Exceptional Saharan dust transport over the Atlantic Ocean
5 June 2020 00:00 UTC–26 June 21:00 UTC
In June 2020 large amounts of Saharan dust, declared by the media as an "historic Saharan dust plume", travelled on easterly trade winds all the way to the Caribbean and south-eastern parts of the continental US.
11, November 2020
By Natasa Strelec Mahovic and Jose Prieto (EUMETSAT)
Saharan dust transport is a phenomenon that occurs every year, mostly during summer months, often reaching Central and South America.
Being rich in elements such as nitrogen, iron and phosphorus, Saharan dust brings important nutrients to the plant-life of the Amazon's rainforest and acts as a fertiliser for the production of phytoplankton.
However, although the occurrence is not unusual, in June 2020 the amount of the dust transported and the density of the dust cloud was exceptional, causing very poor visibility and major dust deposits in many places in the Caribbean.
Because of its long duration and exceptional intensity, the phenomenon could be followed from meteorological satellites throughout the month of June (Figures 1 and 2).
The daily sequence of Dust RGB composites at 12:00 UTC (Figure 3) shows that the largest plumes actually generated from soil. Some occurred in the east parts of Africa, and travelled through the southern Sahara to reach the Atlantic, for example one such plume was generated on the 9-10 June.
The Bodélé depression, often a factor in Saharan dust transportation, was not a major source of dust this month, even if its natural wind channel contributed to a large accumulation around 5 June, which eventually reached the Caribbean.
Although there were several episodes of dust being lifted from Sahara at beginning of June, the presence of a low pressure centre and the circulation in the lower layers of the atmosphere kept the dust 'floating' over West Africa, with only a small amount reaching the Atlantic (Figure 4).
Since the dust cloud was confined to the lowest 4 km of the troposphere, as can be seen from the Cloud-Aerosol Lidar with Orthogonal Polarization (CALIOP) instrument onboard the CALIPSO satellite (Figure 5), it was transported by the winds in the lower atmospheric layers.
The strongest transport started mid-June with strengthening of the Azores High and the associated easterly winds in the lowest 3 km.
The animation (Figure 6) shows the Azores High located half way between Europe and America, with the largest pressure gradients persisting over 15N–20N latitude for more than two weeks, causing strong 850 hPa winds with speeds more than 20 m/s. This synoptic situation was very favourable for the intensive transport of dust. Also note how the maximum of the wind moves westwards, transporting the large amounts of dust far west.
Thermal window channels estimate dry particulate matter (PM) concentrations and their heights. However, the viewing angle plays a significant part in the quality of the aerosol optical depth (AOD)— satellites detect dust better on the boundary of the field of view than near the centre. The reason is the longer interaction of the radiation with dust particles, through a more slant path in the atmosphere.
The average number of particles touched by a straight line through the plume is called the aerosol optical depth (AOD) of the plume. This number is bigger when the line traverses the plume diagonally (obliquely), so it is bigger for the most distant satellite (Figure 7). Multi-satellite imagery can mislead the detection of dust and typically underestimate its concentration over the Atlantic.
On the comparison of GOES and Meteosat views of the dust plume for several locations on its path (Figure 8), taken on 23 June at 15:10 UTC, each satellite enhances the dust plume closer to the other satellite. Notice that both satellites look at precisely the same dust concentrations, just from the different viewing angles.
Details of satellite measurements for three locations, marked in Figure 8, A (21N–8E) on land in Africa, B (17N–23E) over the ocean near Cape Verde, and C (18N–70E) in the Caribbean, can be analysed with the help of scatter plots.
Channels on ABI are spectrally different from channels in SEVIRI close in wavelength. The readings differ by a fraction of a degree due to spectral properties, most of the time. But differences due to the viewing angle are bigger. That is why it is assumed that 10.3 µm on ABI is equivalent of 10.8 µm on SEVIRI, and 12.3 µm on ABI equivalent of 12.0 µm.
The graphs for location B over the Cape Verde (Figure 9) show the dust distribution of brightness temperatures (BT, also called glow temperatures). On the shorter wavelength channel at 10.x µm, GOES BTs are about 5 K colder than on Meteosat, 287 K versus 292 K. A longer path through the dust reduces the signal (see Figure 7). Also the difference with the longer wavelength gets deeper, -1.5 K versus -0.6 K, part of which is a bias due to different weighting functions for ABI and SEVIRI channels, and part due to a higher AOD for GOES. The upper dust contribution for thick plumes is colder in the diagonal than along the vertical.
For the location C in the Caribbean region (Figure 10), the behaviour is similar, with an AOD advantage for Meteosat, which reaches -2.5 K in the difference (vertical axis) compared with just 0.5 K for GOES almost in the vertical, due to the high humidity above the sea favouring 10.3µm channel. Also the 10.x µm values show 15 K difference (29 5 K versus 281 K), which points to a large concentration of dust, hard to notice in GOES imagery.
Finally, for the African soil (Figure 11), the graph again shows a large bias for the shorter wavelength of 15 K. A larger area is covered in the GOES graph (left), so different layers of dust can be identified as the three 'legs' in that graph, at 277, 285 and 293 K. These are BT values, an approximate average of the dust temperatures and ground temperatures.
The Meteosat-11 Dust RGB animation from 6–22 June (Figure 11) shows the various African dust sources and, at the end, the dust lingering over the Caribbean, on the limb of the field of view.
The GOES-16 animation for 16–27 June (Figure 12) focuses on the Atlantic-Caribbean scene, with the dust signal becoming faint (in contrast to Meteosat).
A Dust Plume to Remember (NASA Earth Observatory)
NASA-NOAA’s Suomi NPP Satellite Analyzes Saharan Dust Aerosol Blanket (NASA)
Massive Saharan dust cloud shrouds the Caribbean (BBC News)
The historic Saharan dust plume is darkening skies in the Caribbean and will soon stretch into the US (CNN)
Saharan Dust Affects Caribbean Nations - Jun. 19 / Jun. 22, 2020 (Disaster Compilations/YouTube)
ScienceCasts: Desert Dust Feeds Amazon Forests (Science at NASA/YouTube)
NASA Satellite Reveals How Much Saharan Dust Feeds Amazon’s Plants (NASA)
Extensive DIBS in the Deformation Zone
In April 2020, pockmarked DIBS cloud, produced by a cyclone over the Mediterranean Sea, entered an elongated deformation zone - stretching from France to Turkey.
Aralkum Desert dust pollutes air in South-East Europe
High values of particulate matter (PM10) were recorded in the air in many places across South-East Europe on 27 March 2020.
Dust over Europe
Two dust clouds, one from northern Africa and one from Central Europe, travelled north towards Iceland and Greenland in late April 2019.
Large Dust Fan (Spanish Dancer) over West Africa
A cyclone over Algeria pushes cold air southward over West Africa, causing a synoptic scale dust outbreak, in early March 2019.
Heavy snow in parts of Spain
Parts of central Spain saw their heaviest snowfalls in decades in January 2021.
Early summer convection in central Argentina and Uruguay
Severe convection in central Argentina in December 2020.
Nearly-record snowfall in the western Alps in December 2020
Winter 2020 started with more than 2 m snow in the Alps and an extreme amount of rain.