Sea level pressure (SLP) acts, on the one hand, as a %26quot;bridge parameter%26quot; to which geophysical properties at the air-sea interface (e.g., wind stress and sea surface height) are linked, and on the other hand, as an %26quot;index parameter%26quot; by which major atmospheric oscillations, including the well-known Southern Oscillation, are defined. Using 144 yr (1854-1997) of extended reconstructed SLP data, seasonal patterns of its variability are reinvestigated in detail. New features on fundamental structure of its annual and semiannual cycles are revealed in two aspects. First, the spatiotemporal patterns of yearly and half-yearly SLPs are basically determined by a network of %26quot;amphidromes,%26quot; which are surrounded by rotational variations. Fourteen cyclonic and anticyclonic annual SLP amphidromes (half each and often in pair) are found in the global ocean, while the numbers of the two types of semiannual amphidrome are 11 and 9, respectively. The second dominant feature in SLP variability is the pattern of oscillation or seesaw for both annual and semiannual components. At least eight oscillation zones are identified for the annual cycle, which can be categorized into a boreal winter mode and an austral winter mode. As for the semiannual cycle, the seesaw pattern is geographically divided into three regimes: the North Pacific regime, the North Atlantic regime, and the Southern Ocean regime. These findings serve as a new contribution to characterizing and understanding the seasonality of the global ocean-atmosphere system.

• 出版日期2012-4
• 单位中国海洋大学