Biophysical effects of an old tundra fire in the Brooks Range Foothills of Northern Alaska, U.S.A

IF 1.5 4区地球科学 Q3 ECOLOGY Polar Science Pub Date : 2024-03-01 DOI:10.1016/j.polar.2023.100984

Eric A. Miller , Carson A. Baughman , Benjamin M. Jones , Randi R. Jandt

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Abstract

Our understanding of tundra fire effects in Northern Alaska is limited because fires have been relatively rare. We sampled a 70+ year-old burn visible in a 1948 aerial photograph for vegetation composition and structure, soil attributes, terrain rugosity, and thermokarst pit density. Between 1948 and 2017 the burn initially became wetter as ice wedges melted but then drained and dried as the troughs became hydrologically connected. The reference tundra has become wetter over the last few decades and appears to be lagging through a similar sequence. The burn averaged 2.5 °C warmer than the reference tundra at 30 cm depth. Thinning of organic soil following fire appears to dramatically accelerate the background degradation of ground-ice features in response to climate change and promotes a plant community that is distinct in terms of taxa and structure, dominated by tall willows and other competitive, rather than cold-tolerant, species. The cover of sedges and mosses is low while that of willows and grass is high relative to the reference tundra. The changes in plant community composition and structure, increasing ground temperature, and thermokarst lead us to expect the observed biophysical changes to the tundra will persist centuries into the future.

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美国阿拉斯加北部布鲁克斯山脉山麓老苔原火灾的生物物理效应

由于火灾相对罕见，我们对阿拉斯加北部苔原火灾影响的了解十分有限。我们对 1948 年航拍照片中可见的 70 多年前的燃烧区进行了采样，以了解植被组成和结构、土壤属性、地形崎岖度和热陨石坑密度。在 1948 年至 2017 年期间，随着冰楔的融化，焚烧区最初变得更加潮湿，但随着水槽的水文连接，焚烧区随之干涸。参考冻原在过去几十年间变得更加湿润，似乎也经历了类似的变化过程。在 30 厘米深处，燃烧后的温度平均比参照冻土层高 2.5 °C。火灾后对有机土壤的稀释似乎大大加快了地冰特征因气候变化而发生的背景退化，并促进了植物群落在类群和结构方面的独特性，该群落以高大的柳树和其他竞争性而非耐寒物种为主。与参考冻原相比，莎草和苔藓的覆盖率较低，而柳树和草的覆盖率较高。植物群落组成和结构的变化、地面温度的升高以及热沼泽的出现，使我们预计所观测到的苔原生物物理变化将持续几个世纪。

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来源期刊

Polar Science ECOLOGY-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

3.90

自引率

5.60%

发文量

期刊介绍： Polar Science is an international, peer-reviewed quarterly journal. It is dedicated to publishing original research articles for sciences relating to the polar regions of the Earth and other planets. Polar Science aims to cover 15 disciplines which are listed below; they cover most aspects of physical sciences, geosciences and life sciences, together with engineering and social sciences. Articles should attract the interest of broad polar science communities, and not be limited to the interests of those who work under specific research subjects. Polar Science also has an Open Archive whereby published articles are made freely available from ScienceDirect after an embargo period of 24 months from the date of publication. - Space and upper atmosphere physics - Atmospheric science/climatology - Glaciology - Oceanography/sea ice studies - Geology/petrology - Solid earth geophysics/seismology - Marine Earth science - Geomorphology/Cenozoic-Quaternary geology - Meteoritics - Terrestrial biology - Marine biology - Animal ecology - Environment - Polar Engineering - Humanities and social sciences.