1.
Direct forcing of Ocean
heat
budget - sunlight
evaporation
infrared emission
sensible heat
winds
tides
2.
Tides
Tidal
forcing is the result of the gravitational pull of the moon
and the sun. The earth-moon-sun system is in balance, with
gravitational forces balancing the centripetal forces
associated with their orbits around the centre of mass of the
system. The sun is much larger than the moon, but also much
farther away, so the solar tides are half the size of lunar
tides.
How
do tidal currents result? Consider the earth-moon system only.
The gravitational force of the moon is matched by the
centripetal force of the earth rotating around the centre of
gravity of the earth-moon system (which is 3/4 of the way from
the centre of the earth to its surface). But, if we look at a
place on the surface of the earth that is closer to the moon,
there is an excess of gravitational force. On the surface of
the earth farthest from the moon, the centripetal force will
be slightly greater. This causes two tidal bulges, one towards
the moon and one away from the moon. Since there are two
tidal bulges at any one time and the earth rotates once per
day, then we expect two tides per day: the forcing is
SEMI-DIURNAL.
There
are many tidal constituents, in addition the the
semi-diurnal due to the interaction of the solar and lunar
tidal forcings at different periods and due to long-term
changes in the orbits of the earth-moon-sun system. The
principal lunar and solar tides “beat” at periods of
fourteen days, acting in concert to produce SPRING tides and
in opposition to produce NEAP tides.
spring tide neap tide
Because
of the cyclical nature of tides, tidal height and tidal
currents can be predicted along the coasts using measurements
collected over many years (18 years to account for some
orbital variations) and harmonic analysis. The most accurate
estimates of open ocean tidal currents come from satellite
altimeter data.
When
considering the large-scale, open ocean circulation the
effect of tidal currents is small. Averaged over a day or
two the tidal currents slosh back and forth with little mean
effect on the flow. Therefore, in the case of snapshots of
ocean circulation from hydrographic data, for example, tides
might be considered noise and need to be removed. For time
series data, we often filter out tides using low-pass
filters, and concentrate on the longer time scale flows.
However, the tides do effect the mean circulation in a very
important way that cannot be filtered out - through MIXING.
Tidal mixing is the result of the high frequency
fluctuations of tidal currents and of breaking internal
waves. This important tidal mixing is “parameterized” in the
equations of motion as EDDY VISCOSITY AND EDDY DIFFUSION - a
transfer of energy from large scales to small scales.
3.
Winds
In
each hemisphere there are three main zonal bands of winds,
driven by the vertical circulation of the atmosphere (see Heat
section below). Close to the pole there are easterlies, at
subpolar latitudes there are westerlies, and at subtropical
latitudes there are the trade winds. The trades are
northeasterly in the northern hemisphere and southeasterly in
the southern hemisphere. At the equator (just north) is the
Intertropical convergence zone where winds are light.
Seasonality:
Winds are stronger during winter than summer, and in the
northern Indian Ocean and northwest Pacific winds change
direction due to the Asian monsoon.
Winds
blowing over the ocean exert a STRESS on the ocean surface
that is proportional to the wind speed squared. The wind
stress accelerates the flow in the upper ocean, causing a
velocity shear, du/dz. The resulting force on a parcel of
water is proportional to the vertical gradient of this
velocity shear. The depth over which the wind stress
directly accelerates ocean currents is about 50 - 100 m and
is called the EKMAN LAYER.
4.
Heat budget
Important
to remember that the atmosphere does not just drive the ocean,
but also the ocean drives the atmosphere: it is a COUPLED
DYNAMIC SYSTEM.
The
ocean is the dominant source of heat that drives atmospheric
circulation: the uneven distribution of sea surface
temperature (SST) drives winds. Also, evaporation from the
tropical oceans transfers heat, in the form of water vapour,
into the atmosphere. The heat is released when the water
vapour condenses and it rains.
The
atmosphere is almost transparent to sunlight, directly
absorbing only 20%. Half of the sunlight reaching earth is
absorbed by the ocean. Most heat stored by the ocean is
released locally. The remainder is transported to higher
latitudes by ocean currents (thermohaline circulation).
Oceanic heat storage and heat transports help moderate the
seasons at high latitudes. Oceanic heat transport is not
steady and may play a role in the development of ice ages and
rapid climate change.
Surface
heat fluxes:
Insolation,
Q_SW,
function of latitude, time of day, cloudiness, season
Latent
heat of evaporation, Q_L,
function of wind speed and relative humidity
Net
long wave, Q_LW,
function of sea surface temperature
Sensible
heat (conduction), Q_S,
function of air-sea temperature difference and wind speed
In
the mean there is large heat gain by the ocean in the tropics
and large heat loss over the western boundary current systems.
The primary balance at low and mid latitudes is between
insolation and evaporation. Measurements of surface heat flux
come from ships and more recently from satellites. Flux
estimates in the Southern Ocean are poor due to a lack of
measurements. Climatologies have typical global misbalances of
30 W/m2.
Interesting
to note that atmosphere warms primarily as a result of RAIN
and long-wave radiation from the ocean (not directly from
sun). Since overall the atmosphere and ocean gain heat in
the tropics and lose heat over the poles there must be a
transport of heat by the ocean and atmosphere from the
equator towards the poles. This north-south transport is
called the MERIDIONAL HEAT TRANSPORT. It peaks at 6 PW at 35
degrees latitude. About one quarter of this transport is
carried by the ocean.
Resources
Climatologies
of wind stress and heat fluxes: COADS, NCEP, ECMWF,
Quikscat, NOC (formerly SOC) climatology.
Reading
Stewart,
chapters 4, 5, and 17.
Aug
2007