Which ocean basins do you know?
Pacific, Atlantic, Indian, Southern, Arctic
What do you think how deep the ocean is? On average? At its deepest point?
mean: 3734m
median: 4093m
deep maximum: 11022m (Mariana trench in western Pacific)
How does the landscape at the bottom of the ocean look like?
Seafloor divided in three distinct provinces:
Continental margin:
shelf -> gravel and sand (<150m)
slope -> mud (100m - several km)
rise -> 3000-4000m
Deep ocean
abyssal plains (mostly smooth)
abyssal hills
seamounts
deep sea trenches (clay/oozes (mineralic and organic)
Mid ocean ridges
shallow or steep flanks (spreading rate)
crest (spreading center)
How do we know what the bottom of the ocean looks like?
echo sounding and seismic reflection rely on sound pulses that reflect off the ocean floor and off sedimentary layers
Altimetry: relies on satellites deducing different sea level depths due to different masses of the water column or rock/mud beneath the seasurface
Autonomous systems: equpped with multibeam echo sounder -> high resolution images due to proximity to seafloor
How can the topography of the ocean bottom affect the circulation?
dense bottom waters are seperated by MORs and can only leak through small gaps (fracture zones)
trenches can steer and impact deep boundary currents
ocean bottom roughness affects ocean mixing rates
seamount chains refract tsunamis and change their propagation direction
What is special about water (interms of physical properties)?
High surface tension
high heat capacity (4187J/kg) -> heat storage -> 90% of anthropogenic global warming is absorbed in the ocean
heat capacity of the whole atmosphere resembles heat capacity of top 3.2m of ocean
Good solvent -> slightly negatively charges O and slightly positively charged H2 form a dipole that binds all kinds of stuff
density anomaly at 3.98°C
Why does ice float?
Water has its highest density at 3.98°C, at lower temperatures H2O molecules form hexagonal clusters which take up more space -> ice floats
Which varaibles determine the density of seawater?
Salinity
Temperature
Pressure
Is saline water more or less dense than freshwater?
It is more dense as there are more ions in tthe water
Can you directly compare the temperature measured at different water depths?
No, there is an in situ temperature (the one a parcel of water has) and a potential temperature (the one that a parcel of water has if it is moved adiabatically to the surface)
Adiabatic: thermodynamic process in which a given system is moved from one pressure tto another without exchange with its environment (e.g. a Nisken bottle)
-> the in siu T would be warmer than the potential T
Is sound in the ocean faster or slower than air?
Acoustic waves are:
compressional waves
longitudinal polarized (displacement parallel to vector)
dispersionless (phase speed indipendent of frequency)
Speed of sound:
air: 341 m/s
water: 1480 m/s
not constant in water, depends on density
p-change: 1.8m/s/100m
T-change: 5m/s/°K
S-change: 3m/s/g/kg
Where in the water column is the speed particularly high and why?
In water masses of particularly high densities, but also high temperatures (si at surface and deep ocen fast)
also: SOFAR-Channel
sound fixing and ranging channel -> sits at the minimum of the curve from vertical sound speed (mid depths) -> pressure increase to the deep (faster) counteracts temperature increase to surface (faster) -> around 500m depth
As a result of Snell’s law, sound waves are refracted towards regiions with lower sound speeds
far sound travel in SOFAR channel (esp. for low frequencies)
Why does the ocean appear blue?
Photons of longer wave lengths are absorbed before photons at shorter wave lengths and thus continuous attenuation of light other than blue, make the ocean appear blue
Furtther: blue light is more likely to be scattered (randomly reflected back in all directions
How deep does light reach into the ocean?
Depends on turbidity/clarity
Maximum values of the euphotic zone (1% light left) for very clear waters: ~100m
What are the sources and sinks of freshater in the ocean?
Sources:
precipitation
river runoff
ice melting
ground water flow
Sinks:
evaporation
ice formation and brine rejection
What are the units of transport and flux of salt and heat, respectvely?
Transport: Stuff per time
water: m3/s
salt: hg/s
heat: J/s =. W
Flux: transport per unit area
heat: W/m2 (e.g. heat loss of. sea surface)
volume flux: m3/s*m2
Budget:
Transport in and out of a closed system
Which earth surfaces reflect a lot of the incoming solar radiation?
Average solar heating: 342 W/m2
Albedo: fraction of incident radiation (light), that is reflected by a surface/body - High Albedos: Desert Sands < Clouds < bare ice < ice and snow (alpha = 0.9)
There are heat fluxes
Ocean <-> Atmosphere
Atmosphere ~ Wind
Atmosphere ~ Condensation
Sum of the heat fluxes are
flux of sunlight into the ocean(Qsw)
net flux of infrared radiation from the ocean (Qlw)
flux of heat out of the sea due to conduction (Qsen)
flux of heat carried by evaporated water (Qlat)
change of heat storage (QT)
divergance of heat transport (Qv)
Why aren’t the polar regions getting colder every year even though these regions experience a net surface heat loss?
high latitudes -> high albedos (sea ice and snow) -> net heat. deficiency
BUT: divergance of heat transport Qv!
Areas of net gain ((sub-)tropics) and loss annihilate each other due to convection in atmosphere + THC (warm waters flow poleward, cold sink and flow equatorwards)
What water masses have you heard of?
NADW
NEADW
LSW
AAIW
AABW
Which properties could be used to define a body of water that has the same origin?
Definition of a body of water:
temperature, salinity, oxygen, nutrients, helium, chlorofluorocarbons, SF6
Most water masses acquire their characteristics at the sea surface
When it sinks it carries these properties with it -> slow mixing with sourroundng waters
Where do the coldest waters, that are found at the bottom of the ocean originate from?
Polar regions - AABW - originates from Antarctic shelf - prone to:
open ocean convection, increased density due to air-sea-ice buoyancy loss
shelf convection (at ploynyas, caused by catabatic winds), air-sea-ice buoyancy loss, ice formation - brine rejection and buoyancy loss -> slides down continental shelf (overflow) to great depth
also entrain neighboring waters
What effect does the formation of sea ice have on the salinity of the surface water?
Sea ice is from fresh water, brine is rejected during the formation and increases salinity of sourrounding waters
How and where are NADW and AABW formed?
NADW:
originated from North Atlantic Ocean - deep water mixing in Greenland and Labrador sea, forms by deep convection with significant entrainment (mixing with surrounding water)
AABW:
ooriginates from coastal regions around Antarctica, forms by shelf convection with significant entrainment (sea ice important role)
Why is the water in the ocean moving? What are the acting forces?
Large scale ocean circulation is forced by
wind stress on sea surface -> wind driven circulation
Buoyancy fluxes (heat and freshwater fluxes) -> Thermohaline circulation
Forces acting on the ocean. (in all cardinal directions)
pressure gradient force:
P1 and P2 act over a distance x on different sides of water cubicle
Results: -(δp/δx)
differnet pressures because of different sea level height and different densites
Friction
wind stress τ: prportional to the square of windspeed, transmitted downward as a result of fricttion (not beyond 50-100m)
bottom drag: provokes frictiion boundary layer at the seafloor, dependent on the structure of seafloor
Coriolis - apparent force
dependent on:
lattitude
speed of particle
Gravity - towards the center of earths mass
Tides
Is the ocean flow impacted by tthe rotatiion of the earth?
Air and water not only follow pressure gradient but are deflected by Coriols
What is the effect of the Coriolis force?
NH: deflection of objects to the right
SH: deflectiion of objects to the left
What is the notation for the zonal, meridional and vertical currents?
Zonal: UE ; ∂u/∂t-fv=1/p*∂p/∂x+R
Meridional: VE ; ∂v/∂t+fu=-1/p*∂p/∂y+R
Vertical: (W)??; ∂p/∂z=-ρg
Where do we find upwelling regions in the ocean and why are they located there?
Mostly EBUS or equatorial upwelling system
What is described by the geostrophic balance?
Major forces in the ocean:
1: acceleration (change of velocity due to force imbalances)
2a: horizontal advectioin of velocty
2b: vertical advection of velocity (mostly small, not discussed)
3: Coriolis force
4: Pressure gradent force
5: Viscous forces (turbulent viscosity, eddy friction)
6: Frictional forces (wind stress)
The geostrophic balance is between the coreolis force (3) and the pressure gradiient force (4)
-> forces flow along isobars (high pressure on the right)
BUT: isobars ≠ isopycnals -> baroclinic conditions:
the deeper, thesmaller the PGF because relative pressure differences provoking pressure differences become smaller
flow generated by PGF becomes smaller
Thermal wind equation:
geostrophic balance (3) + hydrostatic balance / PGF (4) = thermal wind equation (6)
relates the vertical “shear” of the horizontal flow to the horizontal density dradientdue
basically: how strong is the change of flow with depth
How does the direct wind forcing reach down into the ocean?
Ekman layer depth: 20m to maximum 150m
calculated via
How the wind influence could generate currents deeper into the ocean?
Ekman spiral:
Balance of coreolis force (3) and frictional force (wind - 6)
water set in motion by wind -> if several days: flow near surface described by coreolis force and vertical friction
wind stress is transmitted downwards by internal friction
Coriolis effect set into play creating wind driven frictional layer called called ekman layer -> propagates deep
Coriolis force is a function of latitude and speed
Ekman layer depth is the e-folding deptth of decaying velocity
Vertical integration of horizontal velocity within the Ekman layer is called Ekman Transport
How are Ekman Transport and Upwelling related?
Equatorial setting:
Ekman transport due to easterly winds provoke divergence and depression of sea level height -> replenished by underlying cold waters + upwards shift of thermocline
visible as equatorial cold tongue (Atl + Pac)
Coastal setting:
Equatorward coast-parallel winds lead to Ekman transport off-shore
BUT: Ekman transport tilts sea surface height provoking an addditional, opposing PGF towards coast
YET balanced out by Coriolis force causing coast-parallel geostrophic surface flow
THIS forces an onshore flow (see picture GF) in the bottom boundary layer that. supplies the coastal upwelling
ADDITIONALLY wind stress curl, provoking increased water heights towards equator result in. a net laaaarge scale PGF towards the pole., which satisfied by poleward undercurrents (PF)
What forces ocean surface waves?
Winds -> wind speed + fetch and time relevant for wave height
Seismic disruptions (earthquakes, landslides) -> Tsunamis: off-shore, fast and long wave length, small amplitude; on shore, slows, energy conserved -> amplitude grows
Gravitational attractoin of moon and sun
Opposing and restoring forces:
Surface tensioin (creating capillary waves)
Gravity (creating wind waves, Tsunamis, Tides)
Wave characzeristics:
Wave number: k=2π/λ (λ = Wavelength)
Frequency: ω= 2π/T (Period: time required for a wave crest(maximum) to reach from a certain point to another)
Phase speed: c= λ/T → c= ω/k
Why are there two high tides and two low tides in many coastal areas each day?
earth rotates with respect to moon with a period of 24h50min -> equilibrium tidal bulges would need to travel in the opposite direction in order to maintain their positiioins relative to the moon -> two high and two low tides per lunar day
BUT: actual tides do not behave as equilibrium tides
depth of ocean
land masses constrict preferred directiioin of flow
inertia causes time lag in oceans response to tractiive forces
Coriolis force deflects tidal flows
What are differences and similaritiies between the North Sea and the Baltic Sea?
Similarities: Both marginal and relatively shallow Seas of North Atlantic
Salinity:
Baltic has significant west to east salinity gradient 18-2psu, larger river catchment area + low volume
North Sea is northwards open to ocean psu-values, coastal ares slightly lower (catchment and baltic runoff)
Exchange:
Baltic is very enclosed wiith only one opening-> storms needed
North Sea is open to the Atlantic (english Channel + Faire-Isle Channel and North Sea Plateau
Topography/Tides:
Baltic has no tides + very weak circulation, exchange
North Sea has strong seasonal and daily circulation due to winds, (anti-)clockwise circulation in basin (seasonal) + domiinant diurnal spring-neap tides superimpose everything else in the Baltic (mainly M2 and S2 constituents)+ shallow topography makes permanent displacement of water possible
Depth:
Baltic <30m
North Sea ~90m (including deep norwegian trench ~800m)
Temperature:
Baltic has very high surface temperature iin summer because it is so shallow
North Sea has mean summer temperature of 17°C
Oxygen:
Baltiic has pronounced regions of hypoxia/anoxia
North Sea has frequent mixing and displacement does not provoke oxygen deficiencies
Low oxygen areas are prevalent at the bottom of the Baltic Sea. Do you have an idea why this could be the case?
Baltic is permanently stratified water body (no pronounced autumn or winter mixing to full depths)
in summer: 3-layer-stratification witha thermocline at 15-20m depth and a strooong halocline at 30-70m depth -> very diffiicult vertical advection
in winter: still two layer stratification with strong thermocline due to immense psu differences not advected
Therefore, especially iin the deep basins -> water does not become advected on a winterly basis
Deep water exchange and replenishment of oxygen is limited to singular storm events (e.g. 2014) and only weak continuous vertical advectioin in Baltic
Baltic sea has large catchmnet ares (85 Mio. inhabitants) -> strongly eutrophied and high export productioin
The winds in the equatorial Atlantic and Pacific are easterly, i.e. blowing from the east to the west. What implications does that have for the sea surface height and sea surface temperature along the equator? Does it also impact the thermocline?
easterly winds transport warm and less dense surface water to the western end of the basin, where it is piled up
-> tilted sea-level with negative west to east gradient (PGF develops) + warm pool at western end of basins
replacement of water at eastern margins of basin through colder deep-water (reaching all the way to surface) -> thermocline tilted, flattens in the east
What comes to your wind when you hear the term El Nino?
Usually: easterly trade winds -> warm SSTs in W and colder in E -> tilted tehrmocliine, deep convection over western warm pool -> heavy rains
El Nino conditioins: every few years trade winds weaken -> warm pool migrates eastwards -> thermocline flattens ->.less equatorial upwelling in east -> disappearance of equatorial cold tongue -> deep convectioin follows warm pool eastwards -> heavy rains over middle of pacific
Often followed by La Nina: trade winds come back strionger than normal -> push warm water extremely westward -> steep thermocline -> center of convection extremely to the west, especially pronounced eastern pacific cold tongue
SST and surface air pressure (Tahiti-Darwin Islands) are good proxies for La Nina/El Nino
Why is there a rain and a dry season in India?
Indian subcontinent shows big-scale seasonal reversals
January: from continent to ocean <—> July: from ocean
Physical ingredients:
Land sea differences: differing heat capacities of land and water -> also, water stores more heat because vertical entrainment and future release
Planetary rotatoin: iintroduces swirl + much stronger winds
Moisture: Water vapor, collected over oceans throug evaporation, condenses over land + marginal seas releasing vast quantities of heat
Orography: Acts as elevated heat source which intensifies flow and also ducts flow
And the in summer -> water vapor collected over ocean precipitates at west ghats and Himalayas
In winter, winds from north to south do not pick up any moisure siince they only drift over land
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