Quantifying the effect of geomorphology on aeolian dust emission potential in northern China

Representation of dust sources remains a key challenge in quantifying the dust cycle and its environmental and climatic impacts. Direct measurements of dust fluxes from different landform types are useful in understanding the nature of dust emission and characterizing the dynamics of soil erodibilit...

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Bibliographic Details
Published in:Earth surface processes and landforms 2019-11, Vol.44 (14), p.2872-2884
Main Authors: Cui, Mengchun, Lu, Huayu, Wiggs, Giles F.S., Etyemezian, Vicken, Sweeney, Mark R., Xu, Zhiwei
Format: Article
Language:English
Subjects:
Atmospheric particulates
Beds (geology)
Climate models
Dunes
Dust
Dust cycle
Dust emission
Dust storms
Emission analysis
Emissions
Environmental impact
Eolian dust
Fluxes
Geomorphology
Grasslands
Lake beds
Lakes
Landforms
northern China
Parameterization
Particulate matter
Particulate matter emissions
PI‐SWERL
Playas
PM10
Seasonal variation
Seasonal variations
Seasonality
Soil
Soil dynamics
Soil erodibility
Soil erosion
Soil moisture
Soil moisture variations
Soils
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Summary:Representation of dust sources remains a key challenge in quantifying the dust cycle and its environmental and climatic impacts. Direct measurements of dust fluxes from different landform types are useful in understanding the nature of dust emission and characterizing the dynamics of soil erodibility. In this study we used the PI‐SWERL® instrument over a seasonal cycle to quantify the potential for PM10 (particles with diameter ≤10 μm) emission from several typical landform types across the Tengger Desert and Mu Us Sandy Land, northern China. Our results indicate that sparse grasslands and coppice dunes showed relatively high emission potentials, with emitted fluxes ranging from 10−1 to 101 mg m−2 s−1. These values were up to five times those emitted from sand dunes, and one to two orders of magnitude greater than the emissions from dry lake beds, stone pavements and dense grasslands. Generally, PM10 emission fluxes were seen to peak in the spring months, with significant reductions in summer and autumn (by up to 95%), and in winter (by up to 98%). Variations in soil moisture were likely a primary controlling factor responsible for this seasonality in PM10 emission. Our data provide a relative quantification of differences in dust emission potential from several key landform types. Such data allow for the evaluation of current dust source schemes proposed by prior researchers. Moreover, our data will allow improvements in properly characterizing the erodibility of dust source regions and hence refine the parameterization of dust emission in climate models. © 2019 John Wiley & Sons, Ltd. © 2019 John Wiley & Sons, Ltd. Seasonal variations in u*t and PM10 fluxes for different landform types in northern China.
ISSN:0197-9337
1096-9837
DOI:10.1002/esp.4714