legacy of mid‐Holocene fire on a Tasmanian montane landscape

AIM: To assess the long‐term impacts of landscape fire on a mosaic of pyrophobic and pyrogenic woody montane vegetation. LOCATION: South‐west Tasmania, Australia. METHODS: We undertook a high‐resolution multiproxy palaeoecological analysis of sediments deposited in Lake Osborne (Hartz Mountains Nati...

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Published in:Journal of biogeography 2014-03, Vol.41 (3), p.476-488
Main Authors: Fletcher, Michael‐Shawn, Wolfe, Brent B, Whitlock, Cathy, Pompeani, David P, Heijnis, Hendrik, Haberle, Simon G, Gadd, Patricia S, Bowman, David M. J. S, Linder, Peter
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Athrotaxis
Biogeography
Biological and medical sciences
carbon
Charcoal
charcoal particles
climate
Climatic correlates and controls
Cupressaceae
El Nino
Eucalyptus
Eucryphia
extinction
fire
fires
Forest fires
Forestry
Fundamental and applied biological sciences. Psychology
General aspects
General forest ecology
Generalities. Production, biomass. Quality of wood and forest products. General forest ecology
geochemistry
ITRAX
lakes
mountains
national parks
nitrogen
Nothofagus
Nothofagus cunninghamii
Paleoclimatology
Pollen
rain forest
rain forests
Sediments
soil erosion
Southern Hemisphere
Synecology
Taxa
Temperate rain forests
Vegetation
Watersheds
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Summary:AIM: To assess the long‐term impacts of landscape fire on a mosaic of pyrophobic and pyrogenic woody montane vegetation. LOCATION: South‐west Tasmania, Australia. METHODS: We undertook a high‐resolution multiproxy palaeoecological analysis of sediments deposited in Lake Osborne (Hartz Mountains National Park, southern Tasmania), employing analyses of pollen, macroscopic and microscopic charcoal, organic and inorganic geochemistry and magnetic susceptibility. RESULTS: Sequential fires within the study catchment over the past 6500 years have resulted in the reduction of pyrophobic rain forest taxa and the establishment of pyrogenic Eucalyptus‐dominated vegetation. The vegetation change was accompanied by soil erosion and nutrient losses. The rate of post‐fire recovery of widespread rain forest taxa (Nothofagus cunninghamii and Eucryphia spp.) conforms to ecological models, as does the local extinction of fire‐sensitive rain forest taxa (Nothofagus gunnii and Cupressaceae) following successive fires. MAIN CONCLUSIONS: The sedimentary analyses indicate that recurrent fires over several centuries caused a catchment‐wide transition from pyrophobic rain forest to pyrophytic eucalypt‐dominated vegetation. The fires within the lake catchment during the 6500‐year long record appear to coincide with high‐frequency El Niño events in the equatorial Pacific Ocean, signalling a potential threat to these highly endemic rain forests if El Niño intensity amplifies as predicted under future climate scenarios.
ISSN:0305-0270
1365-2699
DOI:10.1111/jbi.12229