The project restored both structural and habitat functions of Bayou Dupont and flanking marshes. The project created and nourished marsh and restored a ridge on the west bank of Bayou Dupont. The entire ridge will be planted with appropriate woody vegetation. Soil samples to be taken every 6 months over a 2- to 3-year period due to concerns about high salinities of the ridge soils affecting survivability of the planted woody vegetation.

We are collecting stream channel geometry and bed sediment grain size distribution data at the Parker River to evaluate physical habitat changes associated with the planned Larkin Mill Dam removal. In addition to evaluating channel response to dam removal, our two years of pre-removal data collection (2008 and 2010) bracketed a large flood event that allowed us to investigate whether this small dam is an efficient sediment trap.

We are collecting stream channel geometry and bed sediment grain size distribution data at the Parker River to evaluate physical habitat changes associated with the planned Larkin Mill Dam removal. In addition to evaluating channel response to dam removal, our two years of pre-removal data collection (2008 and 2010) bracketed a large flood event that allowed us to investigate whether this small dam is an efficient sediment trap.

This dataset includes stream channel geometry and bed sediment grain size distribution data at the Parker River to evaluate physical habitat changes associated with the planned Larkin Mill Dam removal. In addition to evaluating channel response to dam removal, two years of pre-removal data collection (2008 and 2010) bracketed a large flood event that allowed us to investigate whether this small dam is an efficient sediment trap.

We are collecting stream channel geometry and bed sediment grain size distribution data at Sedgeunkedunk stream to evaluate physical habitat changes associated with the Brewer Dam removal. These data complement studies led by others that are investigating biological responses to the project. Together, the physical and biological data collected in the lower Sedgeunkedunk stream help us understand the effectiveness of dam removal for restoring diadromous fish access and ecosystem recovery.

We are collecting stream channel geometry and bed sediment grain size distribution data at Sedgeunkedunk stream to evaluate physical habitat changes associated with the Brewer Dam removal. These data complement studies led by others that are investigating biological responses to the project. Together, the physical and biological data collected in the lower Sedgeunkedunk stream help us understand the effectiveness of dam removal for restoring diadromous fish access and ecosystem recovery.

This dataset includes stream channel geometry data along Sedgeunkedunk Stream to evaluate physical habitat changes associated with the Brewer Dam removal. These data complement studies led by others that are investigating biological responses to the project. Together, the physical and biological data collected in the lower Sedgeunkedunk Stream help us understand the effectiveness of dam removal for restoring diadromous fish access and ecosystem recovery.

These images represent LiDAR (Light Detection & Ranging) data collected by NOAA from the shoreline of southwestern Puerto Rico to about 50 meters in depth. Reflectivity was calculated for each sounding as the ratio of returned energy to transmitted energy, normalized for losses in a single wavelength (green/blue 532nm). This data was critical for creating benthic habitat maps.

This dataset contains surface measurements of dissolved inorganic carbon, total alkalinity, pH in the North Atlantic Ocean. Increasing amounts of atmospheric carbon dioxide from human industrial activities are causing changes in global ocean carbon chemistry. Through the SOOP program we measure air and ocean surface pCO2 and take discrete samples of other carbon parameters. This effort is in support of the coastal monitoring and research objectives of the NOAA Ocean Acidification Program (OAP) and the Climate Program Office.

This dataset contains bottle measurements of dissolved inorganic carbon and total alkalinity off the east coast of Florida. Increasing amounts of atmospheric carbon dioxide from human industrial activities are causing changes in global ocean carbon chemistry. Through the SOOP program we measure air and ocean surface pCO2 and take discrete samples of other carbon parameters. This effort is in support of the coastal monitoring and research objectives of the NOAA Ocean Acidification Program (OAP) and the Climate Program Office.