Physical and biological dynamic coastal processes and their role in coastal recovery (BLUE-coast)
Lead Research Organisation:
NATIONAL OCEANOGRAPHY CENTRE
Department Name: Science and Technology
Abstract
The BLUE-coast consortium addresses NERC highlight topic B, Coastal morphology: coastal sediment budgets and their role in coastal recovery. This project will adopt a holistic and multidisciplinary approach, combining the expertise of biologists, coastal engineers, geologists, geomorphologists and oceanographers with complementary experimental (field and laboratory) and numerical skills, to understand what processes control the coastal system dynamics and answer the relevant scientific questions.
BLUE-coast will explicitly address uncertainties in the prediction of medium-term (years) and long -term (decadal and longer) regional sediment budgets and better understand morphological change and how the coast recovers after sequences of events, such as storms by: (i) improving representation of both transportable and source material within the coastal zone within models; (ii) establishing how transportable material is mediated by the ecological system using exemplar habitats representative of the UK coastal zone; (iii) assessing sensitivities of this mixed-sediment physical and biological system to possible changes in external forcing, including the combined impact of multiple variables and sequences of events, with the goal of understanding the internal dynamics of the system (e.g. nonlinearities, critical thresholds, tipping points, precursors and antecedent conditions) in parallel with assessments of behavioural uncertainties, and (iv) reduce uncertainties in medium to long -term prediction of regional sediment budgets and morphological change.
Project Overview: the scope of the Highlight Topic sets a requirement for quantitative knowledge on both physical and biological dynamic coastal processes in order to improve hydrodynamic model predictions of regional sediment budgets and morphological change. To deliver an integrated, holistic and cost effective response, our main activities will combine (i) a detailed study of representative shelf sea landscapes that spans the full variety of organism-sediment conditions typically observed in temperate coasts, with (ii) in situ validation studies of key processes, and (iii) manipulative laboratory and field experiments aimed at unambiguously identifying causal relationships and establishing generality, and (iv) integration of new understanding of controls and effects on coastal morphodynamics at regional scales and under environmental forcing. By undertaking a substantial element of in situ observation and process studies, we will directly quantify the effect of antecedent conditions on coastal erosion and recovery, the effect of biota on mediating sediment fluxes and pathways and the effect of event sequencing on coastal erosion and recovery, across a range of geographically significant sediment habitats. These data will act as calibration and validation datasets for existing and innovative numerical models that will be able to simulate the coastal morphological consequences of key biological and physical drivers, alone and in combination. We will gain mechanistic understanding and achieve generality by performing carefully controlled experiments, generating different flow regimes using flumes, tracking changes during natural events using state-of-the-art field measurement technology and, in the laboratory, using intact sediments and sediment communities exposed to anticipated future conditions (warming, ocean acidification, nutrient loading). As it is not feasible to quantify all the relevant morphodynamic processes at high spatial resolution across the entire UK coast, our approach is to address the principal objectives through 4 interdisciplinary workpackages that follow a logical progression of scientific themes.
BLUE-coast will explicitly address uncertainties in the prediction of medium-term (years) and long -term (decadal and longer) regional sediment budgets and better understand morphological change and how the coast recovers after sequences of events, such as storms by: (i) improving representation of both transportable and source material within the coastal zone within models; (ii) establishing how transportable material is mediated by the ecological system using exemplar habitats representative of the UK coastal zone; (iii) assessing sensitivities of this mixed-sediment physical and biological system to possible changes in external forcing, including the combined impact of multiple variables and sequences of events, with the goal of understanding the internal dynamics of the system (e.g. nonlinearities, critical thresholds, tipping points, precursors and antecedent conditions) in parallel with assessments of behavioural uncertainties, and (iv) reduce uncertainties in medium to long -term prediction of regional sediment budgets and morphological change.
Project Overview: the scope of the Highlight Topic sets a requirement for quantitative knowledge on both physical and biological dynamic coastal processes in order to improve hydrodynamic model predictions of regional sediment budgets and morphological change. To deliver an integrated, holistic and cost effective response, our main activities will combine (i) a detailed study of representative shelf sea landscapes that spans the full variety of organism-sediment conditions typically observed in temperate coasts, with (ii) in situ validation studies of key processes, and (iii) manipulative laboratory and field experiments aimed at unambiguously identifying causal relationships and establishing generality, and (iv) integration of new understanding of controls and effects on coastal morphodynamics at regional scales and under environmental forcing. By undertaking a substantial element of in situ observation and process studies, we will directly quantify the effect of antecedent conditions on coastal erosion and recovery, the effect of biota on mediating sediment fluxes and pathways and the effect of event sequencing on coastal erosion and recovery, across a range of geographically significant sediment habitats. These data will act as calibration and validation datasets for existing and innovative numerical models that will be able to simulate the coastal morphological consequences of key biological and physical drivers, alone and in combination. We will gain mechanistic understanding and achieve generality by performing carefully controlled experiments, generating different flow regimes using flumes, tracking changes during natural events using state-of-the-art field measurement technology and, in the laboratory, using intact sediments and sediment communities exposed to anticipated future conditions (warming, ocean acidification, nutrient loading). As it is not feasible to quantify all the relevant morphodynamic processes at high spatial resolution across the entire UK coast, our approach is to address the principal objectives through 4 interdisciplinary workpackages that follow a logical progression of scientific themes.
Planned Impact
Our research will deliver improved predictions of coastal erosion in different coastal habitats, along with modelling tools to better understand coastal recovery and to understand the implications of climate change for coastal systems. We will provide evidence-based advice for different options for coastal protection and management. We will engage with stakeholders at the national (e.g. Defra, Environment Agency), regional (e.g. District Councils, Internal Drainage Boards, Regional Flood and Coastal Committees) and local level (e.g. community groups, coastal flood fora, the public) using workshops, web-based material, newsletters and an end-of-project roadshow. We will also engage with non-government organisations associated with coastal land management (e.g. National Trust, Crown Estate) or with interests in protecting specific coastal marine species or habitats (e.g. Wildlife Trusts, RSPB). We will produce a series of short accessible videos having adopted the technique successfully before. Management of the project's impacts will be under the newly created Institute for Sustainable Coasts and Oceans at Liverpool. We will produce an annual project newsletter and the communications teams of all institutes will be proactive with regular press releases for both national and regional media opportunities, especially focusing on local media in the three 'coastal type' areas where our fieldwork activities will take place. We will develop a programme of engagement based around interactive activities at community events, visits and school project work and will target 'hard to reach' sectors of the community through exploring partnerships with organizations such as the Active Learning Partnership.
We will disseminate our final results at a mobile roadshow that spend a day at a key location within each Regional Flood and Coastal Committee. This "Moving Coastlines Show" will culminate close to London where we will invite national level stakeholders (e.g. Defra, Environment Agency, Natural England) and stage a question-time style debate. The KE officer (NOC) will work closely with the Knowledge Exchange expertise at each institute to monitor and ensure timely delivery of outreach and impact. Quantitative measures of success will include numbers of people participating in engagement events; participation in our "Moving Coastlines Show"; usage of our online materials; and by using YouTube Analytics for our public outreach material, as well as the number of media articles generated. Policy impact will be gauged by the influence that our work has on strategic environmental planning, but success in this area would be maximized by changes in coastal planning attributable to our project, particularly in the guidance for Shoreline Management Plans.
We will disseminate our final results at a mobile roadshow that spend a day at a key location within each Regional Flood and Coastal Committee. This "Moving Coastlines Show" will culminate close to London where we will invite national level stakeholders (e.g. Defra, Environment Agency, Natural England) and stage a question-time style debate. The KE officer (NOC) will work closely with the Knowledge Exchange expertise at each institute to monitor and ensure timely delivery of outreach and impact. Quantitative measures of success will include numbers of people participating in engagement events; participation in our "Moving Coastlines Show"; usage of our online materials; and by using YouTube Analytics for our public outreach material, as well as the number of media articles generated. Policy impact will be gauged by the influence that our work has on strategic environmental planning, but success in this area would be maximized by changes in coastal planning attributable to our project, particularly in the guidance for Shoreline Management Plans.
Publications
Billson O
(2020)
In-situ Observations of Infragravity Response during Extreme Storms on Sand and Gravel Beaches
in Journal of Coastal Research
Guerrero Q
(2021)
Small-scale bedforms and associated sediment transport in a macro-tidal lower shoreface
in Continental Shelf Research
Phillips B
(2020)
Modeling Impact of Intertidal Foreshore Evolution on Gravel Barrier Erosion and Wave Runup with XBeach-X
in Journal of Marine Science and Engineering
Solan M
(2023)
Biological-physical interactions are fundamental to understanding and managing coastal dynamics.
in Royal Society open science
Thorne P
(2021)
Acoustic scattering characteristics and inversions for suspended concentration and particle size above mixed sand and mud beds
in Continental Shelf Research
Wei X
(2021)
Unraveling Interactions between Asymmetric Tidal Turbulence, Residual Circulation, and Salinity Dynamics in Short, Periodically Weakly Stratified Estuaries
in Journal of Physical Oceanography
Wei X
(2022)
Salt Intrusion as a Function of Estuary Length in Periodically Weakly Stratified Estuaries
in Geophysical Research Letters
Description | The BLUEcoast project has brought together a range of approaches to characterise the interactions between physical and biological processes: field observations, including the development of new survey and monitoring methods; laboratory testing of response to environmental and climate change; numerical simulations. The integration of these methods is effective for identifying the key processes that control the dynamics of certain types of coastal and estuarine systems. As a result of BLUEcoast, we know biodiversity-environment interactions are important. Coastal protection is dependent on biology as well as the physical component. Context matters! The solution working in one place won't necessarily work elsewhere. Coastal systems are dynamics with distinct yet overlapping scales for different physical and biological components. These multiple scales control coastal response, recovery, and resilience. We have identified that there is a time to emergence of the climate signal on different coasts. Decadal variability in wave forcing is more important in driving medium-term coastal dynamics than sea-level rise - it is then unlikely we will be able to isolate coastal erosion caused by sea-level rise until after 2050. Even under the most extreme storms sand and gravel are not 'lost' from the nearshore system. Responses of estuaries to natural and anthropogenic changes are strongly dependent on the geometric feature of the estuarine system. Remote sensing data and models can effectively project the outcomes from storms and alterative coastal management interventions. Spanning gravel to vegetated coastal systems, vegetation and organic matter play a key role in determining budget and therefore response and sensitivity to change. BLUEcoast has significantly advanced our ability to obtain sediment budget data - as moderated by vegetation, organic matter and EPS. We have new methods to map the amount of sand, gravel and fine sediment budgets. Order of magnitude estimates of sediment passing around coastal headlands can be predicted based on knowledge of wave climate, sediment cover, and headland geometry. We know that many coastal embayments are not closed and do exchange sediments with neighbouring embayments. An empirical relationship between beach volume and soft cliff annual recession rate is now available to inform triggering thresholds for intervention. Waves do not always result in loss of sediment. We have better biophysical modelling. Structure-from-motion can be successfully used as a low-cost monitoring tool for coastal erosion, for example of saltmarshes. Storm surveys and radar monitoring provide effective assessment of coastal change and coastal hydrodynamics. |
Exploitation Route | Our findings can be taken forward by (i) policy makers, coastal engineers and practitioners to improve coastal risk management (ii) coastal consultants and engineers to design and deliver more effective coastal protection working with nature (iii) organisations with coastal assets. For example, our findings on the impact of curvature on reinforcing shoals/flats would be of interest to port authorities where the navigation channel is curved (e.g. Liverpool). In Liverpool, observations of channel bathymetry and migration are consistent with the mechanism we highlighted. |
Sectors | Energy Environment Transport |
URL | https://projects.noc.ac.uk/bluecoast/ |
Description | Results from the BLUEcoast project have been cited in the practitioner guide for sediment budget analysis produced by the EA (Environment Agency, Sediment budget analysis: practitioner guide, Report: SC150011). |
First Year Of Impact | 2018 |
Sector | Environment |
Impact Types | Policy & public services |
Description | Coastal Hazards: Multi-hazard controls on Flooding and Erosion (CHAMFER) |
Amount | £2,713,354 (GBP) |
Funding ID | NE/W004992/1 |
Organisation | Natural Environment Research Council |
Sector | Public |
Country | United Kingdom |
Start | 03/2022 |
End | 03/2027 |
Description | Gravel barrier resilience in a changing climate (#gravelbeach) |
Amount | £2,676,195 (GBP) |
Funding ID | 2,676,195 |
Organisation | Natural Environment Research Council |
Sector | Public |
Country | United Kingdom |
Start | 01/2024 |
End | 01/2028 |
Description | Resilient coasts: optimising co-benefit solutions (Co-Opt) |
Amount | £562,931 (GBP) |
Funding ID | NE/V016423/1 |
Organisation | Natural Environment Research Council |
Sector | Public |
Country | United Kingdom |
Start | 11/2021 |
End | 10/2024 |
Title | FVCOM Model setup at UK scale |
Description | Dataset summarising FVCOM setup for UK scale implementation. Data submitted to BODC |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | Dataset used in Wei et al., 2019 paper in Ocean Modelling. |
Title | Hydrodynamic and sediment transport observations for subtidal channel in Morecambe Bay |
Description | 4 datasets relating to observations of hydrodynamics and sediment transport for a campagin in Winter 2019 submitted to BODC. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | Datasets used in ongoing research at NOC part as part of the BLUEcoast project to assess the role of moderate storms on intertidal flats. |
Title | Hydrodynamic and sediment transport observations on Morecambe Bay intertidal flats (summer) |
Description | 18 datasets relating to observations of hydrodynamics and sediment transport for a campagin in summer 2018 submitted to BODC. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | Datasets used in ongoing research at NOC part as part of the BLUEcoast project to assess the role of moderate storms on intertidal flats. |
Title | Hydrodynamic and sediment transport observations on Morecambe Bay intertidal flats (winter) |
Description | 23 datasets relating to observations of hydrodynamics and sediment transport for a campagin in summer 2018 submitted to BODC. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | Datasets used in ongoing research at NOC part as part of the BLUEcoast project to assess the role of moderate storms on intertidal flats. |
Title | Hydrodynamic and sediment transport observations on lower shoreface of Perranporth Beach |
Description | 6 datasets relating to observations of hydrodynamics and sediment transport on the lower shoreface of Perranporth Beach for a campagin in January-March 2017. SUbmitted to BODC. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | Datasets used in ongoing research at NOC part as part of the BLUEcoast project to quantify sediment fluxes to/from lower shoreface. |
Title | Model outputs of Wei et al. (2022): "Salt intrusion as a function of estuary length in periodically weakly stratified estuaries", published in Geophysical research Letters. |
Description | The .mat file includes all model data used in the study "Salt intrusion as a function of estuary length in periodically weakly stratified estuaries", published in Geophyscial Research Letters, 2022. The .txt file contains description of all physical variables contained in the .mat file. |
Type Of Material | Database/Collection of data |
Year Produced | 2022 |
Provided To Others? | Yes |
URL | https://zenodo.org/record/5500231 |
Title | Particle size analysis of sediment samples from BLUEcoast project |
Description | Particle size analysis of sediment samples from BLUEcoast project. Sediment samples from Blackwater estuary, Perranporth beach lower shoreface, and Morecambe Bay. Data submitted to BODC. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | n/a |
Title | XRD analysis of sediment samples |
Description | XRD analysis of sediment samples from the BLUEcoast project. Samples include sediments from the Blackwater estuary, Perranporth Beach, and Morecambe Bay. Dataset submitted to BODC. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | n/a |
Title | XRF analysis of sediment samples |
Description | XRF analysis of sediment samples from Morecambe Bay. Data submitted to BODC. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
Impact | n/a |
Description | Collaboration with CSIC-ICM in Barcelona |
Organisation | Spanish National Research Council (CSIC) |
Country | Spain |
Sector | Public |
PI Contribution | We provided access to data collected during the BLUEcoast project. |
Collaborator Contribution | The partners at CSIC included a PhD student who processed and analysed datasets collected during the BLUEcoast project. The resulting study was included in a doctoral thesis defended early 2019. |
Impact | Thesis by Queralt Querrero. Paper led by Queralt Guerrero published in Continental Shelf Research in 2021 |
Start Year | 2017 |
Description | Collaboration with H Schuttelaars |
Organisation | Delft University of Technology (TU Delft) |
Country | Netherlands |
Sector | Academic/University |
PI Contribution | Idealised modelling of estuarine dynamics. |
Collaborator Contribution | Expertise in idealised modelling. |
Impact | Paper in Journal of Physical Oceanography by Wei et al., 2021. |
Start Year | 2019 |
Description | Interview on BBC Radio Hereford and Worcester |
Form Of Engagement Activity | A broadcast e.g. TV/radio/film/podcast (other than news/press) |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Public/other audiences |
Results and Impact | Interview on BBC radio Hereford and Worcester part of the 'Ask Oscar' feature where listeners ask questions and then the producer (Oscar) goes away and finds experts to answer the question. Question was "what causes waves in the sea?" |
Year(s) Of Engagement Activity | 2022 |