利用机载激光引导成像光谱技术绘制森林特征多样性图谱并指导保护工作。

Airborne laser-guided imaging spectroscopy to map forest trait diversity and guide conservation.

机构信息

Department of Global Ecology, Carnegie Institution for Science, 260 Panama Street, Stanford, CA 94305, USA.

Dirección General de Ordenamiento Territorial, Ministerio del Ambiente, San Isidro, Lima, Perú.

出版信息

Science. 2017 Jan 27;355(6323):385-389. doi: 10.1126/science.aaj1987.

DOI:10.1126/science.aaj1987

PMID:28126815

Abstract

Functional biogeography may bridge a gap between field-based biodiversity information and satellite-based Earth system studies, thereby supporting conservation plans to protect more species and their contributions to ecosystem functioning. We used airborne laser-guided imaging spectroscopy with environmental modeling to derive large-scale, multivariate forest canopy functional trait maps of the Peruvian Andes-to-Amazon biodiversity hotspot. Seven mapped canopy traits revealed functional variation in a geospatial pattern explained by geology, topography, hydrology, and climate. Clustering of canopy traits yielded a map of forest beta functional diversity for land-use analysis. Up to 53% of each mapped, functionally distinct forest presents an opportunity for new conservation action. Mapping functional diversity advances our understanding of the biosphere to conserve more biodiversity in the face of land use and climate change.

摘要

功能生物地理学可以弥合基于实地的生物多样性信息与基于卫星的地球系统研究之间的差距，从而支持保护计划，以保护更多的物种及其对生态系统功能的贡献。我们使用机载激光引导成像光谱学和环境建模，得出了秘鲁安第斯山脉到亚马逊生物多样性热点地区的大规模、多变量森林冠层功能特征图谱。七种绘制的冠层特征揭示了由地质、地形、水文和气候解释的地理空间模式中的功能变化。冠层特征的聚类产生了用于土地利用分析的森林β功能多样性图谱。多达 53%的每个具有独特功能的绘制森林都为新的保护行动提供了机会。绘制功能多样性图谱可以提高我们对生物圈的理解，以在面对土地利用和气候变化时保护更多的生物多样性。

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利用机载激光引导成像光谱技术绘制森林特征多样性图谱并指导保护工作。

Airborne laser-guided imaging spectroscopy to map forest trait diversity and guide conservation.

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