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(accessed 12 February 2018). © NASA.

Graph depicts annual mean absorbed solar radiation, outgoing longwave radiation and net radiation (W m-2) as a function of latitude, 2000–2013.

      Source: Hartmann (2016), figure 2.12, p. 44. © Elsevier.

      The key to understanding wind patterns in the low latitudes is a feature known as the Hadley Circulation (Nguyen et al. 2013), a thermally driven atmospheric circulation that features ascent of equatorial air to a height of about 15 km, with transportation aloft towards the poles, descent at the subtropics and a return flow near the surface. This circulation pattern explains the persistence and extent of the trade winds and the subtropical high‐pressure belt that dominates the climate at low latitudes. There is an overall strengthening trend in the trade winds in the western equatorial Pacific and an overall weakening trend in the eastern equatorial Pacific (Li et al. 2019). This trend can be primarily attributed to a cold tongue mode, an out‐of‐phase relationship in SST anomaly variability between the Pacific cold tongue region in the east and elsewhere in the Pacific. The cold tongue region in the eastern equatorial Pacific (Liu et al. 2019) is characterized by a strong atmospheric subsidence that exerts powerful controls on global circulation patterns and the position of the intertropical convergence zone.

Schematic illustration of annual mean net surface heat flux (W m-2) into the global ocean.

      Source: Public access at https://www.pmel.noaa.gov/ocs/air‐sea‐fluxes (accessed 15 April 2019). © United States Department of Commerce.

      The ITCZ is a narrow band of rising air and intense precipitation. The latter in the ITCZ is driven by moisture convergence associated with the northerly and southerly trade winds that collide at the equator. The ITCZ accounts for 32% of global precipitation (Kang et al. 2018) and moves north and south across the equator following the seasonal cycle of solar insolation and is intimately connected to seasonal monsoon circulations. On an annual average, the ITCZ lies a few degrees north of the equator. The location of the ITCZ has not changed significantly over the past three decades, but there has been a narrowing and strengthening of precipitation in the ITCZ over recent decades in both the Atlantic and Pacific Oceans (Byrne et al. 2018). Climate models project further narrowing and a weakening of the average ascent within the ITCZ as the climate continues to warm.

      Wind speed and direction over the global tropical ocean are thus the result of a balance of forces that vary with distance from the equator. As the Coriolis force is weak at the equator this balance breaks down, although there is reasonable balance until about 6° latitude where some momentum usually carries the wind in the direction it is moving when in near‐geostrophic balance, that is, wind in equilibrium between the pressure gradient and Coriolis forces thus blowing parallel to isobars or contours of height. Thus, there is a strong effect of latitude on the wind field patterns. Vertical wind motion takes place at a range of scales throughout the tropics. This vertical motion is facilitated by the Hadley Circulation, the main means by which the atmosphere tries to move energy from the equator to the poles (Nguyen et al. 2013)

      Schematic illustration of late-seventeenth century chart of global trade winds. (top) Atlantic and Indian Oceans and (bottom) Pacific Ocean. Schematic illustration of late-seventeenth century chart of global trade winds. (top) Atlantic and Indian Oceans and (bottom) Pacific Ocean.

      Source: Modified from Dampier (1699), figures b2 and table 1, p 134 and 156. © John Wiley & Sons.

Graph depicts latitudinal distribution of the annually averaged surface water balance, showing evaporation, E, precipitation, P, and P-E (runoff), 1979–2009.

      Source: Hartmann (2016), figure 5.2, p. 134. © Elsevier.

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