Climate Models and Remote Sensing Retrievals Neglect Substantial Desert Dust Asphericity

Huang, Yongjun; Kok, Jasper F.; Kandler, Konrad; Lindqvist, Hannakaisa; Nousiainen, Timo; Sakai, Tetsu; Adebiyi, Adeyemi A.; Jokinen, Olli

doi:10.1029/2019gl086592

Cited by 60 publications

(123 citation statements)

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“…Africa contributes almost 50 % of the world's dust emissions (Huneeus et al, 2011), with easterly winds transporting the dust over the Atlantic subtropical belt throughout the full seasonal cycle. The impacts of dust span from climate-relevant timescales, which primarily focus on dust's radiative effects, to the shorter timescales important for human endeavors.…”

Section: Introductionmentioning

confidence: 99%

Apparent dust size discrepancy in aerosol reanalysis in north African dust after long-range transport

et al. 2020

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Abstract. North African dust reaches the southeastern United States every summer. Size-resolved dust mass measurements taken in Miami, Florida, indicate that more than one-half of the surface dust mass concentrations reside in particles with geometric diameters less than 2.1 µm, while vertical profiles of micropulse lidar depolarization ratios show dust reaching above 4 km during pronounced events. These observations are compared to the representation of dust in the Modern-Era Retrospective analysis for Research and Applications, version 2 (MERRA-2) aerosol reanalysis and closely related Goddard Earth Observing System model version 5 (GEOS-5) Forward Processing (FP) aerosol product, both of which assimilate satellite-derived aerosol optical depths using a similar protocol and inputs. These capture the day-to-day variability in aerosol optical depth well, in a comparison to an independent sun-photometer-derived aerosol optical depth dataset. Most of the modeled dust mass resides in diameters between 2 and 6 µm, in contrast to the measurements. Model-specified mass extinction efficiencies equate light extinction with approximately 3 times as much aerosol mass, in this size range, compared to the measured dust sizes. GEOS-5 FP surface-layer sea salt mass concentrations greatly exceed observed values, despite realistic winds and relative humidities. In combination, these observations help explain why, despite realistic total aerosol optical depths, (1) free-tropospheric model volume extinction coefficients are lower than those retrieved from the micro-pulse lidar, suggesting too-low model dust loadings in the free troposphere, and (2) model dust mass concentrations near the surface can be higher than those measured. The modeled vertical distribution of dust, when captured, is reasonable. Large, aspherical particles exceeding the modeled dust sizes are also occasionally present, but dust particles with diameters exceeding 10 µm contribute little to the measured total dust mass concentrations after such long-range transport. Remaining uncertainties warrant a further integrated assessment to confirm this study's interpretations.

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Section: Introductionmentioning

confidence: 99%

Apparent dust size discrepancy in aerosol reanalysis in north African dust after long-range transport

et al. 2020

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“…In particular, mineral dust aerosols with aspect ratios close to unity (Veghte & Freedman, 2014) are unnecessarily to be excluded. The aspect ratios larger than 2.0 or smaller than 0.5 that are most useful for spheroidal model are not essential when the superspheroidal model is employed, although realistic dust aerosol aspect ratio could be out of this range (0.5–2.0; Y. Huang, Kok et al., 2020). To conclude, the superspheroidal model with large roundness parameter appears to be a superior dust aerosol model for polarized radiative transfer simulations.…”

Section: Discussionmentioning

confidence: 99%

Capability of Superspheroids for Modeling PARASOL Observations Under Dusty‐Sky Conditions

Lin

Weng

et al. 2021

JGR Atmospheres

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In particular, because dust particle size has a wide range starting at a value smaller than 0.1 µm to a value larger than 20 µm, their interaction with both short and long waves are critical for determining the dust radiative effect. Dust particles with a size greater than 5 µm are found in the source regions while particles with sizes between 0.1 and 5 µm can be transported over a long distance (

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“…The Soil Moisture Active Passive (SMAP) Level-4 Soil Moisture data product addressed these limitations by merging the satellite observations into a numerical model of the land surface water and energy balance while considering the uncertainty of the observations and model estimates (Reichle et al, 2019). In this work, we utilized the 3-hourly data of soil moisture derived from the SMAP for barren and open shrublands, separately (Reichle et al, 2018 Compared to the assumption on spherical shapes of aerosols, the dust asphericity increased aerodynamic drag at a given volume and mass, and thus increased gravitational settling lifetime by about 20% (Huang et al, 2020a). Here, we implemented globally averaged asphericity factor of 0.87 (Huang et al, 2020a) to the gravitational settling scheme for mineral dust.…”

Section: Aerosol Chemistry Transport Modelmentioning

confidence: 99%

“…In this work, we utilized the 3-hourly data of soil moisture derived from the SMAP for barren and open shrublands, separately (Reichle et al, 2018 Compared to the assumption on spherical shapes of aerosols, the dust asphericity increased aerodynamic drag at a given volume and mass, and thus increased gravitational settling lifetime by about 20% (Huang et al, 2020a). Here, we implemented globally averaged asphericity factor of 0.87 (Huang et al, 2020a) to the gravitational settling scheme for mineral dust. Consequently, the lifetime of the dust aerosol for the largest-size bin in the IMPACT model even after accounting for asphericity (1.4 days for 5-20 µm of diameter) was significantly shorter than an ensemble of model results (2.1 ± 0.3 days for the mass mean diameter of 8.3 µm) (Kok et al, 2017).…”

Section: Aerosol Chemistry Transport Modelmentioning

confidence: 99%

“…(RRTMG) (Iacono et al, 2008) (i.e., default simulation). We improve the accuracy of these simulations by correcting the bias in size-resolved dust concentration with the Dust Constraints from joint Observational-Modelling-Experimental analysis (DustCOMM) data set ) (i.e., improved simulation), as well as by considering the aspherical shape (Huang et al, 2020a(Huang et al, , 2020b. We then explore the sensitivity to dust refractive index.…”

Section: Introductionmentioning

confidence: 99%

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Less atmospheric radiative heating due to aspherical dust with coarser size

Ito

Adebiyi

Huang

et al. 2021

Preprint

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Abstract. Mineral dust aerosols cool and warm the atmosphere by scattering and absorbing both solar (short-wave: SW) and thermal (long-wave: LW) radiation. However, large uncertainties remain in dust radiative effects, largely due to differences in the dust size distribution and optical properties simulated in Earth system models. Here, we improve the simulated dust properties with datasets that leverage measurements of size-resolved dust concentration and asphericity factor (improved simulation) in a coupled global chemical transport model (IMPACT) with a radiative transfer module (RRTMG) (default simulation). The global and annual average of dust aerosol optical depth at 550 nm (DAOD550) from the improved simulation (0.029) falls within the range of a semi-observation-based estimate (0.030 ± 0.005), in contrast to that (0.023) of the default simulation. Improved agreement against semi-observation-based estimate of the radiative effect efficiency was obtained using less absorptive SW and more absorptive LW dust refractive indices. Our sensitivity simulations reveal that the improved simulation leads to a similar net global dust radiative effect at the Top Of Atmosphere (TOA) on a global scale to the default simulation (−0.08 vs. −0.09 W ·m−2) but results in less cooling at the surface (−0.23 vs. −0.88 W ·m−2), because of enhanced LW warming by coarser aspherical dust. Our results thus suggest less atmospheric radiative heating due to aspherical dust with coarser size over the major source regions (0.15 vs. 0.79 W ·m−2 on a global scale).

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Climate Models and Remote Sensing Retrievals Neglect Substantial Desert Dust Asphericity

Cited by 60 publications

References 58 publications

Apparent dust size discrepancy in aerosol reanalysis in north African dust after long-range transport

Apparent dust size discrepancy in aerosol reanalysis in north African dust after long-range transport

Capability of Superspheroids for Modeling PARASOL Observations Under Dusty‐Sky Conditions

Less atmospheric radiative heating due to aspherical dust with coarser size

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