University of Reading: Salt more important than temperatures in sea ice formation
When polar seas freeze and ice forms, it is not only due to cold air chilling the surface of the water. Even more important is that warm water from the depths of the ocean is prevented from rising to the surface, due to the much lower salinity of the surface water.
Researchers from the University of Reading, the University of Gothenburg and elsewhere have described this effect in a new scientific study published in Science Advances.
Sea ice forms in the polar regions because it gets so cold in winter. However, cold water is heavier than warm water, so the chilled water should sink and not remain on the surface. This sinking should bring the warmer water back to the surface preventing ice to form in the oceans.
Dr David Ferreira, of the University of Reading, said: “The salinity of the surface water is lower, thanks to the supply of freshwater from precipitation to the ocean.
“The difference in salinity between the surface water and the deeper water is an important factor for the formation of sea ice at low temperatures at the poles.
“Without the difference in salinity maintaining the stability, the water would continuously mix deeper and deeper, thus preventing the formation of ice.
“This means salt levels are more important in the formation of sea ice than cold polar temperatures.”
Difference in salinity creates a “lid”
The surface of the water, with its lower salinity, creates a “lid” that prevents warm water from rising to the surface. Without that lid, the cold polar temperatures would not be sufficient to freeze continuously moving warmer water.
The strength of this salinity lid is due to the unique properties of the seawater. In freshwater, water that is colder than 4 degrees Celsius has a lower density and therefore remains at the surface and freezes into ice, without mixing with water from greater depths. In the ocean, saltwater has a density that is lowest exactly at the freezing point, around -2C. The density of the water varies much less with the temperature in cold water than when it is warmer, which is very unusual for a fluid.
Sea ice inhibits the greenhouse effect
Professor Ferreira said: “The closer you get to the poles, the more important salinity is for limiting the mixing and evening out of water temperature throughout the water.
“This discovery shows how important the special properties of the water molecule are for Earth’s climate. The exchange of heat between the ocean and atmosphere is affected not only by temperature differences, but also by the salinity of the ocean. If salty water behaved more like other fluid mixtures, it would be impossible for sea ice to form to any greater extent under current climate conditions. This would require lower greenhouse gases in the atmosphere and large cooling of the planet, or extreme precipitations to maintain the “salt lid” against the temperature effect.
“With global warming, we see a decline in sea ice, which impairs the capacity of the polar seas to maintain the ‘lid’ of lower salinity that prevents carbon from rising into the atmosphere. But at the same time, warmer weather can lead to increased freshwater in the polar seas as glaciers melt and precipitation potentially increases. The difference in salinity can then increase, which may contribute to sustain sea ice formation. But it’s difficult to predict which effect will be dominant – we just have to wait and see.”