卫星监测植被碳吸收的原则

I. Colin Prentice, Manuela Balzarolo, Keith J. Bloomfield, Jing M. Chen  , Benjamin Dechant, Darren Ghent, Ivan A. Janssens, Xiangzhong Luo  , Catherine Morfopoulos, Youngryel Ryu, Sara Vicca, Roel van Hoolst
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摘要

基于遥感的数值模式利用卫星对植被光吸收的测量来估算全球总初级生产力(GPP)的模式和趋势--这是陆地碳循环的基础。在本《视角》中,我们将讨论利用这些模型估算 GPP 所面临的挑战,并探讨提高其可靠性的方法。目前的模型在结构上差异很大,产生的结果也不尽相同,尤其是在 GPP 的时间趋势方面。许多模型都引用光利用效率原理来估算 GPP,该原理将光吸收与光合作用和植物生物量生产联系起来。然而,这些模型对光利用效率控制的假设各不相同,而且通常依赖于许多约束性较差的参数。生态进化优化原理可以大大减少参数要求,提高 GPP 估算的准确性和一致性,并解释其与环境驱动因素的关系。整合不同卫星和传感器的数据,并利用辅助光学波段检索,可以提高时空分辨率,改进基于模型的植被生理检测,包括干旱胁迫。扩展和协调涡度协方差通量塔网络将支持对 GPP 模型进行系统评估。提高 GPP 和生物量生产估算的可靠性将更好地描述时间变化特征,并促进对陆地碳循环对环境变化的响应的理解。全球初级生产力的模式和趋势是利用遥感模型估算的。本视角概述了如何确保下一代模式预测能够有力地描述陆地碳循环的这一关键要素是如何变化的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Principles for satellite monitoring of vegetation carbon uptake
Remote-sensing-based numerical models harness satellite-borne measurements of light absorption by vegetation to estimate global patterns and trends in gross primary production (GPP) — the basis of the terrestrial carbon cycle. In this Perspective, we discuss the challenges in estimating GPP using these models and explore ways to improve their reliability. Current models vary substantially in their structure and produce differing results, especially regarding temporal trends in GPP. Many models invoke the light use efficiency principle, which links light absorption to photosynthesis and plant biomass production, to estimate GPP. However, these models vary in their assumptions about the controls of light use efficiency and typically depend on many, poorly constrained parameters. Eco-evolutionary optimality principles can greatly reduce parameter requirements, improving the accuracy and consistency of GPP estimates and interpretations of their relationships with environmental drivers. Integrating data across different satellites and sensors, and utilizing auxiliary optical band retrievals, could enhance spatiotemporal resolution and improve model-based detection of vegetation physiology, including drought stress. Extending and harmonizing the eddy-covariance flux-tower network will support systematic evaluation of GPP models. Improved reliability of GPP and biomass production estimates will better characterize temporal variation and advance understanding of the response of the terrestrial carbon cycle to environmental change. Global patterns and trends in primary production are estimated using remote-sensing-based models. This Perspective outlines ways to ensure that the next generation of model predictions robustly characterizes how this key element of the terrestrial carbon cycle is changing.
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