Modeling impacts of dust mineralogy on fast climate response

IF 5.2 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES Atmospheric Chemistry and Physics Pub Date : 2024-06-28 DOI:10.5194/acp-24-7421-2024
Qianqian Song, Paul Ginoux, María Gonçalves Ageitos, Ron L. Miller, Vincenzo Obiso, Carlos Pérez García-Pando
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Abstract

Abstract. Mineralogical composition drives dust impacts on Earth's climate systems. However, most climate models still use homogeneous dust, without accounting for the temporal and spatial variation in mineralogy. To quantify the radiative impact of resolving dust mineralogy on Earth's climate, we implement and simulate the distribution of dust minerals (i.e., illite, kaolinite, smectite, hematite, calcite, feldspar, quartz, and gypsum) from Claquin et al. (1999) (C1999) and activate their interaction with radiation in the GFDL AM4.0 model. Resolving mineralogy reduces dust absorption compared to the homogeneous dust used in the standard GFDL AM4.0 model that assumes a globally uniform hematite volume content of 2.7 % (HD27). The reduction in dust absorption results in improved agreement with observation-based single-scattering albedo (SSA), radiative fluxes from CERES (the Clouds and the Earth's Radiant Energy System), and land surface temperature from the CRU (Climatic Research Unit) compared to the baseline HD27 model version. It also results in distinct radiative impacts on Earth's climate over North Africa. Over the 19-year (from 2001 to 2019) modeled period during JJA (June–July–August), the reduction in dust absorption in AM4.0 leads to a reduction of over 50 % in net downward radiation across the Sahara and approximately 20 % over the Sahel at the top of the atmosphere (TOA) compared to the baseline HD27 model version. The reduced dust absorption weakens the atmospheric warming effect of dust aerosols and leads to an alteration in land surface temperature, resulting in a decrease of 0.66 K over the Sahara and an increase of 0.7 K over the Sahel. The less warming in the atmosphere suppresses ascent and weakens the monsoon inflow from the Gulf of Guinea. This brings less moisture to the Sahel, which combined with decreased ascent induces a reduction of precipitation. To isolate the effect of reduced absorption compared to resolving spatial and temporal mineralogy, we carry out a simulation where the hematite volume content of homogeneous dust is reduced from 2.7 % to 0.9 % (HD09). The dust absorption (e.g., single-scattering albedo) of HD09 is comparable to that of the mineralogically speciated model on a global mean scale, albeit with a lower spatial variation that arises solely from particle size. Comparison of the two models indicates that the spatial inhomogeneity in dust absorption resulting from resolving mineralogy does not have significant impacts on Earth's radiation and climate, provided there is a similar level of dust absorption on a global mean scale before and after resolving dust mineralogy. However, uncertainties related to emission and distribution of minerals may blur the advantages of resolving minerals to study their impact on radiation, cloud properties, ocean biogeochemistry, air quality, and photochemistry. On the other hand, lumping together clay minerals (i.e., illite, kaolinite, and smectite), but excluding externally mixed hematite and gypsum, appears to provide both computational efficiency and relative accuracy. Nevertheless, for specific research, it may be necessary to fully resolve mineralogy to achieve accuracy.
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模拟尘埃矿物学对快速气候响应的影响
摘要矿物组成是尘埃对地球气候系统影响的驱动因素。然而,大多数气候模式仍然使用同质尘埃,而不考虑矿物学的时空变化。为了量化解析尘埃矿物学对地球气候的辐射影响,我们在 GFDL AM4.0 模型中实施并模拟了 Claquin 等人(1999 年)提出的尘埃矿物(即伊利石、高岭石、镜铁矿、赤铁矿、方解石、长石、石英和石膏)的分布(C1999),并激活了它们与辐射的相互作用。与标准 GFDL AM4.0 模型中使用的均质尘埃(假设赤铁矿体积含量为全球均匀的 2.7%(HD27))相比,解析矿物学可减少尘埃吸收。与基线 HD27 模式版本相比,灰尘吸收的减少使得与基于观测的单散射反照率 (SSA)、CERES(云和地球辐射能量系统)的辐射通量以及 CRU(气候研究单位)的陆地表面温度的一致性得到改善。它还对北非的地球气候产生了明显的辐射影响。在 JJA(6 月-7 月-8 月)期间的 19 年(从 2001 年到 2019 年)建模期内,与基线 HD27 模式版本相比,AM4.0 中灰尘吸收的减少导致整个撒哈拉地区的净向下辐射减少了 50%以上,萨赫勒地区大气顶部(TOA)的净向下辐射减少了约 20%。尘埃吸收的减少削弱了尘埃气溶胶对大气变暖的影响,并导致陆地表面温度的改变,使撒哈拉地区的温度降低了 0.66 K,萨赫勒地区的温度升高了 0.7 K。大气升温幅度减小,抑制了上升,削弱了来自几内亚湾的季风流入。这给萨赫勒地区带来了更少的水汽,再加上上升气流减少,导致降水量减少。与解析空间和时间矿物学相比,为了分离吸收减少的影响,我们进行了一次模拟,将均质尘埃的赤铁矿体积含量从 2.7% 降至 0.9%(HD09)。在全球平均尺度上,HD09 的尘埃吸收率(如单一散射反照率)与矿物学特定模型的吸收率相当,尽管空间变化较小,这完全是由颗粒大小引起的。这两个模型的比较表明,如果在解析尘埃矿物学之前和之后,全球平均尺度上的尘埃吸收水平相似,那么解析矿物学导致的尘埃吸收空间不均匀性不会对地球辐射和气候产生重大影响。然而,与矿物的排放和分布有关的不确定性可能会模糊解析矿物学的优势,从而无法研究它们对辐射、云特性、海洋生物地球化学、空气质量和光化学的影响。另一方面,将粘土矿物(即伊利石、高岭石和直闪石)放在一起,但不包括外部混合的赤铁矿和石膏,似乎既提高了计算效率,又相对准确。不过,在具体研究中,可能有必要全面解析矿物学,以实现准确性。
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来源期刊
Atmospheric Chemistry and Physics
Atmospheric Chemistry and Physics 地学-气象与大气科学
CiteScore
10.70
自引率
20.60%
发文量
702
审稿时长
6 months
期刊介绍: Atmospheric Chemistry and Physics (ACP) is a not-for-profit international scientific journal dedicated to the publication and public discussion of high-quality studies investigating the Earth''s atmosphere and the underlying chemical and physical processes. It covers the altitude range from the land and ocean surface up to the turbopause, including the troposphere, stratosphere, and mesosphere. The main subject areas comprise atmospheric modelling, field measurements, remote sensing, and laboratory studies of gases, aerosols, clouds and precipitation, isotopes, radiation, dynamics, biosphere interactions, and hydrosphere interactions. The journal scope is focused on studies with general implications for atmospheric science rather than investigations that are primarily of local or technical interest.
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