Sub‐arctic river bank dynamics and driving processes during the open‐channel flow period

Lotsari, Eliisa; Hackney, Christopher; Salmela, Jouni; Kasvi, Elina; Kemp, Justine; Alho, Petteri; Darby, Stephen E.

doi:10.1002/esp.4796

Cited by 14 publications

(23 citation statements)

References 47 publications

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“…Kasvi et al, 2013), and interactions between sediments frozen in winter period, influence of high-flow events caused by snowmelt, rain events and related mass failures, and groundwater seeping (cf. Lotsari et al, 2020).…”

Section: Meandering Rivers -Postglacial Landscapementioning

confidence: 99%

The evolution of meandering and anabranching rivers in postglacial and loess landscapes of Europe

Słowik

2022

The Holocene

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This study aims to explain the influence of sediments and landforms of postglacial and loess landscapes of Europe on processes forming meandering and anabranching rivers. Based on a literature review, sedimentary architecture, types and grain-size of deposits, and channel planform changes since the Late Pleniglacial were collected for extensive set of European rivers. These data were used to create a conceptual model explaining the evolution of meandering and anabranching rivers in both types of landscape. The present study shows that the inheritance of glacial and fluvioglacial landforms and sediments, and loess formation, influence types of processes forming anabranching and meandering rivers. Point bar accretion formed meandering rivers in postglacial zone whereas oblique accretion dominated in loess areas. Anabranching rivers of postglacial zone evolved through the formation of crevasse channels and meandering anabranches. Anabranching rivers of loess zone formed sustained bifurcations. Postglacial and loess rivers reacted differently to increased deposition and humidity in the Late-Holocene. Meanders of postglacial zone formed channel bars owing to increase in stream power and sediment load. In cases of flow energy decrease, and sustained upstream sediment delivery, they turned into anastomosing rivers. Anabranching rivers in ice-marginal valleys maintained its courses until hydro technical works in the 19th century. Low-energy meandering rivers of loess areas became wetlands owing to deposition of silts. High-energy meandering and anabranching rivers maintained the planforms throughout the Holocene. These findings need to be refined by detailed studies on the evolution of rivers in subarctic zone, and large rivers of Europe.

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Section: Meandering Rivers -Postglacial Landscapementioning

confidence: 99%

The evolution of meandering and anabranching rivers in postglacial and loess landscapes of Europe

Słowik

2022

The Holocene

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“…F I G U R E 4 Downstream variation in braidplain slope (after Weckwerth et al, 2017 and width of proximal, middle and distal parts of the Waldemar River outwash (a) and transverse profiles in its proximal (b), middle (c) and distal (d) parts (see profile location in Figures 2 and 10D) Changes in air temperature and precipitation totals affect the mass balance of the glaciers, which leads to changes in river discharge, influencing fluvial activity in the forefields of contemporary glaciers (Costard et al, 2003;Lotsari et al, 2019;Strzelecki et al, 2018). Many years' worth of research in the catchment of the Waldemar River provides an important contribution to the understanding of fluvial processes (including lateral erosion) taking place in the river catchment (Sobota, 2005(Sobota, , 2014.…”

Section: Glaciological and Hydro-meteorogical Researchmentioning

confidence: 99%

“…Active and passive controls on braidplain widening in the Arctic region are conditioned by mutual relationships between the discharge of F I G U R E 1 0 Distributary channel patterns and changes in the Waldemar River outwash feeding system: (a-c) active both northern (red arrow) and southern (yellow arrow) feeder channels and distributary streams active in northern and southern parts of the braidplain; (d) active southern (yellow arrow) feeder channel and distributary streams active in the southern part of the braidplain (for details see Figure 11). An aerial photograph taken in 1966 was not included in investigations on braidplain widening rate due to low image resolution [Colour figure can be viewed at wileyonlinelibrary.com] meltwater, braidplain morphology, sediment spatial distribution (Lotsari et al, 2019;Turowski et al, 2008). In terms of the lateral erosion of proglacial streams, its modelling was based usually on processes recognized over the course of a single melt season or as the result of short-term investigations (Fenn & Gurnell, 1987;Kociuba et al, 2014;Kociuba et al, 2019;Warburton, 1994).…”

Section: Controls and Feedbacks Involving Outwash Braidplain Dynamicsmentioning

confidence: 99%

Where will widening occur in an outwash braidplain? A new approach to detecting controls on fluvial lateral erosion in a glacierized catchment (north‐western Spitsbergen, Svalbard)

Weckwerth

Sobota

Greń

2021

Earth Surf Processes Landf

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The dynamics of fluvial system evolution depend on fluvial processes and their driving forces associated with climatic variations, which affect changes in the morphology of river channels and floodplains. Neither channel slope and morphology, nor the properties of fluvial sediment have previously been considered as determinants of active braidplain widening on outwash plains (formed from valley/alpine glaciers and confined by pre-existing topography) in the High Arctic region and in the forefields of retreating glaciers. Factors determining widening of braidplain activity of the Waldemar River outwash (north-western Spitsbergen, Svalbard) were analysed on the basis of geomorphological, sedimentological, glaciological and meteorological research, and indicate significant multiple correlations between meltwater discharge, precipitation, braidplain width, morphology of the braided channel and the textural features of braidplain deposits. The capability of multivariate adaptive regression splines to detect these relationships was described, and threshold values were identified. The results indicate that the rate of active braidplain widening is proportional to the meltwater outflow in proglacial rivers, which can decrease despite a growing rate of glacial ablation. A proposed model enables us to predict zones of braidplain prone to widening activity in the High Arctic (humid) outwash fans and plains as well as fans developed in arid intermountain basins. The necessary conditions to activate braidplain widening processes were (1) spatial changes in the outwash feeding system due to glacier terminus retreat and (2) crossing the thresholds in passive factors (S and d 50 ) controlling lateral erosion intensity. As a result, the braidplain reached a new dynamic equilibrium, in which high-magnitude-low-frequency extreme meltwater discharges were of particular importance in terms of braidplain dynamics and are the dominant controls on the pattern of distributary channels.

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“…However, the warming air temperatures could also have thawed permafrost and destabilised river banks, enabling more geomorphic work to be accomplished than if the ground remained frozen (c.f. Lotsari et al, 2020). Furthermore, it might be considered that the majority of Greenland deltas are aggrading (Bendixen et al 2017) due to enhanced meltwater generation and sediment mobilisation.…”

Section: Impact Of Glof Magnitude On Geomorphological Impactsmentioning

confidence: 99%

Geomorphological impacts of a glacier lake outburst flood in the high arctic Zackenberg River, NE Greenland

Ewertowski

Carrivick

2020

Journal of Hydrology

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Sub‐arctic river bank dynamics and driving processes during the open‐channel flow period

Cited by 14 publications

References 47 publications

The evolution of meandering and anabranching rivers in postglacial and loess landscapes of Europe

The evolution of meandering and anabranching rivers in postglacial and loess landscapes of Europe

Where will widening occur in an outwash braidplain? A new approach to detecting controls on fluvial lateral erosion in a glacierized catchment (north‐western Spitsbergen, Svalbard)

Geomorphological impacts of a glacier lake outburst flood in the high arctic Zackenberg River, NE Greenland

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