Controls on the distribution of cosmogenic &amp;lt;sup&amp;gt;10&amp;lt;/sup&amp;gt;Be across shore platforms

Hurst, Martin D.; Rood, Dylan H.; Ellis, Michael A.

doi:10.5194/esurf-5-67-2017

Cited by 25 publications

(56 citation statements)

References 56 publications

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“…At present, the only way to verify the accuracy of models of long-term change of fully erosional rocky coasts is via cosmogenic radionuclide exposure dating 8,13 . Calculation of isotope concentrations across an active shore platform allows previous position(s) of the cliff to be reconstructed from their timing of exposure of the foreshore.…”

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confidence: 99%

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Cosmogenic exposure dating reveals limited long-term variability in erosion of a rocky coastline

et al. 2020

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Predicted sea-level rise and increased storminess are anticipated to lead to increases in coastal erosion. However, assessing if and how rocky coasts will respond to changes in marine conditions is difficult due to current limitations of monitoring and modelling. Here, we measured cosmogenic 10 Be concentrations across a sandstone shore platform in North Yorkshire, UK, to model the changes in coastal erosion within the last 7 kyr and for the first time quantify the relative long-term erosive contribution of landward cliff retreat, and downwearing and stripping of rock from the shore platform. The results suggest that the cliff has been retreating at a steady rate of 4.5 ± 0.63 cm yr −1 , whilst maintaining a similar profile form. Our results imply a lack of a direct relationship between relative sea level over centennial to millennial timescales and the erosion response of the coast, highlighting a need to more fully characterise the spatial variability in, and controls on, rocky coast erosion under changing conditions.

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confidence: 99%

“…They have also simplified the potential role of mesoscale (10 −1 -10 0 m) block detachment stripping material from the foreshore 18,19 . While the potentially highly important role of some of these factors in reconstructing the rate and nature of rocky coast erosion has been conceptually demonstrated 13 , this has yet to be explored with field data.…”

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Cosmogenic exposure dating reveals limited long-term variability in erosion of a rocky coastline

et al. 2020

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“…Measuring sea cliff erosion presents a wide range of techniques. Those techniques vary significantly in terms of the following: (i) accuracy, which range from field observation and "expert" estimates May and Hansom (2003) of volume loss to precise measurements using techniques such as lidar (e.g., Dewez et al, 2013); (ii) time period surveyed, which range from twenty minutes (e.g., Williams et al, 2018) to thousands of years (e.g., Choi et al, 2012;Hurst et al, 2017;Regard et al, 2012); and (iii) the spatial extent along the coast, which ranges from tens of meters (e.g., Letortu et al, 2015) to kilometers (e.g., Hapke et al, 2009). Moreover, these measurements can be divided into three classes of methods:…”

Section: Measurement Descriptionmentioning

confidence: 99%

“…The tidal range describes the variation in the height of the water surface. One consequence is that the cliff and platform undergo cyclic wetting and drying that weakens and erodes the constituting rocks (Kanyaya and Trenhaile, 2005).…”

Section: Tidesmentioning

confidence: 99%

“…Hence, platforms can be regarded as natural defences against wave attack of the cliff. The shore platform evolves under marine forcing like wave agitation and associated shear stress (e.g., Sallenger Jr et al, 2002;Stephenson and Kirk, 2000;Sunamura, 1992;Trenhaile, 2008Trenhaile, , 2009, or tide-induced wetting and drying cycles (Kanyaya and Trenhaile, 2005;Stephenson and Kirk, 2000). The second group of drivers is rock mass properties, which are believed to have a strong influence on cliff evolution (Mortimore and Duperret, 2004).…”

Section: Introductionmentioning

confidence: 99%

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GlobR2C2 (Global Recession Rates of Coastal Cliffs): a global relational database to investigate coastal rocky cliff erosion rate variations

Prémaillon¹,

Regard

Dewez

et al. 2018

Earth Surf. Dynam.

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Abstract. Rocky coast erosion (i.e., cliff retreat) is caused by a complex interaction of various forcings that can be marine, subaerial or due to rock mass properties. From Sunamura's seminal work in 1992, it is known that cliff retreat rates are highly variable over at least four orders of magnitude, from 1 to 10 mm yr−1. While numerous local studies exist and explain erosion processes at specific sites, there is a lack of knowledge at the global scale. In order to quantify and rank the various parameters influencing erosion rates, we compiled existing local studies into a global database called GlobR2C2 (which stands for Global Recession Rates of Coastal Cliffs). This database reports erosion rates from publications, cliff setting and measurement specifications; it is compiled from peer-reviewed articles and national databases. In order to be homogeneous, marine and climatic forcings were recorded from global models and reanalyses. Currently, GlobR2C2 contains 58 publications that represent 1530 studied cliffs and more than 1680 estimated erosion rate. A statistical analysis was conducted on this database to explore the links between erosion rates and forcings at a global scale. Rock resistance, inferred using the criterion of Hoek and Brown (1997), is the strongest signal explaining variation in erosion rate. Median erosion rates are 2.9 cm yr−1 for hard rocks, 10 cm yr−1 for medium rocks and 23 cm yr−1 for weak rocks. Concerning climate, only the number of frost days (number of day per year below 0 ∘C) for weak rocks shows a significant, positive, trend with erosion rate. The other climatic and marine forcings do not show any clear or significant relationship with cliff retreat rate. In this first version, GlobR2C2, with its current encompassing vision, has broad implications. Critical knowledge gaps have come to light and prompt a new coastal rocky shore research agenda. Further study of these questions is paramount if we one day hope to answer questions such as what the coastal rocky shore response to sea-level rise or increased storminess may be.

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Identifying mechanisms of shore platform erosion using Structure‐from‐Motion (SfM) photogrammetry

Swirad

Rosser

Brain

2019

Earth Surf Processes Landf

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Shore platforms control wave energy transformation which, in turn, controls energy delivery to the cliff toe and nearshore sediment transport. Insight into shore platform erosion rates has conventionally been constrained at millimetre‐scales using micro‐erosion metres, and at metre‐scales using cartographic data. On apparently slowly eroding coasts, such approaches are fundamentally reliant upon long‐term observation to capture emergent erosion patterns. Where in practise timescales are short, and where change is either below the resolution or saturates the mode of measurement, the collection of data that enables the identification of the actual mechanisms of erosion is hindered. We developed a method to monitor shore platform erosion at millimetre resolution within metre‐scale monitoring plots using Structure‐from‐Motion photogrammetry. We conducted monthly surveys at 15 0.25 m2 sites distributed across the Hartle Loup platform in North Yorkshire, UK, over one year. We derived topographic data at 0.001 m resolution, retaining a vertical precision of change detection of 0.001 m. We captured a mean erosion rate of 0.528 mm yr‐1, but this varied considerably both across the platform and through the year. We characterized the volume and shape of eroded material. The detachment volume–frequency and shape distributions suggest that erosion happens primarily via removal of shale platelets. We identify that the at‐a‐point erosion rate can be predicted by the distance from the cliff and the tidal level, whereby erosion rates are higher closer to the cliff and at locations of higher tidal duration. The size of individual detachments is controlled by local micro‐topography and rock structure, whereby larger detachments are observed on more rough sections of the platform. Faster erosion rates and larger detachments occur in summer months, rather than in more energetic winter conditions. These results have the potential to form the basis of improved models of how platforms erode over both short‐ and long‐timescales. © 2019 John Wiley & Sons, Ltd.

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Controls on the distribution of cosmogenic <sup>10</sup>Be across shore platforms

Cited by 25 publications

References 56 publications

Cosmogenic exposure dating reveals limited long-term variability in erosion of a rocky coastline

Cosmogenic exposure dating reveals limited long-term variability in erosion of a rocky coastline

GlobR2C2 (Global Recession Rates of Coastal Cliffs): a global relational database to investigate coastal rocky cliff erosion rate variations

Identifying mechanisms of shore platform erosion using Structure‐from‐Motion (SfM) photogrammetry

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