Xicheng Li, Lei Zhu, Isabelle De Smedt, Wenfu Sun, Yuyang Chen, Lei Shu, Dakang Wang, Song Liu, Dongchuan Pu, Juan Li, Xiaoxing Zuo, Weitao Fu, Yali Li, Peng Zhang, Zhuoxian Yan, Tzung-May Fu, Huizhong Shen, Chen Wang, Jianhuai Ye, Xin Yang
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引用次数: 0
摘要
温度是全球大气中甲醛(HCHO)及其主要氧化前体生物挥发性有机化合物(BVOCs)的主要驱动因素。我们利用 TROPOMI HCHO 柱数据,在全球范围内重新审视了这种温度(T-)依赖性。我们发现不同植物功能类型(PFTs)的生物源 HCHO 的温度依赖性存在很大差异,其中热带常绿阔叶树的温度依赖性最高(每 6.0 K ± 4.1 K 翻一番),而北极 C3 禾本科植物的温度依赖性最低(每 30.8 K ± 9.6 K 翻一番)。GEOS-Chem 模型在 PFT 水平上解释了 HCHO 柱的 T 依赖性(r = 0.87),平均差异为 16%。这种差异可以用常绿热带阔叶树和暖 C4 草本的 BVOC 排放 T 依赖性来解释,也可以归因于 HCHO 柱对其他 PFT 的 BVOC 排放不敏感。我们的发现强调了 GEOS-Chem 和 MEGAN 中 BVOC 排放的潜在放大变化,尤其是在温度变化较大的地区。
Global Temperature Dependency of Biogenic HCHO Columns Observed From Space: Interpretation of TROPOMI Results Using GEOS-Chem Model
Temperature is the principal driver of global atmospheric formaldehyde (HCHO) and its primary oxidation precursor biogenic volatile organic compounds (BVOCs). We revisit such a temperature (T-) dependency globally, leveraging TROPOMI HCHO column data. We find substantial variations in the T-dependency of biogenic HCHO across plant functional types (PFTs), with the highest over Broadleaf Evergreen Tropical Trees (doubling every 6.0 K ± 4.1 K) and lowest over Arctic C3 Grass (doubling every 30.8 K ± 9.6 K). The GEOS-Chem model interprets HCHO columns' T-dependency at the PFT level (r = 0.87), with a 16% discrepancy on average. The discrepancy can be explained by BVOC emissions T-dependency for Broadleaf Evergreen Tropical Trees and Warm C4 Grass and can be attributed to the insensitivity of HCHO columns to BVOC emissions for other PFTs. Our findings underscore a potentially magnified variation of BVOC emissions by GEOS-Chem and MEGAN therein, particularly in regions experiencing greater temperature variations.
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JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.
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