 (2) ◽  
pp. 159-172 ◽  
Author(s):  
Stewart J. Clarke
Keyword(s):  
Nutrient Dynamics ◽  
Frictional Resistance ◽  
Particulate Material ◽  
Fluvial System ◽  
Fluvial Systems ◽  
Vegetation Growth ◽  
Lowland Streams ◽  
Fine Sediments ◽  
Through Flow

Hydrological and geomorphological research in river environments has largely ignored the influence of instream vegetation growth; focusing rather on the role of riparian vegetation as a control on bank stability or as a potential buffer for dissolved and particulate material entering the channel from the hillslope. However, in many lowland streams instream vegetation may be abundant and reach high levels of biomass during the growing season. These instream plants (macrophytes) have a significant effect on flow, sediment and nutrient dynamics. Plant growth may cause increased frictional resistance to flow and through flow diversion may have a short-to medium-term influence on instream channel geomorphology. Additionally, this effect of plants upon flow velocities within the channel has an impact on sedimentation patterns. Rooted plants also function as a link between bed sediments and the water column, thus plants have a key role in the cycling of nutrients between these two components of the fluvial system. This, combined with the uptake and temporary storage of nutrients by the plants and the retention of fine sediments within dense plant stands, has the result that plants within rivers are an integral component of nutrient dynamics. A review of research on the role of macrophytes in fluvial system nutrient dynamics is presented and identifies the need for an increased understanding and recognition of the role of plants in the functioning of fluvial systems as a whole.

Lithological and structural controls on river profiles and networks in the northern Sierra Nevada (California, USA)

2019 ◽  
Vol 132 (3-4) ◽  
pp. 655-667 ◽  
Author(s):  
Emmanuel J. Gabet
Keyword(s):  
Sierra Nevada ◽  
Mountain Range ◽  
Late Cenozoic ◽  
Joint Spacing ◽  
Fluvial Systems ◽  
Structural Controls ◽  
Metasedimentary Rocks ◽  
River Profiles ◽  
Lithological Heterogeneity

Abstract In this study, the strong lithological heterogeneity of the northern Sierra Nevada (California, USA) is exploited to elucidate the role of lithology on river profiles and patterns at the mountain-range scale. The analyses indicate that plutonic, metavolcanic, and quartzite bedrock generally host the steepest river reaches, whereas gentle reaches flow across non-quartzite metasedimentary rocks and fault zones. In addition, the largest immobile boulders are often in the steepest reaches, suggesting that wide joint spacing plays a role in creating steep channels, and a positive relationship between boulder size and hillslope angle highlights the coupling of the hillslope and fluvial systems. With respect to river network configurations, dendritic patterns dominate in the plutonic bedrock, with channels aligned down the slope of the range; in contrast, river reaches in the metamorphic belts are mainly longitudinal and parallel to the structural grain. River profiles and patterns in the northern Sierra Nevada, therefore, bear a strong lithological imprint related to differential erosion. These observations indicate that attempts to infer uplift and tilting of the range based on the gradients and orientations of paleochannel remnants should first account for the effect of bedrock erodibility. Indeed, the differences in gradients of Tertiary paleochannel remnants used to argue for late Cenozoic uplift of the range can be wholly explained by differences in lithology.

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