A novel method for increasing water-yields, pine forests of the Northern Gulf of Mexico, USA

Abstract. With a burgeoning world population that is expected to reach 10 billion by 2050, 30 % more than today, there is an urgent need to harness available water resources to support regions across the world. This study introduces a new method to identify, prioritize, and select areas for pine basal area reduction to maximize water yields in pine forests along the Northern Gulf of Mexico, USA. The method, demonstrated in the Apalachicola Region of Northwest Florida, an area covered by dense vegetation and pine plantation forests, has experienced freshwater loss due to increased upstream water demand, climate change, and past forest management practices. Potential initial water-yield gains were: 1) 469 m3 d−1 if all pine basal areas were reduced from current to a maximum of 18 m2 ha−1, and 53,400 m3 d−1 if pine basal areas were reduced from current to a maximum of 7 m2 ha−1 for the Apalachicola Region. The method identifies watersheds mainly along the Apalachicola and other rivers and near the Gulf coast that have the greatest potential to increase water yields. Increasing forest water yields translates to increased freshwater availability and improved forest and soil health, water quality, and ecosystem function, services, and resilience, as well as socioeconomic outcomes for communities and people who rely on ecotourism and fisheries for their livelihoods. This method will empower forest managers to focus scarce resources in targeted areas to maximize water-resource benefits per resource investment. Although demonstrated in the Apalachicola Region, the method is easily transferable throughout other pine forests of the Northern Gulf Coast Region. This scientifically sound method is repeatable, scalable, and easily upgraded and adapted as newer, higher resolution datasets become available and relationships between forest metrics, evapotranspiration, and water yields are improved.

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Evidence of Hurricane Influence on Barrier Island Slash Pine Forests in the Northern Gulf of Mexico

The American Midland Naturalist ◽

10.2307/2424946 ◽

1978 ◽

Vol 99 (1) ◽

pp. 234 ◽

Cited By ~ 12

Author(s):

Daniel L. Stoneburner

Keyword(s):

Gulf Of Mexico ◽

Barrier Island ◽

Slash Pine ◽

Pine Forests ◽

Northern Gulf Of Mexico

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Gulf-wide data synthesis for restoration planning: Utility and limitations

Shore & Beach ◽

10.34237/1008813 ◽

2020 ◽

pp. 23-33

Author(s):

Leland Moss ◽

Tim Carruthers ◽

Harris Bienn ◽

Adrian Mcinnis ◽

Alyssa Dausman

Keyword(s):

Gulf Of Mexico ◽

Gulf Coast ◽

Coastal Zone Management ◽

Primary Data ◽

Centers Of Excellence ◽

Northern Gulf Of Mexico ◽

Restoration Planning ◽

Community Benefits ◽

Zone Management ◽

Data Layers

Multiple funding mechanisms support restoration across the northern Gulf of Mexico. To maximize environmental, societal, and financial benefits of these investments, best use of available science is needed to inform project prioritization and planning processes. Synthesizing available data across the northern Gulf of Mexico can provide information on potential threats to, and benefits from, projects or suites of projects. To achieve this, subject matter experts from Alabama, Florida, Louisiana, Mississippi and Texas were identified with recommendations from each of the RESTORE Act Centers of Excellence. These experts provided known sources of Gulf-wide data and recommended metrics that would be most informative, resulting in 40 threat, 19 habitat and 10 community primary data layers. Two tessellated geospatial hexagon grids were generated to provide uniform coverage that encompassed a 25-mile buffer of the Coastal Zone Management Act (CZMA) boundary at a spatial grid resolution of 100 km2 and 1 km2. The two resultant grid domains included all counties in the five Gulf states determined by the National Oceanic and Atmospheric Administration (NOAA) as contributing to coastal watersheds. The varying grid resolutions allowed for data to be spatially visualized both at a broad Gulf-wide scale on the 100 km2 grid as well as at a regional and project level scale on the 1 km2 grid. The data layers were synthesized into combined layers of potential stress, potential ecological benefits, and potential community benefits. These layers support broad scale prioritization for restoration efforts, based on likelihood of success and desired outcomes. The synthesized data were discussed in the context of the five goals and four priority criteria of the Gulf Coast Ecosystem Restoration Council’s (RESTORE Council) aim of using best available science (BAS) to guide future funding for restoration at large and small scales.

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Spatiotemporal Variability in ΔR in the Northern Gulf of Mexico, USA

Radiocarbon ◽

10.1017/rdc.2016.65 ◽

2016 ◽

Vol 59 (2) ◽

pp. 343-353 ◽

Cited By ~ 10

Author(s):

Carla S Hadden ◽

Alexander Cherkinsky

Keyword(s):

Gulf Of Mexico ◽

Gulf Coast ◽

Spatiotemporal Variability ◽

Major Influence ◽

Data Set ◽

Spatial And Temporal Scales ◽

Northern Gulf Of Mexico ◽

Northern Gulf Coast ◽

Gulf Coast Region ◽

Coast Region

AbstractStrombus alatus and Busycon sinistrum are large marine gastropods that are frequently recovered from archaeological contexts in southeastern North America. We previously proposed a reservoir age offset (ΔR) for B. sinistrum from the northern Gulf of Mexico region based on known-age pre-bomb 20th-century specimens. We also reported significant variability in radiocarbon both among and within S. alatus specimens, which precluded a reliable estimation of ΔR for this taxon. In this paper, we present a complementary data set from archaeological contexts to re-evaluate marine reservoir effects in the northern Gulf Coast region at multiple spatial and temporal scales. The new data set consists of a total of 13 14C age determinations from well-associated marine (B. sinistrum and S. alatus) and terrestrial (Odocoileus virginianus) samples from a closed context at the Bayou St. John (1BA21) archaeological site. We suggest a slightly updated ∆R value of –2±53 14C yr for late Holocene-age B. sinistrum from the northern Gulf Coast region. S. alatus, and possibly other species of strombid conchs, are poor candidates for 14C dating due to the highly variable 14C content observed within and among specimens. Though subregional variability in inputs of 14C-depleted waters is likely, life-history factors related to ontogenetic niche and/or habitat shifts appear to be a major influence in shell 14C for S. alatus.

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DISTRIBUTION OF STRUCTURAL STYLES IN THE NORTHERN GULF OF MEXICO AND GULF COAST

Gulf of Mexico Salt Tectonics, Associated Processes and Exploration Potential ◽

10.5724/gcs.89.10.0101 ◽

1989 ◽

Cited By ~ 6

Author(s):

J.A. LOPEZ

Keyword(s):

Gulf Of Mexico ◽

Gulf Coast ◽

Northern Gulf Of Mexico

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Holocene Climate and Climate Variability of the Northern Gulf of Mexico and Adjacent Northern Gulf Coast: A Review

The Open Paleontology Journal ◽

10.2174/1874425700801010007 ◽

2008 ◽

Vol 1 ◽

pp. 7-17 ◽

Cited By ~ 1

Author(s):

Richard Z Poore

Keyword(s):

Climate Variability ◽

Gulf Of Mexico ◽

Gulf Coast ◽

Holocene Climate ◽

Northern Gulf Of Mexico ◽

Northern Gulf Coast

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Warm Season Lightning Distributions over the Northern Gulf of Mexico Coast and Their Relation to Synoptic-Scale and Mesoscale Environments

Weather and Forecasting ◽

10.1175/waf870.1 ◽

2005 ◽

Vol 20 (4) ◽

pp. 415-438 ◽

Cited By ~ 16

Author(s):

Jessica R. Smith ◽

Henry E. Fuelberg ◽

Andrew I. Watson

Keyword(s):

Gulf Of Mexico ◽

Large Scale ◽

Gulf Coast ◽

Warm Season ◽

Sea Breeze ◽

Northern Gulf Of Mexico ◽

Low Level ◽

Lake Charles ◽

Northern Gulf Coast ◽

Mexico Coast

Abstract Cloud-to-ground lightning data from the National Lightning Detection Network are used to create a warm season (May–September) lightning climatology for the northern Gulf of Mexico coast for the 14-yr period 1989–2002. Each day is placed into one of five flow regimes based on the orientation of the low-level flow with respect to the coastline. This determination is made using the vector mean 1000–700-hPa wind data at Lake Charles and Slidell, Louisiana. Flash densities are calculated for daily, hourly, and nocturnal periods. Spatial patterns of composite 24-h and nocturnal flash density indicate that lightning decreases in an east-to-west direction over the region. Flash densities for the 24-h period are greatest over land near the coast, with relative maxima located near Houston, Texas; Lake Charles, Baton Rouge, and New Orleans, Louisiana; Biloxi, Mississippi; and Mobile, Alabama. Flash densities during the nocturnal period are greatest over the coastal waters. Lightning across the northern Gulf coast is closely related to the prevailing low-level synoptic flow, which controls the sea breeze, the dominant forcing mechanism during the warm season. Southwest flow, the most unstable and humid of the five regimes, exhibits the most flashes. In this case, sea-breeze-induced convection is located slightly inland from the coast. Northeast flow, the driest and most stable of the regimes, exhibits the least amount of lightning. The large-scale flow restricts the sea breeze to near the coastline. Geographic features and local mesoscale circulations are found to affect lightning across the region. Geographic features include lakes, bays, marshes, swamps, and coastline orientations. Thermal circulations associated with these features interact with the main sea breeze to produce complex lightning patterns over the area.

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