Geopotential and isobaric surfaces Geopotential surface: constant Φ, perpendicular to gravitiy, also referred to as “level surface” Isobaric surface: constant p. The pressure gradient force is perpendicular to the isobaric surface. In a “stationary” state (u=v=w=0), isobaric surfaces must be level (parallel to geopotential surfaces). In general, an isobaric surface (dashed line in the figure) is inclined to the level surface (full line). In a “steady” state ( ), the vertical balance of forces is The horizontal component of the pressure gradient force is
Geostrophic relation The horizontal balance of force is where tan(i) is the slope of the isobaric surface. tan (i) ≈ 10-5 (1m/100km) if V1=1 m/s at 45oN (Gulf Stream). In principle, V1 can be determined by tan(i). In practice, tan(i) is hard to measure because p should be determined with the necessary accuracy (2) the slope of sea surface (of magnitude <10-5) can not be directly measured (probably except for recent altimetry measurements from satellite.) (Sea surface is a isobaric surface but is not usually a level surface.)
Calculating geostrophic velocity using hydrographic data The difference between the slopes (i1 and i2) at two levels (z1 and z1) can be determined from vertical profiles of density observations. Level 1: Level 2: Difference: i.e., because A1C1=A2C2=L and B1C1-B2C2=B1B2-C1C2 because C1C2=A1A2 Note that z is negative below sea surface.
Since , and we have The geostrophic equation becomes
Current Direction In the northern hemisphere, the current will be along the slope of a pressure surface in such a direction that the surface is higher on the right In the northern hemisphere, the current flows relative to the water just below it with the “lighter water on its right” Sverdrup et al. (The Oceans, 1946, p449) “In the northern hemisphere, the current at one depth relative to the current at a greater depth flows away from the reader if, on the average, the or t curves in a vertical section slope downward from left to right in the interval between two depths, and toward the reader if the curves slope downward from right to left”
“Thermal Wind” Equation Starting from geostrophic relation Differentiating with respect to z Using Boussinesq approximation (for the upper 1000 meters) Or Rule of thumb: light water on the right. .
Deriving Absolute Velocities Assume that there is a level or depth of no motion (reference level) e.g., that V2=0 in deep water, and calculate V1 for various levels above this (the classical method) When there are station available across the full width of a strait or ocean, calculate the velocities and then apply the equation of continuity to see the resulting flow is responsible, i.e., complies with all facts already known about the flow and also satisfies conservation of heat and salt Use a “level of known motion”, e.g., if surface currents are known or if the currents have been measured at some depths. Note that the bottom of the sea cannot be used as a level of no motion or known motion even though its velocity is zero.
Dynamic Topography
Relations between isobaric and level surfaces A level of no motion is usually selected at about 1000 meter depth In the Pacific, the uniformity of properties in the deep water suggests that assuming a level of no motion at 1000m or so is reasonable, with very slow motion below this In the Atlantic, there is evidence of a level of no motion at 1000-2000 m (between the upper waters and the North Atlantic Deep Water) with significant currents above and below this depths That the deep ocean current is small does not mean the deep ocean transport is small
Level of No Motion (LNM) Pacific: Deep water is uniform, current is weak below 1000m. Atlantic: A level of no motion at 1000-2000m “Slope current”: Relative geostrophic current is zero but absolute current is not. May occurs in deep ocean (barotropic?) Current increases into the deep ocean, unlikely in the real ocean