Your search keyword '"Montagu, Kelvin D."' showing total 3 results

1. Patterns of Below- and Aboveground Biomass in Eucalyptus populnea Woodland Communities of Northeast Australia along a Rainfall Gradient

Author

Zerihun, Ayalsew, Montagu, Kelvin D., Hoffmann, Madonna B., and Bray, Steven G.

Published

2006

2. Testing the generality of below-ground biomass allometry across plant functional types.

Author

Paul, Keryn I., Larmour, John, Specht, Alison, Zerihun, Ayalsew, Ritson, Peter, Roxburgh, Stephen H., Sochacki, Stan, Lewis, Tom, Barton, Craig V.M., England, Jacqueline R., Battaglia, Michael, O'Grady, Anthony, Pinkard, Elizabeth, Applegate, Grahame, Jonson, Justin, Brooksbank, Kim, Sudmeyer, Rob, Wildy, Dan, Montagu, Kelvin D., and Bradford, Matt

Subjects

BIOMASS, ALLOMETRY in plants, EUCALYPTUS, SHRUBS, WOODY plants, CARBON cycle

Abstract

Highlights • Over 2000 measurements of plant belowground biomass were compiled. • Accurate generic allometric models could be developed. • These models were validated across stands where whole-plot excavation data were available. • Gains in prediction efficiencies using species-specific models were negligible. Abstract Accurate quantification of below-ground biomass (BGB) of woody vegetation is critical to understanding ecosystem function and potential for climate change mitigation from sequestration of biomass carbon. We compiled 2054 measurements of planted and natural individual tree and shrub biomass from across different regions of Australia (arid shrublands to tropical rainforests) to develop allometric models for prediction of BGB. We found that the relationship between BGB and stem diameter was generic, with a simple power-law model having a BGB prediction efficiency of 72–93% for four broad plant functional types: (i) shrubs and Acacia trees, (ii) multi-stemmed mallee eucalypts, (iii) other trees of relatively high wood density, and; (iv) a species of relatively low wood density, Pinus radiata D. Don. There was little improvement in accuracy of model prediction by including variables (e.g. climatic characteristics, stand age or management) in addition to stem diameter alone. We further assessed the generality of the plant functional type models across 11 contrasting stands where data from whole-plot excavation of BGB were available. The efficiency of model prediction of stand-based BGB was 93%, with a mean absolute prediction error of only 6.5%, and with no improvements in validation results when species-specific models were applied. Given the high prediction performance of the generalised models, we suggest that additional costs associated with the development of new species-specific models for estimating BGB are only warranted when gains in accuracy of stand-based predictions are justifiable, such as for a high-biomass stand comprising only one or two dominant species. However, generic models based on plant functional type should not be applied where stands are dominated by species that are unusual in their morphology and unlikely to conform to the generalised plant functional group models. [ABSTRACT FROM AUTHOR]

Published

2019

3. Testing the generality of above-ground biomass allometry across plant functional types at the continent scale.

Author

Paul, Keryn I., Roxburgh, Stephen H., Chave, Jerome, England, Jacqueline R., Zerihun, Ayalsew, Specht, Alison, Lewis, Tom, Bennett, Lauren T., Baker, Thomas G., Adams, Mark A., Huxtable, Dan, Montagu, Kelvin D., Falster, Daniel S., Feller, Mike, Sochacki, Stan, Ritson, Peter, Bastin, Gary, Bartle, John, Wildy, Dan, and Hobbs, Trevor

Subjects

PLANT biomass, ALLOMETRY, DENSITY, EUCALYPTUS, SHRUBS, RAIN forests

Abstract

Accurate ground-based estimation of the carbon stored in terrestrial ecosystems is critical to quantifying the global carbon budget. Allometric models provide cost-effective methods for biomass prediction. But do such models vary with ecoregion or plant functional type? We compiled 15 054 measurements of individual tree or shrub biomass from across Australia to examine the generality of allometric models for above-ground biomass prediction. This provided a robust case study because Australia includes ecoregions ranging from arid shrublands to tropical rainforests, and has a rich history of biomass research, particularly in planted forests. Regardless of ecoregion, for five broad categories of plant functional type (shrubs; multistemmed trees; trees of the genus Eucalyptus and closely related genera; other trees of high wood density; and other trees of low wood density), relationships between biomass and stem diameter were generic. Simple power-law models explained 84-95% of the variation in biomass, with little improvement in model performance when other plant variables (height, bole wood density), or site characteristics (climate, age, management) were included. Predictions of stand-based biomass from allometric models of varying levels of generalization (species-specific, plant functional type) were validated using whole-plot harvest data from 17 contrasting stands (range: 9-356 Mg ha−1). Losses in efficiency of prediction were <1% if generalized models were used in place of species-specific models. Furthermore, application of generalized multispecies models did not introduce significant bias in biomass prediction in 92% of the 53 species tested. Further, overall efficiency of stand-level biomass prediction was 99%, with a mean absolute prediction error of only 13%. Hence, for cost-effective prediction of biomass across a wide range of stands, we recommend use of generic allometric models based on plant functional types. Development of new species-specific models is only warranted when gains in accuracy of stand-based predictions are relatively high (e.g. high-value monocultures). [ABSTRACT FROM AUTHOR]

Published

2016