Improved GPP upscaling from instantaneous measurements to daily sums using the light-use-efficiency-based model

IF 5.6 1区农林科学 Q1 AGRONOMY

Agricultural and Forest Meteorology Pub Date : 2025-04-12 DOI:10.1016/j.agrformet.2025.110529

Ruonan Chen , Xinjie Liu , Liangyun Liu

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引用次数: 0

Abstract

The rapid development of satellite technology has greatly contributed to the estimation of global terrestrial gross primary productivity (GPP). However, most satellites only obtain instantaneous photosynthetic signals at overpass time. Given the demand for all-day GPP in application studies, this leads to the problem of gaps. Therefore, a temporal upscaling process is needed for daily GPP estimation. Most traditional methods consider the change in the total amount of incident light during a day while ignoring the impact of light use efficiency (LUE) on the diurnal trajectories of GPP, which produces uncertainties in the temporally upscaled results. In this study, using simulations from the SCOPE model and tower-based measurements, we find that the diurnal shape of GPP trajectories is dependent on the latitude of site, DOY, and LAI. By investigating how the canopy structure (LAI employed in this study) influences the light response of LUE and subsequently affects diurnal variations in GPP, we proposed a temporal upscaling method considering the diurnal variation in LUE at the canopy scale. To account for the impact of varying temperature and moisture throughout the day, an asymmetric correction factor was also included. Compared with previous upscaling schemes based on the cosine of SZA, PAR, PAR×NDVI, etc., our LUE-based method showed higher R² and lower RMSE values on both simulations (R² of 0.993, ∆ R² up to 0.008; RMSE of 0.274 gC m⁻² d⁻¹, ∆ RMSE up to 0.058 gC m⁻² d⁻¹,which is 1.763 % of the mean simulated GPP) and tower-based observations (average R² of 0.970, ∆ R² up to 0.09; average RMSE of 0.453 gC m⁻² d⁻¹, ∆ RMSE up to 0.410 gC m⁻² d⁻¹, which is 7.70 % of the mean observed GPP). Moreover, it outperforms traditional methods in low LAI conditions and at low-latitude sites where upscaling is more challenging. Therefore, the LUE-based method exhibits higher robustness, smaller disparities across sites, and less dependence on the time window, which is of great importance for the better estimation of daily GPP from instantaneous satellite observations.

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利用基于光利用效率的模型，改进从瞬时测量到每日总和的全球植被覆盖率提升方法

卫星技术的快速发展极大地促进了全球陆地总初级生产力（GPP）的估算。然而，大多数卫星只能获得过站时间的瞬时光合作用信号。鉴于应用研究需要全天的 GPP，这就导致了缺口问题。因此，需要一个时间放大过程来估算每日的 GPP。大多数传统方法考虑的是一天中入射光总量的变化，而忽略了光利用效率（LUE）对昼夜 GPP 轨迹的影响，这就给时间放大结果带来了不确定性。在这项研究中，我们利用 SCOPE 模型模拟和塔式测量结果，发现 GPP 的昼夜变化轨迹与地点纬度、DOY 和 LAI 有关。通过研究冠层结构（本研究采用的 LAI）如何影响 LUE 的光响应并进而影响 GPP 的日变化，我们提出了一种考虑冠层尺度 LUE 日变化的时间放大方法。为了考虑全天温度和湿度变化的影响，我们还加入了非对称校正因子。与之前基于 SZA、PAR、PAR×NDVI 等的余弦值的放大方案相比，我们基于 LUE 的方法显示出更高的 R 值、我们基于 LUE 的方法在两次模拟中都显示出较高的 R2 值和较低的 RMSE 值（R2 为 0.993，∆ R2 高达 0.008；RMSE 为 0.274 gC m-2 d-1，∆ RMSE 高达 0.058 gC m-2 d-1，是模拟 GDP 平均值的 1.平均 R2 为 0.970，∆ R2 高达 0.09；平均 RMSE 为 0.453 gC m-2 d-1，∆ RMSE 高达 0.410 gC m-2 d-1，为平均观测 GPP 的 7.70%）。此外，在低 LAI 条件下，以及在低纬度地点，它的表现优于传统方法，因为在低纬度地点，上规模更具有挑战性。因此，基于 LUE 的方法表现出更高的鲁棒性、更小的站点差异和更小的时间窗口依赖性，这对于更好地从瞬时卫星观测中估算日 GPP 非常重要。

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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来源期刊

Agricultural and Forest Meteorology 农林科学-林学

CiteScore

10.30

自引率

9.70%

发文量

415

审稿时长

69 days

期刊介绍： Agricultural and Forest Meteorology is an international journal for the publication of original articles and reviews on the inter-relationship between meteorology, agriculture, forestry, and natural ecosystems. Emphasis is on basic and applied scientific research relevant to practical problems in the field of plant and soil sciences, ecology and biogeochemistry as affected by weather as well as climate variability and change. Theoretical models should be tested against experimental data. Articles must appeal to an international audience. Special issues devoted to single topics are also published. Typical topics include canopy micrometeorology (e.g. canopy radiation transfer, turbulence near the ground, evapotranspiration, energy balance, fluxes of trace gases), micrometeorological instrumentation (e.g., sensors for trace gases, flux measurement instruments, radiation measurement techniques), aerobiology (e.g. the dispersion of pollen, spores, insects and pesticides), biometeorology (e.g. the effect of weather and climate on plant distribution, crop yield, water-use efficiency, and plant phenology), forest-fire/weather interactions, and feedbacks from vegetation to weather and the climate system.