4.5 Article

The morphology of fluvial-tidal dunes: Lower Columbia River, Oregon/Washington, USA

Journal

EARTH SURFACE PROCESSES AND LANDFORMS
Volume 47, Issue 8, Pages 2079-2106

Publisher

WILEY
DOI: 10.1002/esp.5364

Keywords

fluvial-tidal bedforms; low-angle dunes; Lower Columbia River; superimposed bedforms; tidal bedforms

Funding

  1. UK Natural Environment Research Council (NERC) [NE/H007954/1, NE/H006524/1, NE/H007261/1, NE/H00582X/1]
  2. Jack and Richard Threet Chair in Sedimentary Geology
  3. ExxonMobil
  4. NERC [NE/H006524/1, NE/H00582X/1, NE/H007261/1, NE/H007954/1] Funding Source: UKRI

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This article quantifies changes in primary dune morphology of the mesotidal Lower Columbia River (LCR), USA, and identifies different types of dunes and the mechanisms that influence their morphology.
This article quantifies changes in primary dune morphology of the mesotidal Lower Columbia River (LCR), USA, through similar to 90 river kilometres of its fluvial-tidal transition at low-river stage. Measurements were derived from a multibeam echo sounder dataset that captured bedform dimensions within the thalweg (>= 9 m depth; H=H-max >= 0.7) of the LCR main channel. Measurements revealed two categories of dunes: (i) fine to medium sand 'fluvial-tidal to tidal' (upstream-oriented, simple, and twodimensional) low-angle dunes (heights approximate to 0.3-0.8 m; wavelengths approximate to 10-25 m; mean lee-angles approximate to 7 degrees -11 degrees), and (ii) medium to coarse sand 'fluvial' (downstream-oriented, compound, and 2.5-dimensional to three-dimensional) low-angle dunes (heights similar to 1.5-3 m; wavelengths approximate to 60-110 m; mean lee-angles approximate to 11 degrees -18 degrees). At low-river stage, where H/H-max similar to 0.7, approximately 86% of the fluvial-tidal transition is populated by 'fluvial' dunes, whilst similar to 14% possesses 'fluvial-tidal to tidal' dunes that form in the downstream-most reaches. Thus, throughout the majority of the deepest channel segments of the fluvial-tidal transition, seaward-oriented river and ebb-tidal currents govern dune morphology, whilst strong bidirectional tidal-current influence is restricted to the downstream most reaches of the transition zone. Two mechanisms are reasoned to explain dune low-angle character: (1) high-suspended sediment transport near peak tidal-currents that lowers the leeside-angles of 'fluvial-tidal to tidal' dunes, and (2) superimposed bedforms that erode the crests, leesides, and stoss-sides, of 'fluvial' dunes, which results in the reduction of leeside-angles. Fluctuations in river discharge create a 'dynamic morphology reach' at depths where H/H-max >= 0.7, which spans river kilometres 12-40 and displays the greatest variation in dune morphology. Similar channel reaches likely exist in fluvial-tidal transitions with analogous physical characteristics as the LCR and may provide a distinct signature for the fluvial-tidal transition zone.

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