遥感变量能更好地预测 1000 公里以下尺度的草原多样性,而非生物变量则能更好地预测更大尺度的草原多样性

IF 7.3 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES
Earths Future Pub Date : 2024-11-04 DOI:10.1029/2024EF004648
Yujin Zhao, Bernhard Schmid, Zhaoju Zheng, Yang Wang, Jin Wu, Yao Wang, Ziyan Chen, Xia Zhao, Dan Zhao, Yuan Zeng, Yongfei Bai
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引用次数: 0

摘要

全球维管植物多样性的空间模式是根据气候主导的环境-多样性关系粗粒度绘制的,并在可能的情况下利用遥感技术进行细粒度绘制。然而,对于植株较小的草地来说,植被小区数据的有限性给物种多样性的精细绘制带来了很大的不确定性。在这里,我们利用来自 1,609 个野外地点的植被调查数据(4,000 个 1 平方米的小块)、遥感数据(生态系统生产力和物候学、栖息地异质性、功能特征和光谱多样性)以及非生物数据(与水和能源相关的、描述气候主导环境特征的数据),结合机器学习和空间自回归模型,以 500 米的分辨率预测和绘制了蒙古高原每 100 平方米草地的物种丰富度。结合所有变量得出的预测准确率为 69%,而使用遥感变量得出的准确率为 64%,或单独使用非生物变量得出的准确率为 65%。在遥感变量中,功能特征对物种丰富度估计的预测能力最高(55%),其次是生产力和物候(48%)、光谱多样性(48%)和生境异质性(48%)。考虑到空间自相关性,遥感变量的解释率为 52%,非生物变量的解释率为 41%。此外,遥感变量在较小粒度(<∼1,000 千米)上提供了更好的预测,而以水和能量为主的宏观环境变量是最重要的驱动因素,并主导了遥感变量在宏观尺度(>∼1,000 千米)上对多样性模式的影响。这些研究结果表明,遥感植被特征和以气候为主的宏观环境为绘制草原植物物种丰富度地图提供了相似的预测,它们在广阔的空间尺度上提供了互补的解释。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Remotely Sensed Variables Predict Grassland Diversity Better at Scales Below 1,000 km as Opposed to Abiotic Variables That Predict It Better at Larger Scales

Remotely Sensed Variables Predict Grassland Diversity Better at Scales Below 1,000 km as Opposed to Abiotic Variables That Predict It Better at Larger Scales

Global spatial patterns of vascular plant diversity have been mapped at coarse grain based on climate-dominated environment–diversity relationships and, where possible, at finer grain using remote sensing. However, for grasslands with their small plant sizes, the limited availability of vegetation plot data has caused large uncertainties in fine-grained mapping of species diversity. Here we used vegetation survey data from 1,609 field sites (>4,000 plots of 1 m2), remotely sensed data (ecosystem productivity and phenology, habitat heterogeneity, functional traits and spectral diversity), and abiotic data (water- and energy-related, characterizing climate-dominated environment) together with machine learning and spatial autoregressive models to predict and map grassland species richness per 100 m2 across the Mongolian Plateau at 500 m resolution. Combining all variables yielded a predictive accuracy of 69% compared with 64% using remotely sensed variables or 65% using abiotic variables alone. Among remotely sensed variables, functional traits showed the highest predictive power (55%) in species richness estimation, followed by productivity and phenology (48%), spectral diversity (48%) and habitat heterogeneity (48%). When considering spatial autocorrelation, remotely sensed variables explained 52% and abiotic variables explained 41%. Moreover, Remotely sensed variables provided better prediction at smaller grain size (<∼1,000 km), while water- and energy-dominated macro-environment variables were the most important drivers and dominated the effects of remotely sensed variables on diversity patterns at macro-scale (>∼1,000 km). These findings indicate that while remotely sensed vegetation characteristics and climate-dominated macro-environment provide similar predictions for mapping grassland plant species richness, they offer complementary explanations across broad spatial scales.

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来源期刊
Earths Future
Earths Future ENVIRONMENTAL SCIENCESGEOSCIENCES, MULTIDI-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
11.00
自引率
7.30%
发文量
260
审稿时长
16 weeks
期刊介绍: Earth’s Future: A transdisciplinary open access journal, Earth’s Future focuses on the state of the Earth and the prediction of the planet’s future. By publishing peer-reviewed articles as well as editorials, essays, reviews, and commentaries, this journal will be the preeminent scholarly resource on the Anthropocene. It will also help assess the risks and opportunities associated with environmental changes and challenges.
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