期刊
JOURNAL OF BIOGEOGRAPHY
卷 45, 期 8, 页码 1768-1780出版社
WILEY
DOI: 10.1111/jbi.13364
关键词
climate change; conifers; pollen-vegetation calibration; postglacial; stability; Yellowstone
资金
- National Science Foundation [EAR 0818467, EPS 1101342, OISE 0966472]
AimReconstruct the long-term ecosystem dynamics of the region across an elevational gradient as they relate to climate and local controls. In particular, we (1) describe the dominant conifers' history; (2) assess changes in vegetation composition and distribution; and (3) note periods of abrupt change versus stability as means of better understanding vegetation responses to environmental variability. LocationGreater Yellowstone Ecosystem (GYE; USA). Time period16.5ka bp-present. Major taxa studiedJuniperus, Picea, Abies, Pinus, Pseudotsuga. MethodsThe vegetation reconstruction was developed from 15 pollen records. Results were interpreted based on modern pollen-vegetation relationships estimated from a suite of regression-based approaches. ResultsCalibrated pollen data suggest that late-glacial vegetation, dominated by shrubs and Juniperus, lacks a modern counterpart in the area. Picea, Abies and Pinus expanded at 16ka bp in association with postglacial warming and co-occurred in mixed-conifer parkland/forest after 12ka bp. This association along with Pinus contorta forest, which was present after 9ka bp, has persisted with little change at middle and high elevations to the present day. This stability contrasts with the dynamic history of plant communities at low elevations, where shifts between parkland, steppe and forest over the last 8,000years were likely driven by variations in effective moisture and fire. Main conclusionsThe postglacial vegetation history of the GYE highlights the dynamic nature of mountain ecosystems and informs on their vulnerability to future climate change: (1) most of the conifers have been present in the area for >12,000years and survived climate change by adjusting their elevational ranges; (2) some plant associations have exhibited stability over millennia as a result of nonclimatic controls; and (3) present-day forest cover is elevationally more compressed than at any time in history, probably due to the legacy of the Medieval Climate Anomaly and the Little Ice Age.
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