Atmospheric and Ocean Circulation Lecture Notes PDF

Summary

These lecture notes cover atmospheric and ocean circulation. Topics include atmospheric composition, energy transfer, and the greenhouse effect. The text also introduces the concept of pressure gradient force and Coriolis force as driving mechanisms in weather patterns.

Full Transcript

**[ATMOSPHERIC AND OCEAN CIRCULATION]**

1. **ATMOSPHERE**

Atmosphere thermal machine.

Atmospheric circulation air movement -- winds

Ocean engine

Winds & Currents redistribute energy

Sun energy source

Water battery

Sun emits electromagnetic radiation (just as all bodies,
Stephan--Boltzman law) [*M* = *σT*^4^]{.math.inline}

Electromagnetic radiation as a function of its frequency (wavelength),
electromagnetic bands:

- UV (\3μm)

- Microwaves (1mm -- 1m)

Sun emits more energy in the visible short wavelength, more energy
radiation

Earth emits more energy in the thermal IR long waves, less energy
radiation

[Atmosphere.]

Emission of the Sun interact with atmosphere before reaching the Earth

Gas thin layer

90% mass up to \~30km

Protecting "shield" (stratosphere)

Air (gas) has several components:

- N 78%

- O 21%

- Ar, Ne, He...

- H2O, CO2, CH4, N2O, O3, particles (needed to create clouds) variable
gases

Tropopause ozone layer, energy release resulting of the chemical
reactions with part of the sun radiation (in stratosphere T increases
with height)

To create clouds (created by liquid or ice water particles) we need:

- condensation nuclei (salt from the ocean)

- temperature drop

- water vapor

Electromagnetic radiation in atmosphere:

- absorbed

- transmitted

- reflected

Most relevant gases in the atmosphere absorb different bands, very
little interaction with the visible band (we can see colours and
everything is not dark):

- CO2 interacts with IR sensible heat wavelength

- H2O interacts with IR

- O3 absorbs completely the UV band

- CH4 does not interact as much with IR as CO2

Greenhouse effect:

1. Short-wave solar radiation -- absorbed by Earth's surface

2. Earth's surface -- emits longwave radiation -- absorbed by GHGs

3. GHGs -- reradiate some energy Earthward, trapping hear in the lower
atmosphere

Some radiation goes out as well

Earth heated by incoming solar energy

Atmosphere heated by IR reradiate by GHGs (CO2 and CH4)

Radiation depends on latitude:

- Lower latitudes sun is higher (closer to the zenith), amount of
energy per unit area at the surface is higher.

- Higher latitudes opposite, added by the energy bouncing (away, loss
of energy) and higher attenuation (thicker atmosphere that the
radiation must penetrate). Polar zones same energy for the double of
unit area

Scattering when energy interacts with a molecule, part of the energy
scattered, is lost (that's why the sky is red in sunset)

Meridional surface T gradient

90˚ N and S (cold, lower T, higher density)

0˚ (warm, higher T for cloud formation, lower density).

Equator air rises by convection, cloud formation, goes up until
tropopause, diverges into N or S. Then due to condensation, release
energy, gets colder, moves and goes down because of density gradient

WATER, characteristics:

1. polar molecule (electrically charged, covalent bonds)

2. cohesive (specially in liquid form, hydrogen bonds, storage of
energy)

3. exists in 3 states at Earth's T

4. high heat capacity a lot of energy needed to heat and evaporate an
amount of water (to separate molecules)

5. absorption and release of heat through condensation and evaporation

Tilted axis of the Earth seasons: amount of energy per unit area varies
over the year

ΔT (meridional T difference or regional/local caused by different
surfaces, clouds, orography) Δρ ΔP Pressure gradient force (drive winds
and ocean currents, perpendicular to isobars, from high to low pressure)

Closer isobars represent a bigger pressure gradient (P variation in
small distance) than more far away isobars (P variation in larger
distance)

Pressure ≡ force per unit area

GENERAL CIRCULATION OF THE ATMOSPHERE

- 1 cell model HADLEY

Contraction in higher latitudes, ↓T, ↑ρ high pressure (air sinks)

Expansion in lower latitudes, ↑T, ↓ρ low pressure (air rises)

\* Missing -- rotation of the Earth

Forces driving the wind (atmospheric circulation):

1. Pressure gradient force [\$PGF = \\frac{\\Delta P}{\\Delta
X}\$]{.math.inline}

2. Coriolis (apparent) force deflects objects (and fluids) trajectories
to the right (left) in the N (S) hemisphere

Angular velocity remains constant in latitude, linear velocity is
higher in lower latitudes. To conserve the momentum tilt to the
right of the direction.

0 in equator, max in polar zones

3. Drag depends on type of surface, changes the flow speed, affects
Coriolis force. Not parallel to isobars but inclined

- 3 cells model FERREL

HADLEY CELL (30˚N to 30˚S) -- convergence in 0˚ (ITCZ, surface),
Trade Winds

Cloud formation at the equator

No seasons wet and dry seasons. convergence zone is wet season, when
it moves to the south or the north is dry season

FERREL CELL (60 to 30˚N and S) -- divergence in 30˚, Westerlies

Polar jet stream

POLAR CELL (90 to 60˚N and S) -- convergence in 60˚, Polar
easterlies

30˚ dry air. Air contracts when goes down, it heats up, pressure
increase becomes drier. Rain not usual

Front 2 different air masses collide. warm air from the south and cold
air from north. Colder air goes under warmer air biggest storms
specially in winter

POLAR JET STREAM \~60˚N, not a line. 2 air masses with different T and
density. Wiggles (Rossby waves)

Extratropical/midlatitudinal storms (weekly) in the polar front
(interphase between 2 air masses). Vortexes can detach and have low
pressure systems

Reality of general circulation very related to continents and water
different thermoproperties:

- land absorbs energy faster, loses energy faster than the water
induces differences in the wind circulations

- continents are not monolithic blocks, have different coastal
contours, differences between hemispheres.

- different mountains, zones with grass, snow, water, asphalt
different surfaces with different thermodynamic properties (through
albedo, amount of energy reflected vs incident energy) ex: forest
and snow different albedo, reflect sun radiation differently,
different impact in lower air, wind can be created between these two
zones. snow zone has a bigger albedo (R/I \~ 1), in a forest the
albedo is smaller.

Semi-permanent high-pressure systems, vary from N to S hemisphere, and
with the seasons

Thermoproperties different in water and land ITCZ moves between the 2
tropics during the year, not straight line.

COASTAL JETS regional winds, regional climate, cause semi-desertic
conditions.

- Strong coastal winds in the left part of the continents, bring cold
air to the surface.

- Produced by sharp contrast between high T inland and lower T over
sea.

- Wind features along Eastern Boundary Currents

- high pressure systems

- cold water (2) no evaporation, air relatively dry even over the
ocean and inland

- cold air

- coast parallel wind (1) no lateral transport from water vapor to
inland (zonal component)

- winds drive upwelling drive cold water from the deep zones into
surface, winds intensify cold

- water with a lot of nutrients (from the deep water), highest fishery
activity in these areas

SEA BREEZE can penetrate inland, low specific heat capacity

2. **OCEAN**

Page 54

north Atlantic very salty because the mediterranean sea is a salt
factory

warm and more dense water goes out of the mediterranean and sinks

AMOC (Atlantic meridional overturning current)

Page 55

close to equator, a lot of evaporation and a lot of rain.

subtropicals higher salinity, a lot of evaporation and less
precipitation

Page 57

the water column of the lake will cool down until it reaches 4 degrees.

when the entire column is 4 degrees, it keeps on cooling and has a
smaller density than the water at 4degrees.

that's why there are blocks of ice in the surface

Page 65

driven by ice formation

warranty of planets climate

the great ocean conve

thermohaline circulation

surface water in mid latitudes and the equator zones will never sink,
there is always a surface layer

Page 69

propagation of the drag force across the depth of the water (across the
different layers in the water surface), until becoming 0

Page 71

surface wind driven currents

effect on water surface is forming a 45 degrees angle (Ekman spiral)

direction of the water is 45 degrees to the right compared to wind
direction

net effect is 90 degrees offset to the wind direction Ekman transport

upwelling caused wind

Page 72

azores high

water net transport into the center, building a dome of water in the
middle (pressure gradient)

Page 73

creates a dome, with convergence of water in the center, this water
starts to go away, creating currents affected by coriolis in their
direction

Page 74

full of bumps

low pressure areas sea surface rises

high pressure areas sea surface lowers