SIO 210: Natural climate variability (decadal modes and longer time scales)
L. Talley 2014
DRAFT (2010 lecture with few edits)
• Climate equilibria, forcing, feedbacks, hysteresis• (ENSO - use notes from previous lecture)• Pacific Decadal Oscillation - ENSO modulation• North Atlantic Oscillation, Arctic Oscillation & Northern
Annular Mode• Southern Annular Mode• North Atlantic meridional overturning and climate
change• Impacts of anthropogenic forcing
• Reading: In DPO Chapter S15
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Elements of the climate system
Atmosphere
Ocean
Land surface
Biological and chemical cycles
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Climate variability vs. climate change
• Current common usage and in, e.g., the Intergovernmental Panel on Climate Change (IPCC) usage. (But not used by all climate scientists.)
• “Climate variability” = natural variability– Natural “modes” of variability
• “Climate change” = anthropogenic forcing– (due to man-made changes in greenhouse gases,
land surfaces, species distributions, etc.)
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Climate forcing
External forcing for earth’s climate includesearth orbit parameters (solar distance factors)solar luminositymoon orbitvolcanoes and other geothermal sourcestectonics (plate motion)greenhouse gases (to the extent that they are not part of the climate system itself)land surface (likewise with respect to the climate system)
Internal forcing: looking at each element of the climate system and how it is forced by another element(e.g. winds forcing ocean, change in ice extent forcing atmosphere or ocean, etc)
Interactions – sometimes include feedbacks
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Natural climate modes with interannual to millenial time scales that involve the ocean
ENSO: interannual time scale (> 1 year, < 10 years)
Pacific Decadal Oscillation: decadal time scale
North Atlantic Oscillation or Arctic Oscillation or Northern Annular Mode: decadal time scale
Southern Annular Mode: decadal time scale
Atlantic overturning mode: centennial time scale
(centennial and longer time scales - VERY sparse data sets, require more modeling to isolate processes)
What sets the time scales?
decadal to centennial suggests longer processes than just atmosphere - for instance ocean circulation or changes in land surface
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Stability and equilibria
Asymptotically stable: force system away from initial condition and the system returns to initial state
Stable or Neutral: force away and system stays where it was pushed to (not illustrated here).
Unstable: force away and system moves to a different state. This usually implies multiple possible stable equilibria, with forcing that is strong enough to push into a different equilibrium state.
Kump, Kasting and Crane (2003)6Talley SIO210 (2014)
Forcing (coupling) with no feedback
• Cause and effect: example of negative coupling (increase in one parameter causes a decrease in the other)
• Volcano causes aerosols • Causes cooling and decrease in temperature
Feedback? None since air temperature does not change incidence of volcanoes
Volcano eruption
Temperature decrease
Negative coupling
Reduction in sunlight
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Positive feedbacks
• Example: ice-albedo feedback– Increased ice and snow cover increases albedo
• (Positive coupling, denoted by arrow)– Increased albedo decreases temperature of atmos.
• (negative coupling, denoted by circle)– Decreased temperature of atmos. Causes ice increase
• (negative coupling, denoted by circle)– Two negatives cancel to make positive; net is positive
feedback (“runaway”, unstable)
Ice increase
Reflection increasePositive coupling
Temperature decrease
Negative couplingNegative coupling
Albedo = reflectivity, scale of 0-1 with 0 = no reflection, 1 = all reflected
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How might the ocean feed back on climate modes and create decadal to centennial to millenial time scales?
Note that advection time scales are similar to these climate modes:
ocean gyres - decades
ocean basins - centuries
global ocean - ~1000 years
(1) Advection of heat and salinity anomalies: from surface forcing regions, subducted, and then returning to surface where they change the forcing for the atmosphere, or change the ice extent.
(2) Or similar advection that changes the upper ocean stratification, hence changing the mixed layer depths heated and cooled by the same air-sea fluxes, thus changing surface temperature
(3) Or propagation of anomalies via Rossby or Kelvin waves, which then reset the temperature in remote locations.
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Stability and equilibria for the ocean: can the N. Atlantic “conveyor” turn on and off and what
would be the result for climate?
Cooling, freshening
Warming, evaporation
Rahmstorf, Nature, 200210Talley SIO210 (2014)
North Atlantic thermohaline circulation variations - millenial time scales and abrupt climate change
(1) If, say, fresh water is dumped on the northern North Atlantic through excessive melting or runoff, how will the N. Atlantic overturning circulation change? Will it:
Absorb the freshwater and return to nearly the initial condition (asymptotically stable)? (stay in the initial equilibrium state)
Shift to a slightly different state and remain there? (neutrally stable) (stay in essentially the same equilibrium state)
Jump into a completely different state of overturn (unstable)? (new equilibrium state)
(2) If the freshwater forcing is continuously changing (increasing and decreasing), what is the response? (“hysteresis” predicted)
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Salt oscillator (Stommel 1961): example of hysteresis
Cooling, freshening
Warming, evaporation
Model:
(1) increase freshwater at high latitudes.
Starts to reduce overturn and reduce high latitude SST slightly.
Then overturn shuts off, SST drops abruptly.
(2) Reduce freshwater at high latitudes. Takes a long time to restore overturn - overshoot (hysteresis)
DPO section 7.10.4N
AD
W f
orm
atio
n ra
te
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North Atlantic thermohaline circulation variations - millenial time scales and abrupt climate change
Rahmstorf, Nature, 200213Talley SIO210 (2014)
Can the N. Atlantic “conveyor” change?
Cartoon of “conveyor” and measurement arrays in place from Quadfasel (Nature, 2005)
Interest in change since it would have some consequences for subpolar SST and for the storm tracks that might respond to location and strength of ocean fronts
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North Atlantic salinity variationsCan these changes in surface salinity create changes in circulation?
Curry (WHOI)15Talley SIO210 (2014)
Observed changes: Freshening of the Atlantic and Nordic Seas
(Dickson et al, Phil Trans Roy Soc 2003)
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Labrador Sea Water variations (Dickson et al.,
and I. Yashayaev)
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Changes in Atlantic water mass salinity (Curry et al, 2003)
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Is the N. Atlantic “conveyor” changing, possibly in response?
Bryden et al. (Nature, 2005) measurements at 25°N suggested a slowdown. They have since withdrawn this conclusion – their results were probably aliased by the large seasonal cycle.
Cartoon of “conveyor” and measurement arrays in place from Quadfasel (Nature, 2005) 19Talley SIO210 (2014)
Natural climate modes with decadal time scales that involve the ocean
ENSO: interannual time scale (earlier lecture)
Pacific Decadal Oscillation: decadal time scale
North Atlantic Oscillation or Arctic Oscillation or Northern Annular Mode: decadal time scale
Southern Annular Mode: decadal time scale
Atlantic overturning mode: centennial time scale
(centennial and longer time scales - sparse data sets, require more modeling to isolate processes)
What sets the time scales?
decadal to centennial suggests longer processes than just atmosphere - for instance ocean circulation or changes in land surface
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The PDO versus ENSO
20-30 year time scale 3-7 year time scale
Similar patterns, but ENSO is very peaked in the tropics, and the PDO is spread out to higher latitudes, particularly N. Pacific.
ENSO pattern (sort of an EOF): mostly tropical
Pacific Decadal Oscillation pattern (sort of EOF): tropics and Aleutian Low
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Pacific Decadal Oscillation time series (Mantua and Hare)
Great website: http://tao.atmos.washington.edu/pdo/
1976 “regime shift” to warm phase PDO, strong Aleutian Low
The PDO was high after about 1976 (“regime shift”) and stayed pretty high until the late 1990s. It looked like it was entering a low phase, but we are back in high.
Lesson for decadal modes: don’t know what you have until you are many years into them.
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Aleutian Low, ocean circulation and decadal change?
Stronger A.L. strengthens subpolar gyre and weakens subtropical gyre - result is ocean warming along North
America
Subpolar gyre
Subtropical gyre
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SST changes due to changing winds and circulation
Adapted from Miller, Chai, Chiba, Moisan and Neilson (J. Oceanogr., 2004)
COOLING
WARM
ING
When the Aleutian Low is strong, get:
westerlies
Stronger
Ocean currents
weaker
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The Arctic Oscillation (or North Atlantic Oscillation or Northern Annular Mode)
“High” and “Low” refer to the anomaly of atmospheric pressure difference between the Azores and Iceland
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NAO SST pattern
High NAO:
Warm subtropical N. Atlantic, warm subtropical N. Pacific
Cool subpolar N. Atlantic, cool subpolar N. Pacific
i.e. also associated with weak Aleutian Low26Talley SIO210 (2014)
Arctic Oscillation sea level pressure pattern
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Where are we in the NAO?
High or neutral
http://www.cgd.ucar.edu/cas/jhurrell/indices.html28Talley SIO210 (2014)
N. Atlantic changes: decrease in oxygen at base of the surface layer -> reduction in upper ocean ventilation
(concomitant increase in Labrador Sea ventilation)
(Gruber, 2004; Johnson, 2004;Feely et al 2005)
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N. Atlantic oxygen changes: ascribed to high NAO since about 1989, reduced ventilation in the NE Atlantic
(Gruber, 2004)
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Arctic Oscillation
surface temperature
variations (land) (Wallace)
High AO:
Cold high latitudes (Canada, Labrador Sea)
Warm Siberia and continental US, warm subtropics
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Southern Annular Mode
NAM
Circumpolar mode; variation in surface pressure and hence in westerly and polar easterly wind strength
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Anthropogenic climate change
The ocean is an excellent integrator of change since its heat capacity is large, and it is an enormous reservoir for freshwater (compared with the atmosphere).
Long-term trends in heat content, salinity and oxygen are observed.
Necessary to integrate over large areas to see this signal separate from the decadal natural modes.
Patterns of A.C.C. might well resemble the natural climate modes since these are, after all, the natural modes that would be forced into a particular state.
Relation to anthropogenic climate change is made through relation to atmosphere trends that are footprints of A.C.C. (night vs. day temperature, troposphere vs. stratosphere heating/cooling, low vs. high latitude warming)
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Observed global ocean changes that might be anthropogenic (Levitus et al 2005)
0.037°C warming (0-3000 m)
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Is there anthropogenic climate change?
• Yes (IPCC TAR)
Levitus et al (2000) heat storage changes in the North Pacific, Pacific, World
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Observed changes: basin-scale temperatureMostly warming but some cooling (presented by H.
Garcia). Especially note cooling in high latitude Atlantic and Pacific, tropical Pacific and Indian. Not just noise.
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Observed changes: Southern Ocean(Gille, Science 2002)
Broad warming in southern ocean at about 800 meters
Also note cooling to the north of the warm band
Accompanied by cooling in central Antarctica
This looks like the Southern Annular Mode pattern. Natural climate modes might also be forced by anthropogenic change.
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Variations in central N. Pacific temperature, salinity and density between 1985 and 2004
(Robbins, pers. comm. 2004)Using CFCs measured concurrently, he is concluding that this is
at least partially anthropogenic
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Large-scale salinity changes: fresh areas freshening and salty areas getting saltier. Suggests increase in atmospheric
hydrological cycle, which would be expected in a warmer world. This can only be observed with ocean salinities rather than with trends in evaporation-precipitation since the latter data sets are
very noisy.
Fresher, cooler
Saltier
Fresher
Saltier
Fresher
Fresher
Saltier
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Extra slides
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Daisyworld - simple model of feedbacks (Lovelock)• Model designed to demonstrate
simple feedbacks that can affect climate
• Albedo: fraction of light that is reflected.Totally reflected: albedo = 1No reflection: albedo = 0
Albedo depends on the material– Snow – Ice– Dirt– Grass– Clouds– Concrete– Water
• http://gingerbooth.com/courseware/daisy.html
Reasonable initial T
High initial T
Negative feedback
Positive feedback
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Pacific Decadal Oscillation SST and SLP patterns: note similarity of SST to ENSO pattern and also large
amplitude in the central N. Pacific
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Pattern for the PNA (like the NPI): this is an intriguing pattern, suggesting a connection to the
Southern Ocean (Southern Annular Mode)
Pacific North American pattern correlated with sea level pressure
North Atlantic Oscillation pattern correlated with sea level pressure
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Decadal variations in ENSO associated with ocean subtropical changes (McPhaden and
Zhang)
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Tropical Pacific and Southern ocean connection (Yuan, 2004)
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What about changing N. Atlantic meridional overturning?
• Freshening of subpolar N. Atlantic is intriguing• Stommel model and many more sophisticated
models exploring effect of freshwater dump on subpolar N. Atlantic
• Freshening would weaken the overturning circulation
• Bryden et al. (2005) and other somewhat recent papers reporting possible decrease in overturning circulation at 24N and at the Nordic Seas overflows
• But present consensus is probably that ascribing variations to anthropogenic forcing is difficult since natural variations (NAO or NAM) are so large
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Is the N. Atlantic conveyor changing? This week in Nature (vol. 438, 1 December 2005)
Bryden et al (2005)
Repeat hydrographic sections at 24N in the N. Atlantic
Transport per unit depth Upper ocean Deep ocean47Talley SIO210 (2014)
Is the N. Atlantic conveyor changing? This week in Nature (vol. 438, 1 December 2005)
Bryden et al (2005)
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Variations in central Pacific continued
Warming from surface to about 1000 m (27.2 sigma0)
Salinification to about 800 m (27.0 sigma0)
1000
T S density
T S
27.0
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Arctic Oscillation
precipitation anomalies (Wallace)
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Anthropogenic warming signature
Wang and Schimel -->
IPCC TAR, from Jones et al (2001)
The observed high latitude warming trend is a signature of anthropogenic change
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All the pacific indices ncep_ncar
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All the pacific indices ncep_ncar
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