Your search keyword '"Stephanie Duce"' showing total 9 results

1. Defining Ecosystem Scale Surface Complexity of Coral Reefs Using a High-Resolution Lidar Digital Elevation Model

Author

Daniel Lee Harris, Jody M. Webster, Ana Vila-Concejo, Stephanie Duce, Javier Leon, and Jorg Hacker

Published

2022

2. Global opportunities and challenges for Shark Large Marine Protected Areas

Author

Robert L. Pressey, Me’ira Mizrahi, Rebecca Weeks, Colin A. Simpfendorfer, Stephanie Duce, and Amy Diedrich

Subjects

0106 biological sciences, Adaptive capacity, Overfishing, 010604 marine biology & hydrobiology, Fishing, Developing country, Legislation, 010603 evolutionary biology, 01 natural sciences, Destructive fishing practices, Marine protected area, Business, Socioeconomic status, Environmental planning, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Legislation to ban the targeted fishing of sharks is frequently employed within developing coastal nations. These Shark Large Marine Protected Areas (SLMPAs) are established primarily to alleviate the direct threats that humans pose to sharks through activities such as overfishing and destructive fishing practices. However, despite the anthropogenic nature of these threats, socioeconomic factors are often given less consideration than their ecological counterparts when designating SLMPAs. In this paper, we identified and examined relevant national-level socioeconomic data to determine the challenges and opportunities associated with implementing SLMPAs, focussing on least developed and low income countries. We aimed to use these socioeconomic data to identify nations where SLMPAs are more likely to be successful in providing conservation benefits to sharks. We used principal component analysis to develop two national-level indices that represent these anticipated opportunities and challenges for implementing SLMPAs across 87 coastal nations. The Opportunity Index identifies those nations in which socioeconomic conditions such as adaptive capacity, and strong and fair governance, are favourable for SLMPAs to provide conservation benefits to sharks. The Challenge Index identifies those nations that may not yet be in a position developmentally to support communities to adapt to a loss of access to resources associated with SLMPAs, or to manage and enforce broad scale restrictive legislation. In combination with biophysical considerations, the Challenge and Opportunity indices presented here can support policy makers in deciding whether, and in what cases, SLMPAs are the most appropriate measure to provide conservation benefits to sharks.

Published

2019

3. Holocene reef growth over irregular Pleistocene karst confirms major influence of hydrodynamic factors on Holocene reef development

Author

Trevor Graham, Belinda Dechnik, Jody M. Webster, Jian-xin Zhao, Tara R. Clark, Gregory E. Webb, Luke D. Nothdurft, Stephanie Duce, and Marcos Salas-Saavedra

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Environmental change, Pleistocene, Geology, 010502 geochemistry & geophysics, Karst, 01 natural sciences, Paleontology, Submarine pipeline, 14. Life underwater, Progradation, Reef, Ecology, Evolution, Behavior and Systematics, Holocene, Sea level, 0105 earth and related environmental sciences

Abstract

Many factors govern reef growth through time, but their relative contributions are commonly poorly known. A prime example is the degree to which modern reef morphology is controlled by contemporary hydrodynamic settings or antecedent topography. Fortunately, reefs record essential information for interpreting palaeoclimate and palaeoenvironment within their structure as they accrete in response to environmental change. Five new cores recovered from the margin of Heron Reef, southern Great Barrier Reef (GBR), provide new insights into Holocene reef development and relationships between Holocene reefs and Pleistocene antecedent topography, suggesting much more irregular underlying topography than expected based on the configuration of the overlying modern reef margin. Cores were recovered to depths of 30 m and 94 new 230Th ages document growth between 8408 ± 24 and 2222 ± 16 yrs. BP. One core penetrated Pleistocene basement at ∼15.3 m with Holocene reef growth initiated by ∼8.4 ka BP. However, 1.83 km west along the same smooth margin, four cores failed to penetrate Pleistocene basement at depths between 20 and 30 m, suggesting that the margin at this location overlies a karst valley, or alternatively, the antecedent platform does not extend there. A 48 m-long margin-perpendicular transect of three cores documents the filling of this topographic low, at least 30 m beneath the current reef top, with seaward lateral accretion at a rate of 34.3 m/ka. Cores indicate steady vertical and lateral accretion between 3.2 and 1.8 ka BP with no evidence of the hiatus in reef flat progradation seen in most other offshore reefs of the GBR at that time. These cores suggest that the relative protection afforded by the valley allowed for unconsolidated sediment to accumulate, enabling continuous progradation even when other areas of the reef flat appear to have ‘turned off’. Additionally, the cores suggest that although reefs in the southern GBR clearly owe their location to Pleistocene antecedent topography, modern reef morphology at sea level primarily reflects the interaction of Holocene reef communities with contemporary hydrodynamics.

Published

2018

4. Estimating regional coral reef calcium carbonate production from remotely sensed seafloor maps

Author

Rafael Cabral Carvalho, Stuart R. Phinn, Karen E. Joyce, Stephanie Duce, Sarah Hamylton, Emily C. Shaw, Ana Vila-Concejo, and Chris Roelfsema

Subjects

0106 biological sciences, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, biology, Resilience of coral reefs, 010604 marine biology & hydrobiology, Coral, Soil Science, Coralline algae, Geology, Ocean acidification, Coral reef, biology.organism_classification, 01 natural sciences, chemistry.chemical_compound, Oceanography, chemistry, Carbonate, Computers in Earth Sciences, Reef, 0105 earth and related environmental sciences, Halimeda

Abstract

Carbonate production on coral reefs is responsible for the provision of beach sands, for the maintenance of seawater chemical balances and for the growth of reef structure and associated habitat complexity. Key carbonate producers including hard coral, crustose coralline algae, foraminiferal sand and Halimeda were mapped from satellite imagery (spatial resolution 2.5 m, mean overall accuracy = 81%) and an upscaling model was applied to estimate carbonate production. A sensitivity analysis was conducted to evaluate the influence of employing different calcification rates for live coral on the upscaling model. Contemporary coral reef carbonate production for the 21 reef platforms of the Capricorn-Bunker Group (southern Great Barrier Reef) is estimated to be between 489,000 and 659,000 t per year based on seawater chemistry, community composition, calcification rates and reef structural complexity (rugosity). The upscaling model was relatively insensitive to different parameterisations of live coral calcification employed, probably due to live coral being a relatively minor contributor by area (approximately 18% of total reef area throughout the study region). This suggests regional scale seafloor characteristics, such as percentage of area dominated by substrates prone to dissolution (e.g. coral rubble), have a strong bearing on calcium carbonate production and need to be given greater consideration The upscaling framework presented provides a new method for quantifying regional carbonate production that could be applied globally, and provides a valuable baseline against which future changes to carbonate production in this region can be assessed.

Published

2017

5. The evolution of the Great Barrier Reef during the Last Interglacial Period

Author

Gregory E. Webb, Juan-Carlos Braga, Belinda Dechnik, James Sadler, Jody M. Webster, Jian-xin Zhao, Luke D. Nothdurft, Andrea Dutton, and Stephanie Duce

Subjects

Marine isotope stage, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Paleontology, Facies, Interglacial, Upwelling, 14. Life underwater, Ice sheet, Reef, Geology, Holocene, Sea level, 0105 earth and related environmental sciences

Abstract

Reef response to Last Interglacial (LIG) sea level and palaeoenvironmental change has been well documented at a limited number of far-field sites remote from former ice sheets. However, the age and development of LIG reefs in the Great Barrier Reef (GBR) remain poorly understood due to their location beneath modern living reefs. Here we report thirty-nine new mass spectrometry U-Th ages from seven LIG platform reefs across the northern, central and southern GBR. Two distinct geochemical populations of corals were observed, displaying activity ratios consistent with either closed or open system evolution. Our closed-system ages (~ 129–126 ka) provide the first reliable LIG ages for the entire GBR. Combined with our open-system model ages, we are able to constrain the interval of significant LIG reef growth in the southern GBR to between ~ 129–121 ka. Using age-elevation data in conjunction with newly defined coralgal assemblages and sedimentary facies analysis we have defined three distinct phases of LIG reef development in response to major sea level and oceanographic changes. These phases include: Phase 1 (> 129 ka), a shallow-water coralgal colonisation phase following initial flooding of the older, likely Marine Isotope Stage 7 (MIS7) antecedent platform; Phase 2 (~ 129 ka), a near drowning event in response to rapid sea level rise and greater nutrient-rich upwelling and; Phase 3 (~ 128–121 ka), establishment of significant reef framework through catch-up reef growth, initially characterised by deeper, more turbid coralgal assemblages (Phase 3a) that transition to shallow-water assemblages following sea level stabilisation (Phase 3b). Coralgal assemblage analysis indicates that the palaeoenvironments during initial reef growth phases (1 and 2) of the LIG were significantly different than the initial reef growth phases in the Holocene. However, the similar composition of ultimate shallow-water coralgal assemblages and slow reef accretion rates following stabilisation of sea level (phase 3b) suggest that reefs of both ages developed in a similar way during the main phase of relatively stable sea level.

Published

2017

6. Geomorphic changes of a coral shingle cay measured using Kite Aerial Photography

Author

Stephanie Duce, Alisha M. Thompson, Mitch Bryson, Daniel L. Harris, Jody M. Webster, Ana Vila-Concejo, and Stefan B. Williams

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Rubble, Elevation, Context (language use), Coral reef, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Photogrammetry, Lidar, Aerial photography, engineering, Reef, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Remote sensing

Abstract

Measurements of geomorphic change in the intertidal zones of coral reefs are made using a variety of remote sensing and in-situ techniques, where variations in the coverage and spatial-temporal precision achieved are directly related to the cost of data acquisition. We present a novel, low-cost technique for measuring high-resolution changes in reef environments based on Kite Aerial Photography (KAP) and photogrammetry/structure-from-motion post-processing. KAP images are used to measure fine-scale changes in intertidal topography and sediment texture characteristics, including rubble particle size, of a coral shingle cay at One Tree Island, Great Barrier Reef in the context of storm activity. Validation using Real Time Kinematic DGPS demonstrates the ability to measure topographic elevation with an error of 5.53 cm (RMSE) and a spatial resolution of 5 cm per point, an accuracy/resolution that is superior to airborne LiDAR and equivalent to terrestrial LiDAR, but at a fraction of the equipment cost.

Published

2016

7. A morphometric assessment and classification of coral reef spur and groove morphology

Author

Robin J. Beaman, Eleanor Bruce, Sarah Hamylton, Jody M. Webster, Stephanie Duce, and Ana Vila-Concejo

Subjects

Morphometrics, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Feature (archaeology), Coral reef, 010502 geochemistry & geophysics, 01 natural sciences, Substrate (marine biology), Swell, Paleontology, Oceanography, Reef, Beach morphodynamics, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Marine transgression

Abstract

Spurs and grooves (SaGs) are a common and important feature of coral reef fore slopes worldwide. However, they are difficult to access and hence their morphodynamics and formation are poorly understood. We use remote sensing, with extensive ground truthing, to measure SaG morphometrics and environmental factors at 11,430 grooves across 17 reefs in the southern Great Barrier Reef, Australia. We revealed strong positive correlations between groove length, orientation and wave exposure with longer, more closely-spaced grooves oriented easterly reflecting the dominant swell regime. Wave exposure was found to be the most important factor controlling SaG distribution and morphology. Gradient of the upper reef slope was also an important limiting factor, with SaGs less likely to develop in steeply sloping (> 5°) areas. We used a subset of the morphometric data (11 reefs) to statistically define four classes of SaG. This classification scheme was tested on the remaining six reefs. SaGs in the four classes differ in morphology, groove substrate and coral cover. These differences provide insights into SaG formation mechanisms with implications to reef platform growth and evolution. We hypothesize SaG formation is dominated by coral growth processes at two classes and erosion processes at one class. A fourth class may represent relic features formed earlier in the Holocene transgression. The classes are comparable with SaGs elsewhere, suggesting the classification could be applied globally with the addition of new classes if necessary. While further research is required, we show remotely sensed SaG morphometrics can provide useful insights into reef platform evolution.

Published

2016

8. Mitigating negative livelihood impacts of no-take MPAs on small-scale fishers

Author

Stephanie Duce, Khin May Chit Maung, Robert L. Pressey, Ei Thal Phyu, Amy Diedrich, Me’ira Mizrahi, Colin A. Simpfendorfer, Zin Lin Khine, and Tracy MacKeracher

Subjects

0106 biological sciences, 010604 marine biology & hydrobiology, fungi, Fishing, Vulnerability, Livelihood, 010603 evolutionary biology, 01 natural sciences, Commercial fishing, Scale (social sciences), Marine protected area, Business, Environmental planning, Socioeconomic status, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, Diversity (business)

Abstract

Marine Protected Areas (MPAs) have the potential to support small-scale fishers in managing their resources. However, a general failure to consider the varying levels of vulnerability of fishers has resulted in MPAs that, often unintentionally, adversely impact small-scale fishers. Furthermore, when fishers lack the capacity to adapt to MPA-related changes, MPAs may fail to meet conservation objectives because fishers do not comply with MPA regulations. In this study, we developed a systematic method to identify individuals who are most vulnerable to being negatively impacted by no-take MPAs through an index that represents individual-level vulnerability. We designed a method for identifying these individuals based on four socioeconomic factors pertaining to vulnerability to MPA changes: livelihood diversity, education, age and wealth, then applied this method in two socially and economically heterogeneous communities in Myanmar's Myeik Archipelago. We used empirical data collected from 80 small-scale fishers in this area to represent each factor, then generated a local-level ‘Livelihood Impact Potential Index’ (LIPI) that reflects the degree to which a no-take MPA would impact an individual fisher's ability to support his or her livelihood. When attributed to each fisher's most frequented fishing ground, the LIPI can identify locations where no-take MPAs would be most detrimental to small-scale fishers' livelihoods based on their levels of vulnerability. The LIPI can thus be used alongside ecological and commercial fishing data to support planners in designing local-scale MPAs that maximise positive impact on biodiversity and minimise adverse impacts on the most vulnerable fishers in a community.

Published

2020

9. Mechanisms of spur and groove development and implications for reef platform evolution

Author

Jody M. Webster, Stephanie Duce, Gregory E. Webb, Luke D. Nothdurft, Ana Vila-Concejo, James Sadler, Marcos Salas-Saavedra, Quan Hua, and Belinda Dechnik

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geology, Coral reef, 010502 geochemistry & geophysics, 01 natural sciences, Great barrier reef, Paleontology, Spur, 14. Life underwater, Reef, Groove (engineering), Ecology, Evolution, Behavior and Systematics, Holocene, 0105 earth and related environmental sciences, Accretion (coastal management)

Abstract

Contemporary understanding of Holocene coral reef development is based primarily on sub-surface investigations of reef flat, back reef and lagoon zones. Few studies of Holocene fore reef development exist, constituting a significant gap in our understanding of reef evolution. The spur and groove (SaG) zone is a distinct, understudied, feature of fore reefs worldwide. We review SaG development from previous studies and present 29 new SaG short cores with 52 14C and U–Th ages from six fore reef regions of Heron and One Tree reefs, the first such data from the Great Barrier Reef. Remarkably, we found that SaGs do not necessarily accrete in the same direction as their adjacent reef flat. We identified three modes of reef flat and SaG lateral accretion: Mode 1 – lagoonward accretion of both the reef flat and SaGs; Mode 2 –lagoonward accretion of the reef flat but seaward accretion of the SaGs; Mode 3 - seaward accretion of both the reef flat and SaGs. Most SaG zones (five of the six studied) accreted in a seaward direction (Modes 2 or 3). Hydrodynamic conditions and local topography appear to be the dominant factors determining which mode occurs. Episodic high-energy events are also likely to play an important role in SaG formation. Our findings suggest that traditionally held models of reef evolution whereby lagoonal, mature reefs fill, developing into senile platform reefs, may not hold. Rather, reef flats may continue to expand seaward on their leeward, and semi-exposed fronts to increase in size while maintaining their lagoons.

Published

2020