Basic definitions, terms, e.g., Climate, climatology, anomaly, teleconnection, …
Trace gases, anthropogenic increase Perspective from paleoclimate on where fossil fuels come
from, some idea of time scales, natural variability, are recent changes unusual,..
ENSO material, mostly as comes back in chpt 4.
Chapter 1. Intro…. Review elements include:Chapter 1. Intro…. Review elements include:
Mid-course overview(NB: overview a guide but not necessarily everything)
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Climate: average condition of the atmosphere, ocean, land surfaces and the ecosystems in them (includes average measures of weather-related variability, e.g. storm frequency)
Weather: state of atmosphere and ocean at given moment. Average taken over January of many different years to obtain a
climatological value for January, etc.
1.1 1.1 Climate dynamics, climate change and climate predictionClimate dynamics, climate change and climate prediction
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Climate change:• occurring on many time scales, including those that affect
human activities.• time period used in the average will affect the climate that one
defines. • e.g., 1950-1970 will differ from the average from 1980-2000.
Climate variability: • essentially all the variability that is not just weather.
• e.g., ice ages, warm climate at the time of dinosaurs, drought in African Sahel region, and El Niño.
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Global warming: predicted warming, & associated changes in the climate system in response to increases in "greenhouse gases" emitted into atmosphere by human activities.
Greenhouse gases: e.g., carbon dioxide, methane and chlorofluorocarbons: trace gases that absorb infrared radiation, affect the Earth's energy budget.
warming tendency, known as the greenhouse effect
Climate prediction endeavor to predict not only human-induced changes but the natural variations. e.g., El Niño
Climate models: • Mathematical representations of the climate system
• typically equations for temperature, winds, ocean currents and other climate variables solved numerically on computers.
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El Niño:• largest interannual (year-to-year) climate variation interaction between the tropical
Pacific ocean and the atmosphere above it.• a prime example of natural climate variability.• first phenomenon for which the essential role of dynamical interaction between
atmosphere and ocean was demonstrated.
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Teleconnections: remote effects of El Niño (or other regional climate variations).
Anomaly: departure from normal climatological conditions. • calculated by difference between value of a variable at a given
time, e.g., pressure or temperature for a particular month, and subtracting the climatology of that variable.
Climatology includes the normal seasonal cycle.• e.g., anomaly of summer rainfall for June, July and August
1997, = average of rainfall over that period minus averages of all June, July and August values over a much longer period, such as 1950-1998.
• To be precise, the averaging time period for the anomaly and the averaging time period for the climatology should be specified. • e.g., monthly averaged SST anomalies relative to 1950-2000 mean.
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1.4 1.4 Global change in recent historyGlobal change in recent history
Air main constituents Formula Concentration
Nitrogen N2 78.08%
Oxygen O2 20.95%
Water H2O 0.1 to 2 %
Trace gas name Concentration (in 2004)
Carbon dioxide CO2 377 (parts per million) ppm, ~0.038%
Methane CH4 1.75 ppm
Nitrous oxide N2O 0.32 ppm
Ozone O3 0.000251 ppm (atm. average) (~10 ppm max in stratosphere)
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Table 1.1
Carbon dioxide concentrations since 1958,measured at Mauna Loa, Hawaii.
Figure 1.1
•Annual, interannual variations:biological impacts on carbon cycle
•Trend: due to fossil fuel emissions.
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Figure 1.2
Concentration of various trace gases
estimated since 1850
•Methane: Cattle, sheep, rice paddies, fossil fuel by-product; wetlands, termites (parts per billion).
•Nitrous Oxide: biomass burning, fertilizers?
•Chlorofluorocarbons: man-made, zero before 1950 (parts per trillion).
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Figure 1.3
Global mean surface temperatures estimated since preindustrial times
• Anomalies relative to 1961-1990 mean• Annual average values of combined near-surface air temperature
over continents and sea surface temperature over ocean. • Curve: smoothing similar to a decadal running average.• From University of East Anglia Climatic Research Unit, Brohan
et al. (2006).Neelin, 2011. Neelin, 2011. Climate Change and Climate Modeling, Climate Change and Climate Modeling, Cambridge Cambridge
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ENSO: El Niño/Southern Oscillation. [Cont’d in Chpt 4]
• El Niño is associated with warm phase of a phenomenon that is largely cyclic.
• La Niña for the cold phase. El Niño arises in tropical Pacific along the equator.
• Changes in sea surface temperature, ocean subsurface temperatures down to a few hundred meters depth, rainfall, and winds: ocean-atmos. interaction!
• Variations in the Pacific basin within about 10-15 degrees latitude of the equator are the primary variables.
1.5 1.5 El Niño: An example of natural climate variabilityEl Niño: An example of natural climate variability
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Paleoclimate: A few climate notes with Geological time scaleFigure 1.12
Very distant past--- Myr=millions of years
Key points: Climate can vary substantially, on
all timescales Long periods in deep past with
warmer climate than present (& higher est. CO2 )
deposition over 100s of millions of years sequesters carbon dioxide as fossil fuels (oil, coal, natural gas)
return of this CO2 to atmosphere occurring over very short period.
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Antarctic ice core records of CO2, deuterium isotope ratio variations (D), and Antarctic air temperature inferred from D
Figure 1.13
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Climate processes • solar radiation tends to get through the atmosphere; ocean
heated from above stable to vertical motions.• warm surface layer, colder deep waters
• mixing near ocean surface upper mixed layer ~ 50 m• mixing carries surface warming down as far as
thermocline, layer of rapid transition of temperature to the colder abyssal waters below
Chapter 2 Basics of Global Climate
2.1 2.1 Components and phenomena in the climate systemComponents and phenomena in the climate system
Review elements include:Review elements include: Basic concepts and terminology that tend to recur later:
• E.g., albedo, moist convection, easterly winds
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Satellite image based on visible light with 5°x5° grid overlay
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Courtesy of NASA
Figure 2.2
For each grid box in a climate model, only the average across the grid box of wind, temperature, etc. is represented.
The average of smaller scale effects has important impacts on large-scale climate.•e.g., clouds primarily occur at small scales, yet the average amount of sunlight reflected by clouds affects the average solar heating of a whole grid box.
Parameterization: representing average effects of scales smaller than the grid scale (e.g., clouds) as a function of the grid scale variables (e.g. temperature and moisture) in a climate model.
The parameterization problem
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2.2 2.2 Basics of radiative forcingBasics of radiative forcing
Solar radiation input: Infrared radiation (IR) is the only way this heat input can be balanced by heat loss to space
Since IR emissions depend on the Earth's temperature, the planet tends to adjust to a temperature where IR energy loss balances solar input:
Blackbody radiation: approximation for how radiation depends on temperature:
Total energy flux integrated across all wavelengths of light
R = T4
Full climate models do detailed computation as a function of wavelength, for every level in the atmosphere, …
[& Trace gases absorb IR at wavelengths where O2, N2 ineffective….]
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Pathways of energy transfer in a global average
Figure 2.8
2.3 2.3 Globally averaged energy budgetGlobally averaged energy budget
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Greenhouse effect:•The upward IR from the surface is mostly trapped in the atmosphere, rather than escaping directly to space, so it tends to heat the atmosphere. •The atmosphere warms to a temperature where it emits sufficient radiation to balance the heat budget, but it emits both upward and downward, so part of the energy is returned back down to the surface where it is absorbed.•This results in additional warming of the surface, compared to a case with no atmospheric absorption of IR.
Atmosphere emits IR downward absorbed at surface.
•Both gases and clouds contribute to absorption of IR and thus to the greenhouse effect.
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At the top of the atmosphere, in the global average and for a steady climate:• IR emitted balances incoming solar.
Global warming involves a slight imbalance: • a change in the greenhouse effect slightly less IR
emitted from the top (chap. 6). • small imbalance slow warming.
Three roles for clouds and convection:1. heating of the atmosphere (through a deep layer)2. reflection of solar radiation (contributing to albedo)3. trapping of infrared radiation (contributing to the
greenhouse effect)
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Pathways of energy transfer in a global average (cont.)
Differences in input of solar energy between latitudes temperature gradients.
These gradients would be huge if it were not for heat transport in ocean & atmosphere and heat storage in ocean.
2.4 Gradients of rad. forcing and energy transport by atm.2.4 Gradients of rad. forcing and energy transport by atm.
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Figure 2.9
Hadley cell: thermally driven, overturning circulation, rising in the tropics and sinking at slightly higher latitudes (the subtropics).
Explanations of this in chpt. 3 Relation to observations
• rising branch assoc. with convective heating and heavy rainfall; subtropical descent regions, little rain.
Latitude structure of the circulation (cont.)
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Intertropical convergence zones (ITZCs) or tropical convection zones: heavy precipitation features deep in the tropics, (convergence refers to the low level winds that converge into these regions). Monsoons: tropical
convection zones move northward in northern summer, southward in southern summer, especially over continents. Not just a function of
latitude, e.g., strong convection over tropical western Pacific, little over cold eastern Pacific: Walker circulation along equator Neelin, 2011. Neelin, 2011. Climate Change and Climate Modeling, Climate Change and Climate Modeling, Cambridge Cambridge
UPUP
Figure 2.13
Equatorial cold tongue: along the equator in the Pacific. • maintained by upwelling
of cold water from below.
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Figure 2.16
Equatorial Walker circulation
Figure 2.14
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Ocean vertical structure
Ocean surface is warmed from above lighter water over denser water (“stable stratification”).
Deep waters tend to remain cold• on long time scales,
import of cold waters from a few sinking regions near the poles maintains cold temperatures.
Figure 2.18
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The thermohaline circulation
Figure 2.19
Salinity (concentration of salt) affects ocean density in addition to temperature.
Waters dense enough to sink: cold and salty Thermohaline circulation: deep overturning circulation is
termed the (thermal for the temperature, haline from the greek word for salt, hals).
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The carbon cycle
Figure 2.21b
Va
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s fr
om
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an
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, IP
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fo
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ien
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r ,
Ph
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s T
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ay
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).
Fossil fuels 6.4 PgC/yr (1990s) (incl. 0.1 PgC/yr cement production)
~40% coal, 40% from oil and derivatives such as gasoline, 20% from natural gas
1.6 PgC/yr land-use change; e.g., deforestation to agricultural (smaller C storage)
1990s; anthropogenic emissions ~8 PgC/yr (6.4 fossil fuels + 1.6 land use change)
Fortunately, less than half remains in the atmosphere
2.2 PgC/yr increased flux into ocean + 2.5 PgC/yr taken up by land vegetationNeelin, 2011. Neelin, 2011. Climate Change and Climate Modeling, Climate Change and Climate Modeling, Cambridge Cambridge
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Fossil fuel emissions and increases in atmospheric CO2 concentrations
Figure 2.22
Val
ues
are
from
Den
man
et a
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(20
07);
form
at
follo
ws
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and
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, Phy
sics
Tod
ay (
2002
).
Fossil fuel emissions converted to CO2 concentration change if all remained in the atmosphere (1 ppm for each 2.1 PgC); rising …
Actual rate of accumulation (change in concentration each year; all positive = rising concentration, but variable rate of increase)
Variations primarily due to land biosphere, e.g., droughts assoc with ENSO
Accumulation rate ~ 55% of fossil fuel emissions on average
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Where do we get the equations in climate models (conservation of momentum, energy, mass,…+eq of state)
Main balances from these equations *especially as we apply them to explain important climate features*• PGF vs Coriolis• Thermal circulation, thermal expansion• Upwelling,…
Chapter 3 Physical Processes in the Climate System
Review elements include:Review elements include:
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3.1 3.1 Conservation of MomentumConservation of Momentum
velocity = Coriolis+PGF+gravity+Fdrag eqs. 3.4 & 3.5d dt
•Coriolis force: due to rotation of earth (apparent force).
•PGF: pressure gradient force. Tends to move air from high to low pressure.
•Fdrag: friction-like forces due to turbulent or surface drag.
Use force per unit mass for atm/oc.
Only in vertical
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• Turns a body or air/water parcel to the right in the northern hemisphere; to the left in the southern hemisphere.
• Exactly on the equator, the horizontal component of the Coriolis force is zero
• Acts only for bodies moving relative to the surface of the Earth’s equator and is proportional to velocity.
Coriolis force (cont.)
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Schematic of geostrophic wind and wind with frictional effects
Geostrophic balance:At large scales at mid-latitudes and approaching the tropics the Coriolis force and the pressure gradient force are the dominant forces (for horizontal motions)
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Figure 3.4
Section 3.1 Overview
•An approximate balance between the Coriolis force and the pressure gradient force holds for winds and currents in many applications (geostrophic balance) (Fig. 3.4).
•The Coriolis force tends to turn a flow to the right of its motion in the Northern Hemisphere (left in the Southern Hemisphere); the pressure gradient force acts from high toward low pressure.
•The Coriolis parameter f varies with latitude (zero at the equator, increasing to the north, negative to the south); this is called the beta-effect ( = rate of change of f with latitude).
•In the vertical direction, the pressure gradient force balances gravity (hydrostatic balance). This allows us to use pressure as a vertical coordinate. Pressure is proportional to the mass above in the atmospheric or oceanic column.Neelin, 2011. Neelin, 2011. Climate Change and Climate Modeling, Climate Change and Climate Modeling, Cambridge Cambridge
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Tropics (Hadley circ) subtropics West Pacific (Walker circ.) East Pacific
• relatively low pressure (at given height) at low levels in warm region; PGF toward warm region (near surface)
Application: thermal circulation
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Figure 3.5
e.g.:
Section 3.2 Overview
•Atmos: relationship of density to pressure and temperature from ideal gas law
•Ocean: density depends on temperature (warmer= less dense, e.g. sea level rise by warming) & salinity (saltier= more dense).
•Thermal circulations (Fig. 3.5): warm atmospheric column has low pressure near the surface and high pressure aloft relative to pressure at same height in a neighboring cold region. Reason: see Fig. 3.5
•PGF near surface toward warm region; Coriolis force may affect circulation but warm region tends to have convergence & rising. e.g.: Walker, Hadley circulations
•sea level rise by thermal expansion: density changes by given fraction (thermal expansion coefficient) so sea level rise proportional to depth of column that warms*T; e.g., deep vs upper oceanNeelin, 2011. Neelin, 2011. Climate Change and Climate Modeling, Climate Change and Climate Modeling, Cambridge Cambridge
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• Ocean: time rate of change of temperature of water parcel given by heating
• for a surface layer: net surface heat flux from the atm. minus the flux out the bottom by mixing
• Atmosphere: Temperature eqn. similar to ocean but…
• when an air parcel rises, temperature decreases as parcel expands towards lower pressure.
• Quickly rising air parcel (e.g. in thermals): little heat is exchanged
• temperature decreases at 10 C/km (the dry adiabatic lapse rate).
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Section 3.3 Overview
Section 3.3 Overview (cont.)
• Time derivatives following parcel hide complexity of the system : the parcels themselves tend to deform in complex ways if followed for a long time.
•Results in the loss of predictability for weather.
• The time derivative for temperature at a fixed point is obtained by expanding the time derivative for the parcel in terms of velocity times the gradients of temperature (advection).
• Similar procedure applies in other equations.
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• Drag of wind stress tends to accelerate currents northward
• Coriolis force turns current to left in S. Hem
[momentum eqn. ] • u away from coast horizontal divergence upwelling from below [thru bottom of surface layer ≈ 50m]
[Continuity eqn. ]
Coastal upwelling: e.g., Peru; northward wind component along a north-south coast
fu ≈ Fydrag
∂w∂zD = _
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Figure 3.9
Processes leading to equatorial upwelling
• Just north of Equator small Coriolis force turns current slightly to right (south of Equator to the left) divergence in surface layer balanced by upwelling from below
• Wind stress accelerates currents westward [wind speed fast relative to currents, so frictional drag at surface slows the wind but accelerates the currents]
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Figure 1.7
∂h∂t
+ HD = 0^
3.4e 3.4e Conservation of warm water mass in idealized layer above thermoclineConservation of warm water mass in idealized layer above thermocline
cold densecold dense
warm less densewarm less dense
• Warm light water above thermocline at depth h
• Horizontal divergence/convergence in upper layer movement of thermocline
[approx. H = mean thermocline depth, D vertical avg. thru layer ]^
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Figure 3.11
Section 3.5 Overview
• Conservation of mass gives equations for water vapor (atmosphere) and salinity (ocean); and other things, e.g. ice/snow
•water vapor main sinks moist convection &precipitation; source surface evaporation (transport in between)
•Salinity at the ocean surface is increased by evaporation and decreased by precipitation.
• latent heat of condensation: water vapor sink gives heating in clouds (connecting mass and energy equations)
•Latent heat of melting important to surface mass balance of ice (or snow), e.g., application to time needed to melt an ice sheet by surface heat flux imbalance [W/m2 vs kg/m2 *J/kg]
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Section 3.6 Overview
• Saturation of moist air depends on temperature according to Figure 3.12. Relative humidity gives the water vapor relative to the saturation value.
• A rising parcel in moist convection decreases in temperate according to the dry adiabatic lapse rate until it saturates, then has a smaller moist adiabatic lapse rate. The temperature curve in Figure 3.13 (the moist adiabat) depends on only the surface temperature and humidity where the parcel started.
• If this curve is warmer than the temperature at upper levels, convection typically occurs.
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• Waves play an important role in communicating effects from one part of the atmosphere to another.
• Rossby waves depend on the beta-effect [change of coriolis force with latitude]. Their inherent phase speed is westward. In a westerly mean flow, stationary Rossby waves can occur in which the eastward motion of the flow balances the westward propagation. Stationary perturbations, such as convective heating anomalies during El Nino, tend to excite wavetrains of stationary Rossby waves.
3.7 Wave Processes in the Atmosphere and Ocean: Overview3.7 Wave Processes in the Atmosphere and Ocean: Overview
[Skim for qualitative background for chpt 4.]
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Tropical Pacific climatology as it sets the stage for ENSO Schematics of ENSO (but with sense of how these connect
to observations seen earlier) Feedbacks that strengthen El Nino/La Nina (Bjerknes
hypothesis feedbacks) Linkage between sea surface height, thermocline depth,
and pressure gradients in the upper ocean
Chapter 4El Nino…
Review elements include:Review elements include:
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December 1997 Anomalies of sea surface temperatureduring the fully developed warm phase of ENSO
Figure 1.7
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Figure 4.2 (Chapter 4 preview)
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The Bjerknes feedbacks (warm phase)
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Figure 4.3
Commonly used index regions for ENSO SST anomalies
Figure 1.5
When SST in the Niño-3 region is warm during El Niño, the SOI tends to be negative, i.e., pressure is low in the eastern Pacific relative to the west.
Pressure gradient tends to produce anomalous winds blowing from west to east along the equator.
Reverse during periods of cold equatorial Pacific SST (La Niña).
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Nino-3 index of equatorial Pacific sea surface temperature anomalies and the Southern Oscillation Index of atmospheric pressure anomalies
Figure 1.6
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December 1997 Anomalies of sea level heightduring the fully developed warm phase of ENSO
Figure 1.10
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Idealized upper ocean layer
• Sea surface height thermocline depth [cm vs. m]• PGF from regions of deep thermocline (high sea surface=high pressure above thermocline) toward regions of shallower thermocline
4.4 Pressure gradients in an idealized upper layer4.4 Pressure gradients in an idealized upper layer
Figure 4.4
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Response of the ocean to a westerly wind anomalyFigure 4.13
• To east of the wind anomalies, equatorial jet (Kelvin wave) extends east, deepening thermocline (H)
• (recall: warms SST…)• To west, inflow of water to jet (in oc. upper layer) comes from off the equator (but little effect on SST)
• shallow thermocline in west extends westward (Rossby wave), as mass transferred to east by jet
• when reaches western boundary, can no longer supply mass by extending shallow region
• Weakening of jet extends eastward, ending warm phase
• As wind anomalies weaken, shallow thermocline extends eastward: transition to cold phase
Wind anoms currents
Deep Thermocline anoms
Re: Onset and demise of El Niño warm phase
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Two positions of the thermocline, indicatingregion of thermocline anomalies
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Figure 4.5
The transition into the 1997-98 El Niño warm phase (Apr. 1997)
Slowly evolving thermocline depth anomalies (= subsurface temperature anoms) affect eastern Pacific SST later. Key to predictability.
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Figure 4.8b
The transition into the 1997-98 El Niño warm phase (Sep. 1997)
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Figure 4.8c
The transition into the 1997-98 El Niño warm phase (Jan. 1998)
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Figure 4.8d
• weather unpredictable beyond ~two weeks• But interaction with the slowly evolving ocean (both in Bjerknes feedbacks and
delayed effects of Western Pacific thermocline anomalies)
permits prediction of ENSO Eastern Pacific SST anomalies (and associated atmospheric anomalies) up to ~9 months ahead
• Forecast skill tends to degrade with longer lead time for forecast• Loss of skill in ENSO forecasts:(i)Imperfections in the forecast system
-e.g., model errors, scarcity of input data (can be improved, if $)
(ii) Fundamental limits to predictability - “weather noise”: acts like a random forcing on slow ocean-atmosphere interaction
e.g., SST gradient determines average strength of Tradewinds. But in a particular month, transient weather events can cause equatorial Easterlies to differ from this
Basis for ENSO forecasts and Limits to skill Basis for ENSO forecasts and Limits to skill
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•Start coupled model from different ocean initial conditions (leading also to changes in atm. ) •Initial differences grow ensemble of prediction runs•Ensemble spread gives estimate of uncertainty• Spread tends to grow with time (due to weather noise & coupled feedbacks)• Ensemble mean gives best estimate
An ensemble of forecasts duringthe onset of the 1998-99 La Niña
Figure 4.18
Courtesy of the European Centre for Medium-range Weather Forecasting.
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