遥测南极洲泰勒谷积雪微生境光合生物群落的特征

IF 5.7 Q1 ENVIRONMENTAL SCIENCES
Sarah N. Power , Mark R. Salvatore , Eric R. Sokol , Lee F. Stanish , Schuyler R. Borges , Byron J. Adams , J.E. Barrett
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引用次数: 0

摘要

微生物群落是南极洲麦克默多干谷碳循环的主要驱动力。密集的微生物垫主要由光合蓝藻组成,占据着与溪流和湖泊相关的水生区域。其他微生物群落也以较低的密度出现在陆地景观中,形成斑块状的地表生物土壤结壳(以下简称生物结壳)。多谱段卫星数据已被用于模拟溪流和湖泊边缘等高密度区域的微生物垫丰度,但以前的研究还没有调查过生物结壳的较低检测限。在这里,我们介绍了遥感和实地调查与取样方法,以研究麦克默多干谷生物簇的可探测性和分布情况。我们结合使用多光谱和高光谱工具以及光谱线性非混合法,对泰勒谷东部的生物壳丰度进行了建模。我们的光谱方法可以检测到实验室微观世界中的低质量生物簇物质,生物簇的质量浓度可低至 1%。这些技术还能将生物岩屑的光谱与来自轨道的地表岩石和矿物特征区分开来。我们发现生物簇存在于泰勒谷东部的土壤中,并与多种底层土壤群落相关联。本研究中发现的最密集的生物簇群落的总有机碳含量是典型干旱土壤的 5 倍。最富饶的生物簇位于融化雪堆的下坡,处于独特的土壤生态系统中,与周围的干旱地貌截然不同。与典型的干旱山谷陆地生态系统相比,雪堆和溪流沉积物群落(土壤无脊椎动物多样性高)及其生态系统特性(如液态水的持久性、可用养分的高转移性、冲刷造成的较低盐度)具有相似性。我们的方法将光合作用群落的轨道遥感能力从水生边缘扩展到了构成大部分地貌的较干燥土壤。这项跨学科工作对于测量和监测陆地碳储量以及预测目前水资源有限但日益动态的南极地貌未来的生态系统动态至关重要,因为南极地貌对气候特别敏感,而且难以进入。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Remotely characterizing photosynthetic biocrust in snowpack-fed microhabitats of Taylor Valley, Antarctica

Microbial communities are the primary drivers of carbon cycling in the McMurdo Dry Valleys of Antarctica. Dense microbial mats, consisting mainly of photosynthetic cyanobacteria, occupy aquatic areas associated with streams and lakes. Other microbial communities also occur at lower densities as patchy surface biological soil crusts (hereafter, biocrusts) across the terrestrial landscape. Multispectral satellite data have been used to model microbial mat abundance in high-density areas like stream and lake margins, but no previous studies have investigated the lower detection limits of biocrusts. Here, we describe remote sensing and field-based survey and sampling approaches to study the detectability and distribution of biocrusts in the McMurdo Dry Valleys. Using a combination of multi- and hyperspectral tools and spectral linear unmixing, we modeled the abundances of biocrust in eastern Taylor Valley. Our spectral approaches can detect low masses of biocrust material in laboratory microcosms down to biocrust concentrations of 1% by mass. These techniques also distinguish the spectra of biocrust from both surface rock and mineral signatures from orbit. We found that biocrusts are present throughout the soils of eastern Taylor Valley and are associated with diverse underlying soil communities. The densest biocrust communities identified in this study had total organic carbon 5x greater than the content of typical arid soils. The most productive biocrusts were located downslope of melting snowpacks in unique soil ecosystems that are distinct from the surrounding arid landscape. There are similarities between the snowpack and stream sediment communities (high diversity of soil invertebrates) as well as their ecosystem properties (e.g., persistence of liquid water, high transfer of available nutrients, lower salinity from flushing) compared to the typical arid terrestrial ecosystem of the dry valleys. Our approach extends the capability of orbital remote sensing of photosynthetic communities out of the aquatic margins and into the drier soils which comprise most of this landscape. This interdisciplinary work is critical for measuring and monitoring terrestrial carbon stocks and predicting future ecosystem dynamics in this currently water-limited but increasingly dynamic Antarctic landscape, which is particularly climate-sensitive and difficult to access.

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