With the increase in ‘source’ depth, the transport of phosphorus

With the increase in ‘source’ depth, the transport of phosphorus was reduced to 2.5 tons m−1 at 45 m depth for the upwelling off the northern Seliciclib ic50 coast and at 65 m depth off the southern coast. In the case of nitrogen the behaviour was slightly different. The greatest transport was from the depth interval of 40–65 m off the southern coast ( Figure 5d) and 43–49 m in the case of the opposite coast ( Figure 5b). The regional upwelling response pattern differs more than 2.5 times – during the southern coast upwelling more than 10 tons m−1 of nitrogen was brought to the surface layer from depths of 45– 55 m, while off the northern coast the highest values were no more than 4 tons m−1 from depths of 40–45 m. The deeper

layers were quite inefficient as nutrient sources for the euphotic layer during short-term upwelling events. Less than 1 ton m−1 of nitrogen was brought to the surface layer from depths of over 53 m and 73 m during the upwelling events along the northern and the southern coasts respectively. The results of a similar nutrient transport

simulation with a 50% smaller wind stress (τ = 0.5 τ0) are shown in Figure 6. The reduction in wind stress results in the overall decrease of amounts of upwelled nutrients. In particular, the largest transport of phosphorus remained in the upper 15–25 m layer off both coasts, whereas nitrogen transport from deeper layers was vanishingly small for the upwelling along the northern coast (< 0.75 tons m−1 from depths greater than 35 m). As regards the southern coast, N-acetylglucosamine-1-phosphate transferase the largest transport of nitrogen remained Trichostatin A purchase in the depth range of 40–55 m with the maximum at 45 m. Nutrients are considered to be conservative passive tracers, and it is therefore possible to transform the cumulative amount of nutrients per metre Δm10/Δz to a volume of water V10, which is cumulatively transported to the upper 10-m layer from a 1 m thick layer at a certain depth z: equation(1) V10=1C(z)Δm10Δz,where C(z) is the initial

nutrient concentration at depth z ( Figure 3). The cumulative volume transports per unit source layer thickness to the upper 10-m layer during the upwelling along the northern and the southern coasts with different wind stresses are shown in Figure 7, and the snapshot of upwelled volumes during the maxima of nutrient amounts on the 6th simulation day in Figure 8. It is seen in both Figure 7 and Figure 8 that the total volume of water transported to the upper 10-m layer from the top depth interval of 15–19 m was almost the same for the upwelling events off the northern and the southern coasts of the Gulf, with the maximum of 6.7 × 109 m2 ( Figure 8). Such equality of upwelled volumes is achieved as a result of the predominance of vertical turbulent diffusion (vertical mixing) over vertical advection, as the intensity of turbulent mixing in the upper sea is governed by wind force rather than wind direction.

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