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Land loss in coastal Louisiana (U.S.A.) (1979)

Craig, N. J. ; Turner, R. E. ; Day, J. W.

Springer

Environmental management 3 (1979), S. 133-144

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ISSN: 1432-1009

Keywords: Coastal zone Management ; Fisheries ; Marshes ; Wetlands ; Louisiana

Source: Springer Online Journal Archives 1860-2000

Topics: Energy, Environment Protection, Nuclear Power Engineering

Notes: Abstract This paper examines causes and consequences of wetland losses in coastal Louisiana. Land loss is a cumulative impact, the result of many impacts both natural and artificial. Natural losses are caused by subsidence, decay of abandoned river deltas, waves, and storms. Artificial losses result from flood-control practices, impoundments, and dredging and subsequent erosion of artificial channels. Wetland loss also results from spoil disposal upon wetlands and land reclamation projects. Total land loss in Louisiana's coastal zone is at least 4,300 ha/year. Some wetlands are converted to spoil banks and other eco-systems so that wetland losses are probably two to three times higher. Annual wetland losses in the Barataria Bay basin are 2.6% of the wetland area. Human activities are the principal determinants of land loss. The present total wetland area directly lost because of canals may be close to 10% if spoil area is included. The interrelationship between hydrology, land, vegetation, substrate, subsidence, and sediment supply are complicated; however, hydrologic units with high canal density are generally associated with higher rates of land loss and the rate may be accelerating. Some cumulative impacts of land loss are increased saltwater intrusion, loss of capacity to buffer the impact of storms, and large additions of nutrients. One measure of the impact is that roughly $8–17 × 106 (U.S.A.) of fisheries products and services are lost annually in Louisiana. Viewed at the level of the hydrologic unit, land loss transcends differences in local vegetation, substrate, geology, and hydrology. Land management should therefore focus at that level of organization. Proper guideline recommendations require an appreciation of the long-term interrelations of the wetland estuarine system.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01867025

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Emittance of bare soil (1989)

Turner, R. E.

Springer

International journal of thermophysics 10 (1989), S. 527-533

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ISSN: 1572-9567

Keywords: emittance ; moisture content ; radiation properties ; soils

Source: Springer Online Journal Archives 1860-2000

Topics: Physics

Notes: Abstract The emittance of soils depends upon the moisture content, the porosity of the soil, the soil surface roughness, and the mineralogical properties of the soil particles. An attempt has been made to model the spectral emittance of soils in terms of these characteristics using deterministic and stochastic methods. For the general case of moist soil one must consider the fact that soil is basically a three-component system of air, water, and organic or inorganic material. For practical analysis using remote measurements one usually does not have knowledge of the relative amounts of each component. Thus, a stochastic model which specifies the emittance as functions of the statistics of the individual constituents seems to be the most reasonable practical approach for the analysis of soils. We have developed a stochastic model to represent the soil emittance in terms of probability distribution functions of the soil components. Also presented is a formula for soil emittance in terms of moisture content.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01133548

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The impact of accelerating land-use change on the N-Cycle of tropical aquatic ecosystems: Current conditions and projected changes (1999)

Downing, J. A. ; Mcclain, M. ; Twilley, R. ; [et al.]

Springer

Biogeochemistry 46 (1999), S. 109-148

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ISSN: 1573-515X

Keywords: estuaries ; lakes ; marine ; nitrogen ; phosphorus ; rivers ; streams ; temperate ; tropics

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology , Geosciences

Notes: Abstract Published data and analyses from temperate and tropical aquatic systems are used to summarize knowledge about the potential impact of land-use alteration on the nitrogen biogeochemistry of tropical aquatic ecosystems, identify important patterns and recommend key needs for research. The tropical N-cycle is traced from pre-disturbance conditions through the phases of disturbance, highlighting major differences between tropical and temperate systems that might influence development strategies in the tropics. Analyses suggest that tropical freshwaters are more frequently N-limited than temperate zones, while tropical marine systems may show more frequent P limitation. These analyses indicate that disturbances to pristine tropical lands will lead to greatly increased primary production in freshwaters and large changes in tropical freshwater communities. Increased freshwater nutrient flux will also lead to an expansion of the high production, N- and light-limited zones around river deltas, a switch from P- to N-limitation in calcareous marine systems, with large changes in the community composition of fragile mangrove and reef systems. Key information gaps are highlighted, including data on mechanisms of nutrient transport and atmospheric deposition in the tropics, nutrient and material retention capacities of tropical impoundments, and N/P coupling and stoichiometric impacts of nutrient supplies on tropical aquatic communities. The current base of biogeochemical data suggests that alterations in the N-cycle will have greater impacts on tropical aquatic ecosystems than those already observed in the temperate zone.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01007576

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