Lowland tundra plant stoichiometry is somewhat resilient decades following fire despite substantial and sustained shifts in community structure

IF 1.6 4区地球科学 Q4 ENVIRONMENTAL SCIENCES Arctic, Antarctic, and Alpine Research Pub Date : 2022-10-20 DOI:10.1080/15230430.2022.2121246

Natalie Baillargeon, G. Pold, S. Natali, S. Sistla

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引用次数: 1

Abstract

ABSTRACT The Arctic is experiencing the greatest increase in average surface temperature globally, which is projected to amplify wildfire frequency and severity. Wildfire alters the biogeochemical characteristics of arctic ecosystems. However, the extent of these changes over time—particularly with regard to plant stoichiometries relative to community structure—is not well documented. Four years after the Yukon-Kuskokwim Delta, Alaska, experienced its largest fire season, aboveground plant and lichen biomass was harvested across a gradient of burn history: unburned (“reference”), 2015 burn (“recent burn”), and 1972 burn (“historic burn”) to assess the resilience of tundra plant communities to fire disturbance. Fire reduced aboveground biomass in the recent burn; early recovery was characterized by evergreen shrub and graminoid dominance. In the historic burn, aboveground biomass approached reference conditions despite a sustained reduction of lichen biomass. Although total plant and lichen carbon (C) and nitrogen (N) were reduced immediately following fire, N stocks recovered to a greater degree—reducing community-level C:N. Notably, at the species level, N enrichment was observed only in the recent burn. Yet, community restructuring persisted for decades following fire, reflecting a sustained reduction in N-poor lichens relative to more N-rich vascular plant species.

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低地冻土带植物化学计量在火灾发生后的几十年里具有一定的弹性，尽管群落结构发生了实质性和持续的变化

北极正在经历全球平均地表温度的最大增长，预计这将增加野火的频率和严重程度。野火改变了北极生态系统的生物地球化学特征。然而，随着时间的推移，这些变化的程度，特别是相对于群落结构的植物化学计量学，并没有很好的文献记录。在阿拉斯加育空-库斯科维姆三角洲经历了其最大的火灾季节四年后，地上植物和地衣生物量在燃烧历史的梯度中被收集:未燃烧(“参考”)，2015年燃烧(“最近燃烧”)和1972年燃烧(“历史燃烧”)，以评估冻土带植物群落对火灾干扰的恢复能力。在最近的燃烧中，火灾减少了地上生物量;早期恢复以常绿灌木为主，禾本科占优势。在历史燃烧中，地上生物量接近参考条件，尽管地衣生物量持续减少。尽管火灾发生后植物和地衣的总碳(C)和氮(N)立即减少，但N储量恢复的程度更大，降低了群落水平的C:N。值得注意的是，在物种水平上，仅在最近的燃烧中观察到N富集。然而，群落结构在火灾后持续了几十年，反映了相对于富氮维管植物物种，缺氮地衣的持续减少。

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来源期刊

Arctic, Antarctic, and Alpine Research 地学-环境科学

CiteScore

3.00

自引率

5.00%

发文量

审稿时长

7 months

期刊介绍： The mission of Arctic, Antarctic, and Alpine Research (AAAR) is to advance understanding of cold region environments by publishing original scientific research from past, present and future high-latitude and mountain regions. Rapid environmental change occurring in cold regions today highlights the global importance of this research. AAAR publishes peer-reviewed interdisciplinary papers including original research papers, short communications and review articles. Many of these papers synthesize a variety of disciplines including ecology, climatology, geomorphology, glaciology, hydrology, paleoceanography, biogeochemistry, and social science. Papers may be uni- or multidisciplinary but should have interdisciplinary appeal. Special thematic issues and proceedings are encouraged. The journal receives contributions from a diverse group of international authors from academia, government agencies, and land managers. In addition the journal publishes opinion pieces, book reviews and in memoria. AAAR is associated with the Institute of Arctic and Alpine Research (INSTAAR) the oldest active research institute at the University of Colorado Boulder.