Climate Change and Land-use Histories
As part of the USGS Coral Reef Project, we are developing new and unique oceanographic and environmental archives from coral skeleton records to better understand the compounding effects of land-use and environmental change on coral reef health.
The Problem
In addition to overfishing, physical damage, and coastal development, declining water quality is one of the most serious and sustained threats to coral reefs and is thought to be a primary cause of the global decline in shallow coral reefs. Isolating the effects of water quality stressors is difficult without determining the physical and biological controls on reef health. However, to evaluate recent trends and establish links to environmental and land-use change, there is a need to put these changes into a temporal and spatial context in order to identify thresholds and ranges of variability in the environment.
Our Approach
By measuring both physical changes (such as bioerosion, calcification, and growth rate) and chemical variations, records of climate change and land-use histories can be developed to supplement disperse observational networks and offer an accessible source of hydrologic, environmental, and land-use information in locations where instrumental records are not available. We are conducting innovative research to develop new and unique oceanographic and environmental archives from coral skeleton records to better understand the compounding effects of land-use and environmental change on coral reef health.
Specifically, we are conducting applied research to strategically address scientific knowledge gaps that impede informed management decisions related to planning and implementing activities in priority coral reef ecosystems and associated watersheds, such as identifying the causes and sources of pollution or estimating load reductions expected from implementation of specific management measures. We apply recently developed nutrient proxies to provide pre-instrumental records of nutrient loading to coral reefs in impacted sites. When these results are coupled to records of reef growth, we can develop a matrix of susceptibility in the context of nutrient loading and changes to carbonate chemistry. We aim to introduce coral-derived time-series information into monitoring and future management decisions to reduce and prevent land-based sources of pollution, including forecasting future impacts and response to load reductions expected from implementation of specific management tactics.
Caption for large image at top of page: Photograph of Asan-1 core (1.17 m in length) taken for image analysis using a Geotek Multi-Sensor Logger (MSL) system. Age dates were assigned based on year of collection, tissue layer, and band counting using annual density growth patterns captured in CT imagery. Image from Prouty et al., 2014
Please also see the associated efforts on the Coral Reef Ecosystem Studies (CREST) Project website:
Learn more about our related studies.
Below are data releases associated with this project.
Below are publications associated with this project.
Reconstructing surface ocean circulation with 129I time series records from corals
Ocean circulation and biogeochemistry moderate interannual and decadal surface water pH changes in the Sargasso Sea
Historic impact of watershed change and sedimentation to reefs along west-central Guam
Environmental assessment of metal exposure to corals living in Castle Harbour, Bermuda
Determination of low-level mercury in coralline aragonite by calcination-isotope dilution-inductively coupled plasma-mass spectrometry and its application to Diploria specimens from Castle Harbour, Bermuda
Coral Ba/Ca records of sediment input to the fringing reef of the southshore of Moloka'i, Hawai'i over the last several decades
Coral proxy record of decadal-scale reduction in base flow from Moloka'i, Hawaii
Geochemical signature of land-based activities in Caribbean coral surface samples
As part of the USGS Coral Reef Project, we are developing new and unique oceanographic and environmental archives from coral skeleton records to better understand the compounding effects of land-use and environmental change on coral reef health.
The Problem
In addition to overfishing, physical damage, and coastal development, declining water quality is one of the most serious and sustained threats to coral reefs and is thought to be a primary cause of the global decline in shallow coral reefs. Isolating the effects of water quality stressors is difficult without determining the physical and biological controls on reef health. However, to evaluate recent trends and establish links to environmental and land-use change, there is a need to put these changes into a temporal and spatial context in order to identify thresholds and ranges of variability in the environment.
Our Approach
By measuring both physical changes (such as bioerosion, calcification, and growth rate) and chemical variations, records of climate change and land-use histories can be developed to supplement disperse observational networks and offer an accessible source of hydrologic, environmental, and land-use information in locations where instrumental records are not available. We are conducting innovative research to develop new and unique oceanographic and environmental archives from coral skeleton records to better understand the compounding effects of land-use and environmental change on coral reef health.
Specifically, we are conducting applied research to strategically address scientific knowledge gaps that impede informed management decisions related to planning and implementing activities in priority coral reef ecosystems and associated watersheds, such as identifying the causes and sources of pollution or estimating load reductions expected from implementation of specific management measures. We apply recently developed nutrient proxies to provide pre-instrumental records of nutrient loading to coral reefs in impacted sites. When these results are coupled to records of reef growth, we can develop a matrix of susceptibility in the context of nutrient loading and changes to carbonate chemistry. We aim to introduce coral-derived time-series information into monitoring and future management decisions to reduce and prevent land-based sources of pollution, including forecasting future impacts and response to load reductions expected from implementation of specific management tactics.
Caption for large image at top of page: Photograph of Asan-1 core (1.17 m in length) taken for image analysis using a Geotek Multi-Sensor Logger (MSL) system. Age dates were assigned based on year of collection, tissue layer, and band counting using annual density growth patterns captured in CT imagery. Image from Prouty et al., 2014
Please also see the associated efforts on the Coral Reef Ecosystem Studies (CREST) Project website:
Learn more about our related studies.
Below are data releases associated with this project.
Below are publications associated with this project.