Riparian Plant Material Inputs to the Murray River, Australia. Composition, Reactivity, and Role of Nutrients

By changing riparian plants from Eucalypts to pasture and exotic deciduous trees, modern development has altered the type of carbon assimilated by Australian rivers. To investigate influences of plant litter substrates on biochemical oxygen demand, plant materials entering the Murray River were anal...

Full description

Saved in:
Bibliographic Details
Published in:Journal of environmental quality 2007-07, Vol.36 (4), p.963-974
Main Authors: Eslemont, G, Maher, W, Ford, P, Lawrence, I
Format: Article
Language:English
Subjects:
Acacia
Aquatic plants
Australia
Bark
bioavailability
Biochemical oxygen demand
Biogeochemistry
Carbon
Carbon - analysis
Carbon Isotopes - analysis
Casuarina
chemical composition
chemical constituents of plants
Comparative studies
Decay
Deciduous trees
Ecologists
Ecosystem
Eucalyptus
Freshwater
Freshwater ecology
Grasses
Herbs
Land use
Leaves
Litter
Mineralization
Nitrogen - analysis
nitrogen content
Nitrogen Isotopes - analysis
Nutrient availability
nutrient content
Oxygen Consumption
Pasture
phosphorus
Phosphorus - analysis
Plant communities
plant litter
Plants - chemistry
Reference Values
riparian areas
River ecology
Rivers
Rivers - chemistry
Salix
Trees
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:By changing riparian plants from Eucalypts to pasture and exotic deciduous trees, modern development has altered the type of carbon assimilated by Australian rivers. To investigate influences of plant litter substrates on biochemical oxygen demand, plant materials entering the Murray River were analyzed for their composition and mineralization potential. Plant materials were distinguished compositionally by two principal components, structural carbon and macronutrients, as: (i) Eucalyptus leaves, (ii) Eucalyptus bark and Casuarina cunninghamiana seed cone, (iii) grasses, (iv) macrophytes, (v) aquatic herbs, (vi) non-eucalypt leaf (Salix, Casuarina, Acacia). Ratios of C/P (1879-14524) and C/N (65-267) were relatively high in Eucalyptus bark, while mean N/P (7-60) ratios were similar among plant materials. Terrestrial weathering increased C/P and C/N ratios, while N/P ratios remained similar, due to greater loss of N and P relative to C. Aerobic decay experiments showed that nutrient supplementation accelerated decay of all organic substrates, except for grasses that decayed efficiently without supplementation. Aquatic herbs also had substantial carbon availability, macrophytes and non-eucalypt leaves had intermediate carbon availability, while eucalypt leaf and bark had intermediate to low carbon availabilities. Because biochemical oxygen demand varies with organic substrates sampled from the Murray River, and also with soluble nutrient availability, it is plausible that that modern changes to riverine plant communities and land use have influenced the biogeochemistry of this river toward faster, and more complete, processing of allochthonous carbon.
ISSN:0047-2425
1537-2537
DOI:10.2134/jeq2006.0318