SALT FLATS - GEOGRAPHY

SALT FLATS - GEOGRAPHY

News: Why are salt flats around the world covered in a similar pattern of ridges?

What's in the news?

●       In salt flats across the world, the salt on the surface forms ridges that join together in a patchwork of pentagons and hexagons.

●       These captivating patterns have been photographed as far apart as Bolivia, Chile, China, India (in the Rann of Kutch), Iran, Tunisia, and the U.S. These shapes are also invariably a metre or two across.

What are Salt flats?

●       A salt flat is a natural landscape in which a large area of flat land is covered by salt.

●       Perhaps the world’s most well-known salt flat is the Salar de Uyuni in Bolivia.

●       It is the largest in the world of its kind, and also contains more than half of the planet’s lithium reserves.

●       A salt flat forms from a natural water body whose recharge rate is lower than the evaporation rate.

●       Over time, all the water evaporates, leaving behind the dissolved minerals, usually salts.

●       They reflect sunlight strongly and thus appear bright.

●       The underlying soil is highly saline, even if the water table is shallow, the groundwater is too salty for humans to drink.

How are these ridges formed?

●       Imagine the soil in a salt flat - there are some ridges on the top, followed by a layer of salt, then the topmost layer of the soil, and finally the rest of the soil.

●       The groundwater in the soil is saline but the distribution of salt is not uniform.

●       The salinity is highest near the top of the soil and decreases towards the bottom.

●       The researchers found that the salt penetrated deeper into the soil exactly below the ridges, and remained shallow under the flat areas.

●       That is, if you removed the topmost layer and looked directly down at the soil, you would see that the salty groundwater is flowing deeper into the soil along vertical sheets, not throughout.

Major findings:

●       If the rate of salt deposition on the surface is sufficiently high, the denser groundwater will sink down, and the less-saline, less-dense groundwater will rise to the top.

●       Over time, there will be more saline groundwater rising up towards the surface through the convection cells than through other parts of the soil, resulting in the salt accumulating on the surface and forming the narrow ridges that make up the polygons.

●       The computer model indicates that the subsurface convection is relatively insensitive to salt chemistry, and over time, the convection columns grew to have a stable width of 1-2 m.

Significance of this study:

●       Scientists have proposed a variety of explanations for why the surface of dried salt lakes develops this pattern of polygonal shapes at least since the early 1960s.

●       The majority of them have either thought about dynamics above or below the surface, but the new study demonstrates that polygons are formed when these two realms interact.