Climatic controls on the interannual to decadal variability in Saudi Arabian dust activity: Toward the development of a seasonal dust prediction model

Yu, Yan; Notaro, Michael; Liu, Zhengyu; Wang, Fuyao; Alkolibi, Fahad; Fadda, Eyad; Bakhrjy, Fawzieh

doi:10.1002/2014jd022611

Cited by 119 publications

(142 citation statements)

References 84 publications

(117 reference statements)

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“…Previous studies have shown that there are decreases in dust from South America over the 1990-2005 period in some models (Doney et al, 2009), but these are not shown in all the model versions or supported by robust observational data (Doney et al, 2009). Yu et al (2015) show evidence for strong decadal variability in the Saudi Arabian source over a different time period than considered here, with an increase between 2000 and 2015, arguing that a drought in the Fertile Crescent is (Fig. 9), consistent with their results, and correlation between precipitation and dust source in these simulations (Table 7).…”

Section: Modeled Temporal Trends In Different Regionssupporting

confidence: 79%

“…It is well established in the dust literature that meteorology and surface conditions play central roles in driving changes in dust emissions, primarily from changes in precipitation, winds, surface roughness or vegetation cover on daily to interannual to geological timescales (e.g., Westphal et al, 1987;Petit et al, 1999;Marticorena and Bergametti, 1996;Mahowald et al, 2002;Prospero and Lamb, 2003;Engelstadter and Washington, 2007;Engelstaedter et al, 2003;Roe, 2008;McGee et al, 2010;Knippertz and Todd, 2012;Cowie et al, 2013;Yu et al, 2015), and we do not seek to repeat or review that work here. Rather, we address the question of how sensitive our simulation of interannual variability is to the meteorology or, alternatively, the modeling framework used.…”

Section: Introductionmentioning

confidence: 99%

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Sensitivity of the interannual variability of mineral aerosol simulations to meteorological forcing dataset

et al. 2017

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Abstract. Interannual variability in desert dust is widely observed and simulated, yet the sensitivity of these desert dust simulations to a particular meteorological dataset, as well as a particular model construction, is not well known. Here we use version 4 of the Community Atmospheric Model (CAM4) with the Community Earth System Model (CESM) to simulate dust forced by three different reanalysis meteorological datasets for the period 1990-2005. We then contrast the results of these simulations with dust simulated using online winds dynamically generated from sea surface temperatures, as well as with simulations conducted using other modeling frameworks but the same meteorological forcings, in order to determine the sensitivity of climate model output to the specific reanalysis dataset used. For the seven cases considered in our study, the different model configurations are able to simulate the annual mean of the global dust cycle, seasonality and interannual variability approximately equally well (or poorly) at the limited observational sites available. Overall, aerosol dust-source strength has remained fairly constant during the time period from 1990 to 2005, although there is strong seasonal and some interannual variability simulated in the models and seen in the observations over this time period. Model interannual variability comparisons to observations, as well as comparisons between models, suggest that interannual variability in dust is still difficult to simulate accurately, with averaged correlation coefficients of 0.1 to 0.6. Because of the large variability, at least 1 year of observations at most sites are needed to correctly observe the mean, but in some regions, particularly the remote oceans of the Southern Hemisphere, where interannual variability may be larger than in the Northern Hemisphere, 2-3 years of data are likely to be needed.

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Section: Modeled Temporal Trends In Different Regionssupporting

confidence: 79%

Section: Introductionmentioning

confidence: 99%

Sensitivity of the interannual variability of mineral aerosol simulations to meteorological forcing dataset

et al. 2017

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“…A substantial increase in AOD over the Middle East since the onset of the 21st century has been revealed from various remote-sensing and ground-based observations Klingmüller et al, 2016;Notaro et al, 2015;Yu et al, 2015) and has been reproduced by global aerosol models (Chin et al, 2014). A substantial increase in AOD over the Middle East since the onset of the 21st century has been revealed from various remote-sensing and ground-based observations Klingmüller et al, 2016;Notaro et al, 2015;Yu et al, 2015) and has been reproduced by global aerosol models (Chin et al, 2014).…”

Section: Introductionmentioning

confidence: 94%

Identification and Characterization of Dust Source Regions Across North Africa and the Middle East Using MISR Satellite Observations

Калашникова

Garay

et al. 2018

Geophysical Research Letters

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Motivated by limitations in current satellite‐based dust source identification techniques, this study examines dust emissions and concentrations over North Africa and the Middle East during 2000–2016 by analyzing stereo and optical products from the Multiangle Imaging SpectroRadiometer instrument on the National Aeronautics and Space Administration polar‐orbiting Terra satellite. Based on the occurrence of fast‐moving, near‐surface dust plumes from the Multiangle Imaging SpectroRadiometer cloud motion vector product, dust sources in the study region are identified in geographical depressions, including the Bodélé Depression, which represents the leading source. The West African El Djouf desert generates substantial dust emissions, which are typically underestimated by aerosol loading‐based dust source identifications. In response to local vegetation cover anomalies, dust emissions and concentrations increased at 15% year−1 over the Middle East and decreased at 12% year−1over the central Sahel during 2001–2013 but partly recovered toward their climatological means afterward.

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“…Meanwhile, decadal variability is regulated by the North African rainfall and the Sahel vegetation (which activates the transport of African dust), in addition to the Mediterranean Sea surface temperatures (which activate the Shamal wind). Furthermore, Yu et al (2015) explain that there is a decreasing amount of rainfall during the winter-to-spring La Niña across the Rub' al Khali Desert, which enhances dust activity, while a relatively cool tropical Indian Ocean produces an anomalously anticyclonic circulation over the central Arabian Peninsula, which enhances the Shamal wind.…”

Section: Introductionmentioning

confidence: 99%

Seasonal variability and synoptic characteristics of dust cases over southwestern Saudi Arabia

Mashat

Alamoudi

Awad

et al. 2017

Intl Journal of Climatology

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ABSTRACT:The synoptic characteristics and statistical variability of seasonal dust over southwestern Saudi Arabia are studied for the period from 1979 to 2006 using the aerosol index (AI) from the Total Ozone Mapping Spectrometer (TOMS) satellite, dust observations from surface stations, and meteorological data from the National Center for Environmental Prediction and the National Center for Atmospheric Research (NCEP/NCAR) reanalysis data set.The seasonal AI distribution indicates that approximately 80% of each year was dusty and that most of the dust occurred during hot months. In addition, the surface observations of the dust types show that the stations with the largest number of dust observations throughout the year were close to the desert, except during the summer, when the stations near the Red Sea had the largest number of dust observations.The synoptic forces that influenced the dust cases were the relative positions of high-pressure systems (Azores or Siberian) and low-pressure systems (Sudan or Indian), alongside their interactions. The relative positions of the atmospheric systems are highly pronounced at a pressure level of 850 hPa; at this pressure, the systems are oriented from north (anticyclonic system) to south (cyclonic system), turn anticlockwise to become oriented from west (anticyclonic system) to east (cyclonic system) during the summer, and then turn clockwise during the winter. Moreover, the interaction of the atmospheric systems influences the wind pattern of the seasonal composition over the southern Arabian Peninsula, which produces an anticyclonic wind pattern during winter, a cyclonic wind pattern during spring, a northerly/northwesterly wind pattern during summer and an anticyclonic wind pattern during autumn.The dust sources changed because of the relative positions of these atmospheric systems, in which the 'Toker Gap' Sudan was the summer/autumn dust source, and the 'central and eastern' Arabian Peninsula was the winter/spring dust source.

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Climatic controls on the interannual to decadal variability in Saudi Arabian dust activity: Toward the development of a seasonal dust prediction model

Cited by 119 publications

References 84 publications

Sensitivity of the interannual variability of mineral aerosol simulations to meteorological forcing dataset

Sensitivity of the interannual variability of mineral aerosol simulations to meteorological forcing dataset

Identification and Characterization of Dust Source Regions Across North Africa and the Middle East Using MISR Satellite Observations

Seasonal variability and synoptic characteristics of dust cases over southwestern Saudi Arabia

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