Biomass-modulated fire dynamics during the Last Glacial–Interglacial Transition at the Central Pyrenees (Spain)

Understanding long-term fire ecology is essential for current day interpretation of ecosystem fire responses. However palaeoecology of fire is still poorly understood, especially at high-altitude mountain environments, despite the fact that these are fire-sensitive ecosystems and their resilience mi...

Full description

Saved in:
Bibliographic Details
Published in:Palaeogeography, palaeoclimatology, palaeoecology palaeoclimatology, palaeoecology, 2014-05, Vol.402, p.113-124
Main Authors: Gil-Romera, Graciela, González-Sampériz, Penélope, Lasheras-Álvarez, Laura, Sevilla-Callejo, Miguel, Moreno, Ana, Valero-Garcés, Blas, López-Merino, Lourdes, Carrión, José S., Pérez Sanz, Ana, Aranbarri, Josu, García-Prieto Fronce, Eduardo
Format: Article
Language:English
Subjects:
Fire history
Historical biogeography
Iberian Peninsula
Lateglacial
Palaeoecology
Quaternary
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Understanding long-term fire ecology is essential for current day interpretation of ecosystem fire responses. However palaeoecology of fire is still poorly understood, especially at high-altitude mountain environments, despite the fact that these are fire-sensitive ecosystems and their resilience might be affected by changing fire regimes. We reconstruct wildfire occurrence since the Lateglacial (14.7calka BP) to the Mid-Holocene (6calka BP) and investigate the climate–fuel–fire relationships in a sedimentary sequence located at the treeline in the Central Spanish Pyrenees. Pollen, macro- and micro-charcoal were analysed for the identification of fire events (FE) in order to detect vegetation post-fire response and to define biomass–fire interactions. mean fire intervals (mfi) reduced since the Lateglacial, peaking at 9–7.7calka BP while from 7.7 to 6calka BP no fire is recorded. We hypothesise that Early Holocene maximum summer insolation, as climate forcing, and mesophyte forest expansion, as a fuel-creating factor, were responsible for accelerating fire occurrence in the Central Pyrenees treeline. We also found that fire had long-lasting negative effects on most of the treeline plant communities and that forest contraction from 7.7calka BP is likely linked to the ecosystem's threshold response to high fire frequencies. •Late Quaternary fire regime is studied in a fuel-limited, high-altitude site.•Biomass is a key factor accelerating fire frequency under a fire-conducive climate.•Mesophytes enhance fires due to its flammability and fast spread.•Frequent fire events between 10-8 kyrs BP avoided arboreal recovery after 7 kyr BP.•Pollen richness is not influenced by fire but it covaries with landscape opening.
ISSN:0031-0182
1872-616X
DOI:10.1016/j.palaeo.2014.03.015