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Environmental Management of Soil Phosphorus : Modeling Spatial Variability in Small Fields

Needelman, Brian A. ; Gburek, William J. ; Sharpley, Andrew N. ; [weitere]

Wiley ; 2001

In: Soil Science Society of America Journal Vol. 65, No. 5 ( 2001-09), p. 1516-1522

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In: Soil Science Society of America Journal, Wiley, Vol. 65, No. 5 ( 2001-09), p. 1516-1522

Kurzfassung: The mapping of soil P concentration is necessary to assess the risk of P loss in runoff. We modeled the distribution of Mehlich‐3 extractable soil P (M3P) in an east‐central Pennsylvania 39.5‐ha watershed (FD‐36) with an average field size of 1.0 ha. Three interpolation models were used: (i) the field classification model—simple field means, (ii) the global model—ordinary kriging across the watershed, and (iii) the within‐field model—ordinary kriging within fields with a pooled within‐stratum variogram. Soils were sampled on a 30‐m grid, resulting in an average of 14 samples per field. Multiple validation runs were used to compare the models. Overall, the mean absolute errors (MAEs) of the models were 76, 71, and 66 mg kg −1 M3P for the field classification, global, and within‐field models, respectively. The field classification model performed substantially worse than did the kriging models in five fields; these fields exhibited strong spatial autocorrelation. The within‐field model performed substantially better than did the global model in three fields where autocorrelation was confined by the field boundary. However, no differences in P index classification were observed between the three prediction surfaces. The field classification model is simpler and less expensive to implement than the kriging models and should be adequate for applications that are not sensitive to small errors in soil P concentration estimates.

Materialart: Online-Ressource

ISSN: 0361-5995 , 1435-0661

URL: Article

DOI: 10.2136/sssaj2001.6551516x

RVK:

RA 4845

Sprache: Englisch

Verlag: Wiley

Publikationsdatum: 2001

ZDB Id: 241415-6

ZDB Id: 2239747-4

ZDB Id: 196788-5

ZDB Id: 1481691-X

SSG: 13

SSG: 21

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UNDERUTILIZED TOOLS: SEAWEEDS AS BIOREMEDIATION AND DIVERSIFICATION TOOLS AND BIOINDICATORS FOR INTE‐GRATED AQUACULTURE AND COASTAL MANAGEMENT

Wiley ; 2001

In: Journal of Phycology Vol. 37, No. s3 ( 2001-06), p. 12-12

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In: Journal of Phycology, Wiley, Vol. 37, No. s3 ( 2001-06), p. 12-12

Kurzfassung: Chopin, T. 1 , Yarish, C. 2 , Neefus, C. 3 , Kraemer, G. P. 4 , Belyea, E. 1 , Carmona, R. 2 , Saunders, G. W. 5 , Bates, C. 5 , Page, F. 6 & Dowd, M. 6 1 University of New Brunswick, Centre for Coastal Studies and Aquaculture and Centre for Environmental and Molecular Algal Research, P.O. Box 5050, Saint John, New Brunswick, E2L 4L5, Canada; 2 University of Connecticut, Department of Ecology and Evolutionary Biology, 1 University Place, Stamford, Connecticut, 06901‐2315, USA; 3 University of New Hampshire, Department of Plant Biology, Office of Biometrics, G32 Spaulding Life Science Center, Durham, New Hampshire, 03824, USA; 4 State University of New York, Purchase College, Division of Natural Sciences, Purchase, New York, 10577, USA; 5 University of New Brunswick, Centre for Environmental and Molecular Algal Research, P.O. Box 4400, Fredericton, New Brunswick, E3B 5A3, Canada; 6 Department of Fisheries and Oceans, Biological Station, 531 Brandy Cove Road, St. Andrews, New Brunswick, E5B 2L9, Canada On a regional scale, finfish aquaculture can be one of the significant contributors to coastal nutrification. Contrary to common belief, even in regions of exceptional tidal and apparent “flushing” regimes like the Bay of Fundy, water mixing and transport may be limited and water residency time can be locally prolonged. Hence, nutrient bio‐availability remains significant for a relatively long period of time in some areas. Understanding the assimilative capacity of coastal ecosystems under cumulative pressure, then, becomes critical. To avoid pronounced shifts in coastal processes, conversion, not dilution, is the solution by integrating fed aquaculture (finfish) with organic and inorganic extractive aquaculture (shellfish and seaweed) so that the “ wastes” of one resource user become a resource for the others. Such a bioremediative approach provides mutual benefits to co‐cultured organisms, and economic diversification and increased profitability per cultivation unit for the aquaculture industry. These concepts will be discussed and illustrated by the results of our on‐going projects and we will demonstrate that seaweeds can also be excellent bio‐indicators of nutrification/eutrophication revealing symptoms of environmental stress and measuring the zone of influence of an aquaculture site. The aquaculture industry is here to stay in our “coastal scape”: it has its place in the global seafood supply and demand, and in the economy of coastal communities. To help ensure its sustainability, it needs, however, to responsibly change its too often monotrophic practices by adopting polytrophic ones to become better integrated into a broader coastal management framework.

Materialart: Online-Ressource

ISSN: 0022-3646 , 1529-8817

URL: Issue

URL: Article

DOI: 10.1111/jpy.2001.37.issue-s3

DOI: 10.1111/j.1529-8817.2001.jpy37303-24.x

RVK:

WA 15000

Sprache: Englisch

Verlag: Wiley

Publikationsdatum: 2001

ZDB Id: 281226-5

ZDB Id: 1478748-9

SSG: 12

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