北美沙尘排放气候学(2001-2020年)与卫星观测的沙尘点源校准

IF 3.1 3区 地球科学 Q2 GEOGRAPHY, PHYSICAL
Mark Hennen , Adrian Chappell , Brandon L. Edwards , Akasha M. Faist , Tarek Kandakji , Matthew C. Baddock , Brandi Wheeler , Gayle Tyree , Ronald Treminio , Nicholas P. Webb
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引用次数: 13

摘要

大气粉尘的测量长期以来影响着我们对粉尘源和粉尘模型校准的理解。然而,评估沙尘排放的大小和频率可以揭示不同的沙尘源动态,对土地管理至关重要。在这里,我们使用MODIS(500米)基于反照率的每日风摩擦估计来产生一个新的北美沙尘排放气候学(2001-2020),通过光学卫星观测的新使用沙尘点源进行校准(而不是调谐到大气中的沙尘)。校准后的沙尘排放主要发生在大平原(GP)和北美沙漠(NAD)的生物群落中,与气溶胶光学深度和沙尘沉积图基本一致,但频率和量级要小得多。总体而言,这些生物群系产生了7.2 Tg y-1,由于条件的差异,各生物群系对NAD和GP的贡献分别为59.8%和40.2%。尘埃排放取决于落基山脉两侧不同的风摩擦条件。总的来说,在整个沙漠中,空气动力粗糙度一直很小,在风速较大的地区,沙尘源被激活;沙漠尘埃排放受到风速限制。在整个大平原,大风持续存在,当植被覆盖减少时,会发生粉尘排放;植被粉尘排放粗糙度有限。我们发现,在不同的生物群系/植被类别中存在类似的空气动力学粗糙度,这表明粉尘排放区域并不局限于单个生物群系,而是分布在有利的风摩擦条件的“包膜”上。风摩擦动力学描述了变化的植被粗糙度(例如,由于气候和土地管理)与变化的风(静止及其逆转)之间的相互作用,影响模拟的沙尘排放的大小和频率及其当前和未来的气候学。我们确认了先前的结果,即在21世纪下半叶,大平原南部最容易受到沙尘排放增加的影响,并首次表明风险是由于风摩擦的增加(植被粗糙度的降低和/或风速的增加)。无论对大气尘埃的校准模型有多好,假设粗糙度在时间上是静态的和/或在空间上是均匀的,都不能充分代表当前和未来的尘埃源动态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A North American dust emission climatology (2001–2020) calibrated to dust point sources from satellite observations

Measurements of atmospheric dust have long influenced our understanding of dust sources and dust model calibration. However, assessing dust emission magnitude and frequency may reveal different dust source dynamics and is critical for informing land management. Here we use MODIS (500 m) albedo-based daily wind friction estimates to produce a new dust emission climatology of North America (2001–2020), calibrated by the novel use of dust point sources from optical satellite observations (rather than being tuned to dust in the atmosphere). Calibrated dust emission occurred predominantly in the biomes of the Great Plains (GP) and North American Deserts (NAD), in broad agreement with maps of aerosol optical depth and dust deposition but with considerably smaller frequency and magnitude. Combined, these biomes produced 7.2 Tg y-1 with contributions split between biomes (59.8% NAD, 40.2% GP) due to the contrasting conditions. Dust emission is dependent on different wind friction conditions on either side of the Rocky Mountains. In general, across the deserts, aerodynamic roughness was persistently small and dust sources were activated in areas prone to large wind speeds; desert dust emissions were wind speed limited. Across the Great Plains, large winds persist, and dust emission occurred when vegetation cover was reduced; vegetated dust emissions were roughness limited. We found comparable aerodynamic roughness exists across biomes/vegetation classes demonstrating that dust emission areas are not restricted to a single biome, instead they are spread across an ‘envelope’ of conducive wind friction conditions. Wind friction dynamics, describing the interplay between changing vegetation roughness (e.g., due to climate and land management) and changing winds (stilling and its reversal), influence modelled dust emission magnitude and frequency and its current and future climatology. We confirm previous results that in the second half of the 21st century the southern Great Plains is the most vulnerable to increased dust emission and show for the first time that risk is due to increased wind friction (by decreased vegetation roughness and / or increased wind speed). Regardless of how well calibrated models are to atmospheric dust, assuming roughness is static in time and / or homogeneous over space, will not adequately represent current and future dust source dynamics.

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来源期刊
Aeolian Research
Aeolian Research GEOGRAPHY, PHYSICAL-
CiteScore
7.10
自引率
6.10%
发文量
43
审稿时长
>12 weeks
期刊介绍: The scope of Aeolian Research includes the following topics: • Fundamental Aeolian processes, including sand and dust entrainment, transport and deposition of sediment • Modeling and field studies of Aeolian processes • Instrumentation/measurement in the field and lab • Practical applications including environmental impacts and erosion control • Aeolian landforms, geomorphology and paleoenvironments • Dust-atmosphere/cloud interactions.
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