Your search keyword '"Shadrick, Jennifer R."' showing total 4 results

1. Sea-level rise will likely accelerate rock coast cliff retreat rates

Author

Shadrick, Jennifer R., Rood, Dylan H., Hurst, Martin D., Piggott, Matthew D., Hebditch, Bethany G., Seal, Alexander J., and Wilcken, Klaus M.

Published

2022

2. Constraints on long-term cliff retreat and intertidal weathering at weak rock coasts using cosmogenic 10Be, nearshore topography and numerical modelling.

Author

Shadrick, Jennifer R., Rood, Dylan H., Hurst, Martin D., Piggott, Matthew D., Wilcken, Klaus M., and Seal, Alexander J.

Subjects

*CLIFFS, *WEATHERING, *CHALK, *TOPOGRAPHY, *BEACHES, *ABSOLUTE sea level change, *LONG-Term Evolution (Telecommunications), *COASTS

Abstract

The white chalk cliffs on the south coast of England are one of the most iconic coastlines in the world. Rock coasts located in a weak lithology, such as chalk, are likely to be most vulnerable to climate-change-triggered accelerations in cliff retreat rates. In order to make future forecasts of cliff retreat rates as a response to climate change, we need to look beyond individual erosion events to quantify the long-term trends in cliff retreat rates. Exposure dating of shore platforms using cosmogenic radionuclide analysis and numerical modelling allows us to study past cliff retreat rates across the Late Holocene for these chalk coastlines. Here, we conduct a multi-objective optimisation of a coastal evolution model to both high-precision topographic data and 10Be concentrations at four chalk rock coast sites to reveal a link between cliff retreat rates and the rate of sea-level rise. Furthermore, our results strengthen evidence for a recent acceleration in cliff retreat rates at the chalk cliffs on the south coast of England. Our optimised model results suggest that the relatively rapid historical cliff retreat rates observed at these sites spanning the last 150 years last occurred between 5300 and 6800 years ago when the rate of relative sea-level rise was a factor of 5–9 times more rapid than during the recent observable record. However, results for these chalk sites also indicate that current process-based models of rock coast development are overlooking key processes that were not previously identified at sandstone rock coast sites. Interpretation of results suggest that beaches, cliff debris and heterogenous lithology play an important but poorly understood role in the long-term evolution of these chalk rock coast sites. Despite these limitations, our results reveal significant differences in intertidal weathering rates between sandstone and chalk rock coast sites, which helps to inform the long-standing debate of "wave versus weathering" as the primary control on shore platform development. At the sandstone sites, subaerial weathering has been negligible during the Holocene. In contrast, for the chalk sites, intertidal weathering plays an active role in the long-term development of the shore platform and cliff system. Overall, our results demonstrate how an abstract, process-based model, when optimised with a rigorous optimisation routine, can not only capture long-term trends in transient cliff retreat rates but also distinguish key erosion processes active in millennial-scale rock coast evolution at real-world sites with contrasting rock types. [ABSTRACT FROM AUTHOR]

Published

2023

3. Reply to: Sea-level rise may not uniformly accelerate cliff erosion rates.

Author

Shadrick, Jennifer R., Rood, Dylan H., and Hurst, Martin D.

Subjects

ABSOLUTE sea level change, CLIFFS, BEACH erosion, EROSION, COASTAL changes, CLIMATE change

Abstract

A response to a commentary by Dickson et al. on a previous study about the impact of sea-level rise on rock coast cliff erosion rates. The authors of the response agree with Dickson et al.'s observations that the model used in the study represents rock coast processes in a highly abstract manner and that the response to sea-level rise will not be consistent across different environments. However, they emphasize that their results still highlight the potential for rock coasts to be more sensitive to sea-level rise than previously thought, which calls for further research. The authors acknowledge the limitations of their model and the need for alternative models that can simulate rock coast evolution over shorter timescales. They also note that their study sites do not provide a direct analogue for future sea-level rise rates. The authors conclude that rock coasts should be included in climate change planning and that historical rates of erosion cannot be used to assess future risk. They hope that this conversation will lead to more research on worldwide coastal cliff response to sea-level rise. [Extracted from the article]

Published

2023

4. Multi-objective optimisation of a rock coast evolution model with cosmogenic 10Be analysis for the quantification of long-term cliff retreat rates.

Author

Shadrick, Jennifer R., Hurst, Martin D., Piggott, Matthew D., Hebditch, Bethany G., Seal, Alexander J., Wilcken, Klaus M., and Rood, Dylan H.

Subjects

*CLIFFS, *COASTS, *SEA level, *PARAMETER estimation, *LONG-Term Evolution (Telecommunications), *TIME series analysis, *TOPOGRAPHY

Abstract

This paper presents a methodology that uses site-specific topographic and cosmogenic 10Be data to perform multi-objective model optimisation of a coupled coastal evolution and cosmogenic radionuclide production model. Optimal parameter estimation of the coupled model minimises discrepancies between model simulations and measured data to reveal the most likely history of rock coast development. This new capability allows a time series of cliff retreat rates to be quantified for rock coast sites over millennial timescales. Without such methods, long-term cliff retreat cannot be understood well, as historical records only cover the past ∼150 years. This is the first study that has (1) applied a process-based coastal evolution model to quantify long-term cliff retreat rates for real rock coast sites and (2) coupled cosmogenic radionuclide analysis with a process-based model. The Dakota optimisation software toolkit is used as an interface between the coupled coastal evolution and cosmogenic radionuclide production model and optimisation libraries. This framework enables future applications of datasets associated with a range of rock coast settings to be explored. Process-based coastal evolution models simplify erosional processes and, as a result, often have equifinality properties, for example that similar topography develops via different evolutionary trajectories. Our results show that coupling modelled topography with modelled 10Be concentrations can reduce equifinality in model outputs. Furthermore, our results reveal that multi-objective optimisation is essential in limiting model equifinality caused by parameter correlation to constrain best-fit model results for real-world sites. Results from two UK sites indicate that the rates of cliff retreat over millennial timescales are primarily driven by the rates of relative sea level rise. These findings provide strong motivation for further studies that investigate the effect of past and future relative sea level rise on cliff retreat at other rock coast sites globally. [ABSTRACT FROM AUTHOR]

Published

2021