Your search keyword '"Hansen, Jeff E."' showing total 9 results

1. Dynamics of the Wave‐Driven Circulation in the Lee of Nearshore Reefs.

Author

da Silva, Renan F., Hansen, Jeff E., Lowe, Ryan J., Rijnsdorp, Dirk P., and Buckley, Mark L.

Subjects

REEFS, BEACHES, WATER levels, WATER waves, MOUNTAIN wave, COASTS, EROSION

Abstract

Nearshore rocky reefs with scales of order 10–100 m are common along the world's coastline and often shape wave‐driven hydrodynamics and shoreline morphology in their lee. The interaction of waves with these reefs generally results in either two or four‐cell mean circulation systems (2CC and 4CC, respectively), with diverging flows behind the reefs and at the shoreline in the 2CC case and flows that diverge in the lee and converge at the shoreline in the 4CC case. By applying a phase‐resolving wave‐flow model to conduct a detailed analysis of mean momentum balances for waves interacting with nearshore reefs, we develop an understanding of the drivers of 2CC and 4CC flow dynamics and how they vary for different reef geometries and wave and water level conditions. The 2CC or 4CC patterns were primarily driven by alongshore pressure gradients toward the exposed (nonreef fronted) or reef‐fronted beach. These alongshore pressure gradients were dependent on the cross‐shore setup dynamics governed by the balance between pressure (i.e., related to the setup) and radiation stress gradients, and mean bottom stresses exerted on the water column. If shoreline wave setup in the lee of the reef was less than the exposed beach, a 4CC pattern developed with convergent flow at the shoreline in the lee of the reef; otherwise, a 2CC emerged with divergent flow at the shoreline. Across the parameter space investigated, reef roughness, distance to the shoreline, and beach slope were the three parameters most likely to change the flow patterns between 2CC and 4CC. Plain Language Summary: Small‐scale nearshore rocky reefs are found worldwide along a variety of sandy and rocky coastlines. Wave breaking over small reefs drives mean alongshore circulation patterns in their lee that may cause shoreline accretion or erosion. In this study, we apply a wave‐flow model to investigate the physical drivers of the mean currents in the lee of small reefs. The alongshore circulation was primarily driven by the differences of the mean water levels between the lee and the adjacent nonreef fronted beaches. Mean water levels increased by wave breaking; however, the onshore‐directed mean flows over the reef created offshore‐directed bottom stresses that reduced the mean water levels in the reef lee. If the shoreline mean water levels in the lee were less than the adjacent beach, alongshore currents that converged from the adjacent beaches toward the reefs were developed. If the shoreline mean water levels in the lee of the reef exceeded the adjacent beach, alongshore currents that diverged from the reef toward the adjacent beach occurred. The improved understanding of the circulation drivers developed in this study enhances our ability to characterize and predict wave‐driven flows in small‐scale nearshore reef systems. Key Points: Phase‐resolved model simulations were used to understand circulation patterns that occur in the lee of small‐scale reefsTwo‐cell and four‐cell circulation patterns were primarily driven by alongshore pressure gradients, which depend on the setup dynamicsA four‐cell pattern generally developed if the shoreline wave setup in the lee of the reef was less than the adjacent nonreef fronted beach [ABSTRACT FROM AUTHOR]

Published

2023

2. Wave‐Driven Hydrodynamic Processes Over Fringing Reefs With Varying Slopes, Depths, and Roughness: Implications for Coastal Protection.

Author

Buckley, Mark L., Lowe, Ryan J., Hansen, Jeff E., van Dongeren, Ap R., Pomeroy, Andrew, Storlazzi, Curt D., Rijnsdorp, Dirk P., da Silva, Renan F., Contardo, Stephanie, and Green, Rebecca H.

Subjects

BEACHES, REEFS, MOUNTAIN wave, CORAL reefs & islands, DRAG coefficient, DRAG force, WATER waves, WATER levels

Abstract

Wave breaking on the steep fore‐reef slopes of shallow fringing reefs can be effective at dissipating incident sea‐swell waves prior to reaching reef shorelines. However, wave setup and free infragravity waves generated during the sea‐swell breaking process are often the largest contributors to wave‐driven water levels (wave runup) at the shoreline. Laboratory flume experiments and a two‐dimensional vertical phase‐resolving nonhydrostatic wave‐flow model, which includes a canopy model to predict drag forces generated by roughness elements, were used to investigate wave‐driven water levels for along‐shore uniform fringing reefs. In contrast to many previous studies, both the laboratory experiment and the numerical model account for the effects of large bottom roughness. The numerical model reproduced the observations of the wave transformation and runup over both smooth and rough reef profiles. The numerical model was then extended to quantify the influence of reef geometry and compared to simulations of plane beaches lacking a reef. For a fixed offshore forcing condition, the fore‐reef slope controlled wave runup on reef‐fronted beaches, whereas the beach slope controlled wave runup on plane beaches. As a result, the coastal protection utility of reefs is dependent on these slopes. For our examples, with a fore‐reef slope of 1/5 and a 500 m prototype reef flat length, a beach slope of ∼1/30 marked the transition between the reef providing runup reduction for steeper beach slopes and enhancing wave runup for milder slopes. Roughness coverage, spacing, dimensions, and drag coefficient were investigated, with results indicating the greatest runup reductions were due to tall roughness elements on the reef flat. Plain Language Summary: Wave breaking and bottom friction are effective at reducing incident sea‐swell waves before they can reach the shoreline of reef‐fronted coastlines. However, globally, mass mortality of coral reef‐building organisms is causing coral reefs to become structurally flatter, a process that may lower wave dissipation. Laboratory flume experiments and a multilayer phase‐resolving wave‐flow model that includes drag forces generated by roughness elements (representing coral reef forms) were used to investigate wave‐driven water levels in the lee of fringing reefs and assess the influence of reef geometry and roughness characteristics. The numerical model was able to reproduce laboratory observations of waves and water levels over both smooth and rough reef profiles. Wave runup, the vertical extent of wave uprush on a beach, was sensitive to the presence and characteristics of roughness. Roughness coverage, spacing, and dimensions were investigated with results indicating the greatest runup reductions were due to tall roughness elements on the reef flat. Key Points: SWASH reproduced laboratory observations of waves and runup over both smooth and rough fringing reefsFore‐reef slope controls wave runup on reef‐fringed coasts as opposed to beach slope on plane open coast beachesWave runup was sensitive to bottom roughness with tall roughness elements on the reef flat generating the greatest runup reduction [ABSTRACT FROM AUTHOR]

Published

2022

3. A Numerical Study of Wave-Driven Mean Flows and Setup Dynamics at a Coral Reef-Lagoon System.

Author

Rijnsdorp, Dirk P., Buckley, Mark L., da Silva, Renan F., Cuttler, Michael V. W., Hansen, Jeff E., Lowe, Ryan J., Green, Rebecca H., and Storlazzi, Curt D.

Subjects

OCEAN waves, OCEANOGRAPHY, CORAL reef ecology, LAGOON ecology, OCEAN circulation

Abstract

Two-dimensional mean wave-driven flow and setup dynamics were investigated at a reef-lagoon system at Ningaloo Reef, Western Australia, using the numerical wave-flow model, SWASH. Phase-resolved numerical simulations of the wave and flow fields, validated with highly detailed field observations (including >10 sensors through the energetic surf zone), were used to quantify the main mechanisms that govern the mean momentum balances and resulting mean current and setup patterns, with particular attention to the role of nonlinear wave shapes. Momentum balances from the phaseresolved model indicated that onshore flows near the reef crest were primarily driven by the wave force (dominated by radiation stress gradients) due to intense breaking, whereas the flow over the reef flat and inside the lagoon and channels was primarily driven by a pressure gradient. Wave setup inside the lagoon was primarily controlled by the wave force and bottom stress. The bottom stress reduced the setup on the reef flat and inside the lagoon. Excluding the bottom stress contribution in the setup balance resulted in an over prediction of the wave-setup inside the lagoon by up to 200--370%. The bottom stress was found to be caused by the combined presence of onshore directed wave-driven currents and (nonlinear) waves. Exclusion of the bottom stress contribution from nonlinear wave shapes led to an over prediction of the setup inside the lagoon by approximately 20--40%. The inclusion of the nonlinear wave shape contribution to the bottom stress term was found to be particularly relevant in reef regions that experience a net onshore mass flux over the reef crest. [ABSTRACT FROM AUTHOR]

Published

2021

4. Climatic Drivers of Extreme Sea Level Events Along the Coastline of Western Australia.

Author

Lowe, Ryan J., Cuttler, Michael V. W., and Hansen, Jeff E.

Subjects

SEA level, CLIMATE extremes, EXTREME environments, COASTAL processes (Physical geology), COASTS

Abstract

Accurate prediction of coastal flooding requires a detailed understanding of all individual contributions to sea level variability and how they interact to trigger extreme sea level (ESL) events. In this study, we focus on the expansive (∼10,000 km) coastline of Western Australia, a region that experiences large latitudinal gradients in met‐ocean sources of sea level variability, as a case study to investigate the mechanisms responsible for ESLs and trends over the past 54 years (1966–2019). Using long‐term sea level records from tide gauges and satellite altimetry, we explore how different contributions to sea level variability at different time scales (from hourly to interannual) interact to generate ESLs. We observe that all individual, nontidal contributions to ESLs (i.e., atmospheric surge, seasonal and interannual variability) are of similar magnitude (of order 10 cm) along the entire coast and comparable to the tidal variations in the microtidal southwestern region. The results reveal the important role that seasonal and interannual sea level variability plays in generating ESLs, with these low‐frequency contributions being relatively large compared to typical global values. With mean sea level having risen by ∼10 cm over this 54‐year study period, sea level rise was also identified as making an increasingly significant contribution to observed increases in the frequency of ESLs. Overall, due to the comparatively large magnitude of low‐frequency sea level contributions (seasonal and longer), the Western Australia coast provides a useful case study to investigate how sustained periods of elevated sea level will impact coastlines worldwide more broadly in the future. Plain Language Summary: Accurate prediction of coastal flooding requires a detailed understanding of the diverse contributions to sea level variability and how they interact to trigger extreme sea level events. In this study, we focus on the expansive (∼10,000 km) coastline of Western Australia, a region that experiences large differences in the sources of sea level variability, as a case study to investigate the causes of sea level extremes over the past 50 years. We combine coastal tide gauge observations and satellite sea level measurements to explore how different contributions to sea level over different time scales (ranging from hours to decades) generate extreme events, including how these contributions have evolved over time. The results reveal the important role that seasonal and interannual sea level variability plays in generating extreme events, which are relatively large compared to typical global values. With mean sea level having risen by ∼10 cm over the study period, sea level rise was also identified as making an increasingly significant contribution to the elevated frequency of extreme events. The Western Australia coast provides a useful global case study to investigate how sustained periods of elevated sea level will impact coastlines more broadly in the future. Key Points: Coastal sea level records were analyzed to isolate the processes responsible for extreme sea level events along Western AustraliaLow‐frequency contributions to sea level variability (seasonal and interannual) were large and comparable to tides and surgesInterannual variability explained clustering of extremes with strong links to global climate cycles [ABSTRACT FROM AUTHOR]

Published

2021

5. The Contribution of Currents, Sea‐Swell Waves, and Infragravity Waves to Suspended‐Sediment Transport Across a Coral Reef‐Lagoon System.

Author

Pomeroy, Andrew W. M., Storlazzi, Curt D., Rosenberger, Kurt J., Lowe, Ryan J., Hansen, Jeff E., and Buckley, Mark L.

Subjects

OCEAN currents, OCEAN waves, GRAVITY waves, SEDIMENT transport, CORAL reefs & islands, LAGOONS

Abstract

Coral reefs generate substantial volumes of carbonate sediment, which is redistributed throughout the reef‐lagoon system. However, there is little understanding of the specific processes that transport this sediment produced on the outer portions of coral reefs throughout a reef‐lagoon system. Furthermore, the separate contributions of currents, sea‐swell waves, and infragravity waves to transport, which are all strongly influenced by the presence of a reef, is not fully understood. Here, we show that in reef‐lagoon systems most suspended sediment is transported close to the seabed and can, at times, be suspended higher in the water column during oscillatory flow transitions (i.e., near slack flow) at sea‐swell wave frequencies, and during the peak onshore oscillatory velocity phase at infragravity wave frequencies. While these wave frequencies contribute to the transport of suspended sediment offshore and onshore, respectively, the net flux is small. Mean currents are the primary transport mechanism and responsible for almost 2 orders of magnitude more suspended‐sediment flux than sea‐swell and infragravity waves. Whilst waves may not be the primary mechanism for the transport of sediment, our results suggest they are an important driver of sediment suspension from the seabed, as well as contributing to the partitioning of sediment grain sizes from the reef to the shoreline. As the ocean wave climate changes, sea level rises, and the composition of reef benthic communities change, the relative importance of mean currents, sea‐swell waves, and infragravity waves is likely to change, and this will affect how sediment is redistributed throughout reef‐lagoon systems. Plain Language Summary: Most of the sandy sediment found on coral reef coastlines is produced by organisms living within the reef. This sediment is then transported by waves and currents across the reef and distributed throughout the lagoon. Little is known about these transport processes, including the relative importance of how currents or different types of waves drive transport. This study shows that most of the sediment in the water column (suspended sediment) is transported close to the seabed by mean currents. At times, this sediment can be suspended higher in the water column by short waves (5–25 s) when the flow transitions from being onshore directed to offshore directed, or when the velocities of longer period waves (25–250 s), called infragravity waves, are directed onshore. The timing of the suspension by these waves helps to sort the sediment into different sizes across the system, but the quantity of sediment transported is small. As the ocean wave climate changes, sea level rises, and reefs change, the relative importance of mean currents, sea‐swell waves, and infragravity waves is also likely to change, and this will affect how sediment is redistributed throughout reef‐lagoon systems. This study provides insight into what changes may be expected. Key Points: Sediment transported in suspension is 3–4 times lower than sediment transported as bedloadSediment transported in suspension by mean currents is 2 orders of magnitude greater than sediment transported by wavesSea‐swell waves typically transport sediment offshore and infragravity waves and mean currents typically transport sediment onshore [ABSTRACT FROM AUTHOR]

Published

2021

6. Source and supply of sediment to a shoreline salient in a fringing reef environment.

Author

Cuttler, Michael V.W., Hansen, Jeff E., Lowe, Ryan J., Trotter, Julie A., and McCulloch, Malcolm T.

Subjects

CLIMATE change, SEDIMENT transport, LANDFORMS, CORAL reef ecology, SOIL erosion

Abstract

Reef‐associated landforms are coupled to the health of the reef ecosystem which produces the sediment that forms and maintains these landforms. However, this connection can make reef‐fronted coastlines sensitive to the impacts of climate change, given that any decline in ecosystem health (e.g. decreasing sediment supply) or changes to physical processes (e.g. sea level rise, increasing wave energy) could drive the sediment budgets of these systems into a net erosive state. Therefore, knowledge of both the sediment sources and transport mechanisms is required to predict the sensitivity of reef‐associated landforms to future climate change. Here, we examine the benthic habitat composition, sediment characteristics (composition, texture, and age), and transport mechanisms and pathways to understand the interconnections between coastal morphology and the reef system at Tantabiddi, Ningaloo Reef, Western Australia. Benthic surveys and sediment composition analysis revealed that although live coral accounts for less than 5% of the benthic cover, coral is the dominant sediment constituent (34% on average). Sediment ages (238U/230Th) were mostly found to be thousands of years old, suggesting that the primary sediment source is relic reef material (e.g. Holocene reef framework). Sediment transport across the lagoon was quantified through measurements of ripple migration rates, which were found to be shoreward migrating and responsible for feeding the large shoreline salient in the lee of the reef. The derived sediment fluxes were comparable with previously measured rates of sediment production by bioerosion. These results suggest that sediment budgets of systems dependent on old (>103 years) source materials may be more resilient to climate change as present‐day reef health and community composition (i.e. sources of 'new' carbonate production) have limited influence on sediment supply. Therefore, the vulnerability of reef‐associated landforms in these systems will be dictated by future changes to mechanisms of sediment generation (e.g. bioerosion) and/or physical processes. © 2018 John Wiley & Sons, Ltd. Ecological, sedimentological, and sediment transport data were analysed to understand the interconnections between coastal morphology and reef ecology within a fringing reef system. The sediment reservoir is predominantly derived from 'old' source material (≥ 1400 years old) but this material is supplied to the shoreline on modern timescales. These results suggest that sediment budgets of similar reef systems may be more resilient to climate change as contemporary reef health and community composition have limited influence on sediment supply. [ABSTRACT FROM AUTHOR]

Published

2019

7. Physical linkages between an offshore canyon and surf zone morphologic change.

Author

Hansen, Jeff E., Raubenheimer, Britt, Elgar, Steve, List, Jeffrey H., and Lippmann, Thomas C.

Published

2017

8. Modeled alongshore circulation and force balances onshore of a submarine canyon.

Author

Hansen, Jeff E., Raubenheimer, Britt, List, Jeffrey H., and Elgar, Steve

Published

2015

9. The impact of the 2009-10 El Niño Modoki on U.S. West Coast beaches.

Author

Barnard, Patrick L., Allan, Jonathan, Hansen, Jeff E., Kaminsky, George M., Ruggiero, Peter, and Doria, André

Published

2011