Development of a Seamless, High-Resolution Bathymetric Model to Compare Reef Morphology around the Subtropical Island Shelves of Lord Howe Island and Balls Pyramid, Southwest Pacific Ocean

Linklater, Michelle; Hamylton, Sarah; Brooke, Brendan; Nichol, Scott L.; Jordan, Alan; Woodroffe, Colin D.

doi:10.3390/geosciences8010011

Cited by 14 publications

(17 citation statements)

References 45 publications

(81 reference statements)

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“…Our results are consistent with the idea that initial local adaptation and postzygotic isolation were supplemented by the rapid completion of prezygotic isolation through flowering time differences (Papadopulos et al 2013b(Papadopulos et al , 2014. Furthermore, given the supporting evidence these results allow us to rule out continuous absence of gene flow, even though LHI was larger at the time of speciation (Papadopulos et al, 2011(Papadopulos et al, , 2013aLinklater et al 2018). Unlike recent genomic reanalyses of classic cases of speciation in sympatry, our results support the proposition that Howea palms must have diverged with continuous gene flow.…”

Section: Resultssupporting

confidence: 90%

“…, ). Furthermore, given the supporting evidence these results allow us to rule out continuous absence of gene flow, even though LHI was larger at the time of speciation (Papadopulos et al., , ; Linklater et al ). Unlike recent genomic reanalyses of classic cases of speciation in sympatry, our results support the proposition that Howea palms must have diverged with continuous gene flow.…”

Section: Resultsmentioning

confidence: 90%

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Ecological speciation in sympatric palms: 4. Demographic analyses support speciation of Howea in the face of high gene flow

et al. 2019

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The idea that populations must be geographically isolated (allopatric) to evolve into separate species has persisted for a long time. It is now clear that new species can also diverge despite ongoing genetic exchange, but few accepted cases of speciation in sympatry have held up when scrutinized using modern approaches. Here, we examined evidence for speciation of the Howea palms of Lord Howe Island, Australia, in light of new genomic data. We used coalescence‐based demographic models combined with double digest restriction site associated DNA sequencing of multiple individuals and provide support for previous claims by Savolainen et al. that speciation in Howea did occur in the face of gene flow.

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Section: Resultssupporting

confidence: 90%

Section: Resultsmentioning

confidence: 90%

Ecological speciation in sympatric palms: 4. Demographic analyses support speciation of Howea in the face of high gene flow

et al. 2019

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“…Some depth errors may also be due to the differences in resolution, i.e., 10 m from the satellite, and the 1 m spot size for lidar-a consideration in areas with steep gradients, such as channel edges. Using a median filter on the SDB reduced other artifacts that typically lead to random noise [49]. One potential error factor that needs to be considered in the future is tide range.…”

Section: Discussionmentioning

confidence: 99%

“…The final step for a corrected bathymetry mapping (SDB) corresponded to a switching model implementation between SDBred and SDBgreen due to the sensitivity of each model: while SDBred performs better over shallow regions [48], SDBgreen performs better over deeper regions [21,31,44,49]. Moreover, SDBgreen frequently yields severe overestimation in shallow regions [22,44,50], especially with dense seagrass, highly undesirable for navigational purposes.…”

Section: Switching Modelmentioning

confidence: 99%

Towards Routine Mapping of Shallow Bathymetry in Environments with Variable Turbidity: Contribution of Sentinel-2A/B Satellites Mission

Caballero

Stumpf

2020

Remote Sensing

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Satellite-Derived Bathymetry (SDB) has significant potential to enhance our knowledge of Earth's coastal regions. However, SDB still has limitations when applied to the turbid, but optically shallow, nearshore regions that encompass large areas of the world's coastal zone. Turbid water produces false shoaling in the imagery, constraining SDB for its routine application. This paper provides a framework that enables us to derive valid SDB over moderately turbid environments by using the high revisit time (5-day) of the Sentinel-2A/B twin mission from the Copernicus programme. The proposed methodology incorporates a robust atmospheric correction, a multi-scene compositing method to reduce the impact of turbidity, and a switching model to improve mapping in shallow water. Two study sites in United States are explored due to their varying water transparency conditions. Our results show that the approach yields accurate SDB, with median errors of under 0.5 m for depths 0-13 m when validated with lidar surveys, errors that favorably compare to uses of SDB in clear water. The approach allows for the semi-automated creation of bathymetric maps at 10 m spatial resolution, with manual intervention potentially limited only to the calibration to the absolute SDB. It also returns turbidity data to indicate areas that may still have residual shoaling bias. Because minimal in-situ information is required, this computationally-efficient technique has the potential for automated implementation, allowing rapid and repeated application in more environments than most existing methods, thereby helping with a range of issues in coastal research, management, and navigation. surveys are constrained by access, logistics and extremely high deployment cost. It is estimated that multibeam echo sounding (at best resolution) would take more than 200 ship-years and billions of dollars to complete a swath survey of the seafloor [6]. The problem is substantial; consider that some 50% of the USA territories-as an example-were surveyed by using old hydrographic methods that do not meet today's requirement [7]. In the opinion of the IHO, sea bottom information derived from satellite imagery, widely known as Satellite-Derived-Bathymetry (SDB), should be considered as a potential technology to improve the collection, timeliness, quality, and availability of bathymetric data worldwide. In this regard, IHO has started to evaluate SDB strategies and the IHO S-44 standards are currently under revision. Furthermore, SDB offers a low-cost and non-intrusive suitable solution because no mobilization is required, removing health and safety risk, and any environmental impact.Approaches to SDB mapping vary on aim and rationale, spatial scale, and source of satellite system information. The concept is based on detection of sunlight reflected from the seafloor, and algorithms that use spectral information from this light to calculate water column depth. Several reviews of the methodologies are available in the literature [8,9]. Although the acquisition of imagery ...

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“…For instance, Walbridge et al [14] used a 3 m resolution lidar dataset of the Buck Island Reef National Monument, in the U.S. Virgin Islands, to classify the seafloor into nine geomorphic classes. Linklater et al [15] empirically derived depth estimates from 2-m resolution WorldView-2 and 2.4-m resolution Quickbird satellite images that were corrected for atmospheric effects and sun glint. Those depth estimates were then combined with existing acoustic data from deeper waters to develop a seamless, high-resolution DBM of the shelf around Lord Howe Island (Southwest Pacific Ocean), from which geomorphometric analyses were performed.…”

Section: Sampling the Depth Of The Seafloormentioning

confidence: 99%

Charting the Course for Future Developments in Marine Geomorphometry: An Introduction to the Special Issue

2018

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The use of spatial analytical techniques for describing and classifying seafloor terrain has become increasingly widespread in recent years, facilitated by a combination of improved mapping technologies and computer power and the common use of Geographic Information Systems. Considering that the seafloor represents 71% of the surface of our planet, this is an important step towards understanding the Earth in its entirety. Bathymetric mapping systems, spanning a variety of sensors, have now developed to a point where the data they provide are able to capture seabed morphology at multiple scales, opening up the possibility of linking these data to oceanic, geological, and ecological processes. Applications of marine geomorphometry have now moved beyond the simple adoption of techniques developed for terrestrial studies. Whilst some former challenges have been largely resolved, we find new challenges constantly emerging from novel technology and applications. As increasing volumes of bathymetric data are acquired across the entire ocean floor at scales relevant to marine geosciences, resource assessment, and biodiversity evaluation, the scientific community needs to balance the influx of high-resolution data with robust quantitative processing and analysis techniques. This will allow marine geomorphometry to become more widely recognized as a sub-discipline of geomorphometry as well as to begin to tread its own path to meet the specific challenges that are associated with seabed mapping. This special issue brings together a collection of research articles that reflect the types of studies that are helping to chart the course for the future of marine geomorphometry.

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Development of a Seamless, High-Resolution Bathymetric Model to Compare Reef Morphology around the Subtropical Island Shelves of Lord Howe Island and Balls Pyramid, Southwest Pacific Ocean

Cited by 14 publications

References 45 publications

Ecological speciation in sympatric palms: 4. Demographic analyses support speciation of Howea in the face of high gene flow

Ecological speciation in sympatric palms: 4. Demographic analyses support speciation of Howea in the face of high gene flow

Towards Routine Mapping of Shallow Bathymetry in Environments with Variable Turbidity: Contribution of Sentinel-2A/B Satellites Mission

Charting the Course for Future Developments in Marine Geomorphometry: An Introduction to the Special Issue

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