6.3: Geographical Distribution of Surface Temperature and Salinity

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The distribution of temperature at the sea surface tends to be zonal; that is, it is independent of longitude (figure \(\PageIndex{1}\)). Warmest water is near the equator, coldest water is near the poles. The deviations from zonal are small. Equatorward of 40\(^{\circ}\), cooler waters tend to be on the eastern side of the basin. North of this latitude, cooler waters tend to be on the western side.

Contour maps of mean sea-surface temperature calculated from the optimal interpolation technique. Top map shows data for July and bottom map shows data for January. — Figure \(\PageIndex{1}\): Mean sea-surface temperature calculated from the optimal interpolation technique (Reynolds and Smith, 1995) using ship reports and AVHRR measurements of temperature. Contour interval is 1\(^{\circ}\)C with heavy contours every 5\(^{\circ}\)C. Shaded areas exceed 29\(^{\circ}\)C.

The anomalies of sea-surface temperature, the deviation from a long term average, are small, less than 1.5\(^{\circ}\)C (Harrison and Larkin, 1998) except in the equatorial Pacific where the deviations can be 3\(^{\circ}\)C (figure \(\PageIndex{2}\): top).

The annual range of surface temperature is highest at mid-latitudes, especially on the western side of the ocean (figure \(\PageIndex{2}\): bottom). In the west, cold air blows off the continents in winter and cools the ocean. The cooling dominates the heat budget. In the tropics the temperature range is mostly less than 2\(^{\circ}\)C.

Two contour maps; top map shows sea-surface temperature anomalies for January 1996 relative to the mean temperature shown in figure 1 above. Bottom map shows annual range of sea-surface temperature calculated from the Reynolds and Smith (1995) mean sea-surface temperature data set. — Figure \(\PageIndex{2}\): **Top:** Sea-surface temperature anomaly for January 1996 relative to mean temperature shown in figure \(\PageIndex{1}\) using data published by Reynolds and Smith (1995) in the Climate Diagnostics Bulletin for February 1995. Contour interval is 1\(^{\circ}\)C. Shaded areas are positive. **Bottom:** Annual range of sea-surface temperature in \(^{\circ}\)C calculated from the Reynolds and Smith (1995) mean sea-surface temperature data set. Contour interval is 1\(^{\circ}\)C with heavy contours at 4\(^{\circ}\)C and 8\(^{\circ}\)C. Shaded areas exceed 8\(^{\circ}\)C.

The distribution of sea-surface salinity also tends to be zonal. The saltiest waters are at mid-latitudes where evaporation is high. Less salty waters are near the equator where rain freshens the surface, and at high latitudes where melted sea ice freshens the surface (figure \(\PageIndex{3}\)). The zonal (east-west) average of salinity shows a close correlation between salinity and evaporation minus precipitation plus river input (figure \(\PageIndex{4}\)).

Two contour maps; top map shows annual mean sea-surface salinity and bottom map shows annual mean precipitation minus evaporation. — Figure \(\PageIndex{3}\): **Top:** Mean sea-surface salinity. Contour interval is 0.25. Shaded areas exceed a salinity of 36. From Levitus (1982). **Bottom:** Precipitation minus evaporation in meters per year calculated from global rainfall by the Global Precipitation Climatology Project and latent heat flux calculated by the Data Assimilation Office, both at NASA’s Goddard Space Flight Center. Precipitation exceeds evaporation in the shaded regions, contour interval is 0.5 m.

Line graph showing the zonal average of sea-surface salinity and the difference between evaporation and precipitation as shown in Figure 3. — Figure \(\PageIndex{4}\): Zonal average of sea-surface salinity calculated for all the ocean from Levitus (1982) and the difference between evaporation and precipitation \((E - P)\) calculated from data shown in figure \(\PageIndex{3}\) (bottom).

Because many large rivers drain into the Atlantic and the Arctic Sea, why is the Atlantic saltier than the Pacific? Broecker (1997) showed that 0.32 Sv of the water evaporated from the Atlantic does not fall as rain on land. Instead, it is carried by winds into the Pacific (figure \(\PageIndex{5}\)). Broecker points out that the quantity is small, equivalent to a little more than the flow in the Amazon River, but “were this flux not compensated by an exchange of more salty Atlantic waters for less salty Pacific waters, the salinity of the entire Atlantic would rise about 1 gram per liter per millennium.”

World map showing transport of water into and out of the Atlantic by atmosphere. Basins draining into the Atlantic are black, deserts are white, and other drainage basins are shaded. Arrows give direction of water transport by the atmosphere, and values are in Sverdrups. — Figure \(\PageIndex{5}\): Water transported by the atmosphere into and out of the Atlantic. Basins draining into the Atlantic are black, deserts are white, and other drainage basins are shaded. Arrows give direction of water transport by the atmosphere, and values are in Sverdrups. Bold numbers give the net transport for the Atlantic at each latitude band. Overall, the Atlantic loses 0.32 Sv, an amount approximately equal to the flow in the Amazon River. After Broecker (1997).

Mean Temperature and Salinity of the Ocean

The mean temperature of the ocean’s waters is: \(t = 3.5^{\circ}\text{C}\). The mean salinity is \(S = 34.7\). The distribution about the mean is small: 50% of the water is in the range: \[\begin{array}{c} 1.3^{\circ}\text{C} < t < 3.8^{\circ}\text{C} \\ 34.6 < S < 34.8 \end{array} \nonumber \]

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