Engineer pioneer plants respond to and affect geomorphic constraints similarly along water–terrestrial interfaces world‐wide

Corenblit, Dov Jean-François; Baas, Andreas; Balke, Thorsten; Bouma, Tjeerd J.; Fromard, François; Garófano‐Gómez, Virginia; González, Eduardo; Gurnell, Angela M.; Hortobágyi, Borbála; Julien, Frédéric; Kim, Dae Hyun; Lambs, Luc; Stallins, J. Anthony; Steiger, Johannes; Tabacchi, Eric; Walcker, Romain

doi:10.1111/geb.12373

Cited by 128 publications

(139 citation statements)

References 77 publications

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“…Changes in channel morphology due to pioneer vegetation dynamics have been documented in flume experiments [e.g., Hicks et al ., ; Tal and Paola , , ; Van Dijk et al ., ; Bertoldi et al ., ] and historical image analysis [e.g., Kondolf and Curry , ; Beechie et al ., ; Zanoni et al ., ; Bertoldi et al ., ; Picco et al ., ]. Links to field experiments and observations suggest that roots reinforce river sediment stability [e.g., Karrenberg et al ., ; Pollen , ; Edmaier et al ., ; Polvi et al ., ], while the flexible branches are able to protect against erosion during flooding and promote fluvial landform formation and associated ambient conditions for vegetation succession [e.g., Corenblit et al ., , ; Gurnell , , ; Gurnell et al ., ]. The engineering action of the pioneer plants, in association with fluvial landform evolution, has led to the notion of biogeomorphic succession [ Corenblit et al ., , , ], in which landform, vegetation type, and structure coevolve in time.…”

Section: Discussionmentioning

confidence: 99%

Groundwater controls on biogeomorphic succession and river channel morphodynamics

Bätz

Colombini

Cherubini

et al. 2016

J. Geophys. Res. Earth Surf.

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Biogeomorphic succession describes feedbacks between vegetation succession and fluvial processes that, at the decadal timescale, lead to a transition from bare river‐deposited sediment to fully developed riparian forest. Where the rate of stabilization by biogeomorphic succession is greater than the rate of ecological disturbance by fluvial processes, a river is likely to evolve into less dynamic states. While river research has frequently considered the physical dimensions of morphodynamics, less is known about physical controls on succession rates, and how these impact stream morphodynamics. Here we test the hypothesis that groundwater dynamics influence morphodynamics via the rate of biogeomorphic succession. We applied historic imagery analysis in combination with dendroecological methods for willows growing on young gravelly fluvial landforms along a steep groundwater‐depth gradient. We determined the following: floodplain morphodynamics and plant encroachment at the decadal scale, pioneer willow growth rates, and their relationships to hydrological variables. Willow growth rates were correlated with moisture availability (groundwater, discharge, and precipitation variability) in the downwelling reach, while little correlation was found in the upwelling reach. After a reduction in ecological disturbance frequency, data suggest that where groundwater is upwelling, biogeomorphic succession is fast, the engineering effect of vegetation is quickly established, and hence channel stability increased and active channel width reduces. Where groundwater is downwelling, deeper and more variable, biogeomorphic succession is slower, the engineering effect is reduced, and a wider active width is maintained. Thus, groundwater is an important control on biogeomorphic feedbacks intensity and, through the stabilizing effect of vegetation, may drive long‐term river channel morphodynamics.

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Section: Discussionmentioning

confidence: 99%

Groundwater controls on biogeomorphic succession and river channel morphodynamics

Bätz

Colombini

Cherubini

et al. 2016

J. Geophys. Res. Earth Surf.

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“…After 1946, photographs were taken approximately every five years. Changes in topography and vegetation canopy height during the biogeomorphic succession are indicated by the two curves (modified after Corenblit et al, 2015). There are more possibilities today to extract elevation from archived stereo-pairs that open opportunities to undertake retrospective diachronic analyses of natural environments, but the accuracy obtained will largely depend on the quality of the photographs.…”

Section: Introductionmentioning

confidence: 99%

Monitoring and reconstructing past biogeomorphic succession within fluvial corridors using stereophotogrammetry

Vautier

Corenblit

Hortobágyi

et al. 2016

Earth Surf Processes Landf

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“…Furthermore, scarps connect marsh platforms to tidal flats, and therefore represent a distinct break in elevation between the two. However, newly formed or seasonal marshes up to the establishment phase of development (Corenblit et al, 2015) have little impact on local topography and will not have formed platforms: they are unlikely to be detected by a topographic method. In this study, we therefore focus on the identification of scarps and steep channel banks as a precursor to the detection of platforms, referred to as step 4 in Fig.…”

Section: Scarp Routingmentioning

confidence: 99%

Unsupervised detection of salt marsh platforms: a topographic method

Goodwin¹,

Mudd²,

Clubb³

2017

Preprint

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Abstract.Salt marshes filter pollutants, protect coastlines against storm surges, and sequester carbon, yet are under threat from sea level rise and anthropogenic modification. The productivity and even survival of salt marsh vegetation depends on the topographic evolution of marsh platforms. Quantifying marsh platform topography is vital for improving the management of these valuable landscapes. Determining platform boundaries currently relies on supervised classification methods requiring near-infrared data 5 to detect vegetation, or demands labor-intensive field surveys and digitization. We propose a novel, unsupervised method to reproducibly isolate saltmarsh scarps and platforms from a DEM, referred to as Topographic Identification of Platforms (TIP).Field observations and numerical models show that saltmarshes mature into sub-horizontal platforms delineated by sub-vertical scarps: based on this premise, we identify scarps as lines of local maxima on a slope raster, then fill landmasses from the scarps upward, thus isolating mature marsh platforms. We test the TIP method using lidar-derived DEMs from six saltmarshes in 10England with varying tidal ranges and geometries, for which topographic platforms were manually distinguished from tidal flats. Agreement between manual and unsupervised classification exceeds 94% for DEM resolutions of 1 m, with all but one sites maintaining an accuracy superior to 90% for resolutions up to 3 m. For resolutions of 1 m, platforms detected with the TIP method are comparable in surface area to digitized platforms, and have similar elevation distributions. We also find that our method allows the accurate detection of local bloc failures as small as 3 times the DEM resolution. Detailed inspection 15 reveals that although tidal creeks were digitized as part of the marsh platform, unsupervised classification categorizes them as part of the tidal flat, causing an increase in false negatives and overall platform perimeter. This suggests our method would have increased accuracy if used in combination with existing creek detection algorithms. Fallen blocs and high tidal flat portions, associated with potential pioneer zones, may also be areas of discordance between our method and supervised mapping.Although pioneer zones prove difficult to classify using a topographic method, it also suggests that these transition areas 20 should be considered when analysing erosion and accretion processes, particularly in the case of incipient marsh platforms.Ultimately, we have shown that unsupervised classification of marsh platforms from high-resolution topography is possibleand sufficient to monitor and analyze topographic evolution.

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Engineer pioneer plants respond to and affect geomorphic constraints similarly along water–terrestrial interfaces world‐wide

Cited by 128 publications

References 77 publications

Groundwater controls on biogeomorphic succession and river channel morphodynamics

Groundwater controls on biogeomorphic succession and river channel morphodynamics

Monitoring and reconstructing past biogeomorphic succession within fluvial corridors using stereophotogrammetry

Unsupervised detection of salt marsh platforms: a topographic method

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