Transcript Document

space
atmosphere
Q
Q
ocean
Most of this course is about
the basic state of the Earth’s
climate system and its
governing forces. However
the climate state varies across
a wide range of time and
spatial scales.
Climate change is due to
many natural and
anthropogenic factors.
This lecture introduces you
to a few of these changes
from century down to
interannual time scales.
Climate Changes…why?
The topic of one of the more
dramatic changes at interannual
scales is covered later in the
ENSO lecture [week of 22
November]
Last 1000 years
Proxy data:anecdotal
tree ring, coral, ice core
?
Instrumental data
Warm period
hotter sun
more sunspots
Cold period
Little Ice Age
colder sun
less sunspots
Now [what
have we
done!]
Solar and greenhouse/aerosols
Greenhouse
gasses &
aerosols
solar
Solar radiation, Qs
w/m2
Qb =
Solar Constant So = 1375
Space
Qs (1- a)/4 = esTe4
Solar radiation, Qs
Te = -18°C
Qb = esTe4
esTe4
In a greenhouse
enhanced world, the
Te is forced to higher
elevation
Te
300 m
Te
Lapse rate, 7°C/km
Lapse rate, 7°C/km
x
x
x
x
x
x
x
x x
x
x x x
x x x xx x x
xDT=2.1°C
x
x
x
Earth Surface
greenhouse
xx
x
x
Natural greenhouse
enhanced
x Greenhouse molecule, H20, CO2
North Atlantic Oscillation, NAO
http://www.ldeo.columbia.edu/NAO
http://sciencebulletins.amnh.org/earth/f/nao.20040910/
The NAO is the dominant mode of winter climate
variability in the North Atlantic region ranging from
central North America to Europe and much into
Northern Asia. The NAO is a large scale seesaw in
atmospheric mass between the subtropical high and
the polar low. The corresponding index varies from
year to year, but also exhibits a tendency to remain
in one phase for intervals lasting several years.
Positive NAO Index
• The Positive NAO index phase shows a stronger than usual subtropical high pressure center and
a deeper than normal Icelandic low.
• The increased pressure difference results in more and stronger winter storms crossing the
Atlantic Ocean on a more northerly track.
• This results in warm and wet winters in Europe and in cold and dry winters in northern Canada
and Greenland
• The eastern US experiences mild and wet winter conditions
Negative NAO Index
The negative NAO index phase shows a weak subtropical
high and a weak Icelandic low.
The reduced pressure gradient results in fewer and weaker
winter storms crossing on a more west-east pathway.
They bring moist air into the Mediterranean and cold air to
northern Europe
The US east coast experiences more cold air outbreaks and
hence snowy weather conditions.
Greenland, however, will have milder winter temperatures
part of NADW phenome
Part of subtropical wind
driven circulation
Cape Hatteras, 80 Sv
Florida Straits, 30 Sv
Decadal ENSO, tied
to North Pacific?
Mostly El Niño
Mostly neutral
NAO relationship to PDO?
Northern Annular Mode [NAM] or
Arctic Oscillation
A Positive NAM Event: the winter pressure at the
pole is relatively low, cold air does not move as quickly
pole ward, allowing the stratospheric winds to “spin up”
vortex.
Once a strong vortex is established it acts as a barrier,
keeping cold air in the arctic, and allowing for warmer
winters in Scandinavia and North America
A Negative NAM Event: the pressure at
the pole is high, cold air spills southward
creating a very irregular jet stream shape,
making the US and Scandinavia very cold, and
promoting mid-latitude storms
In this case the polar vortex is weak
Recent History of the NAM
There has been a general trend
favoring a positive NAM state in
recent years.
NAO/NAM/PDO
connection?
THE ANTARCTIC OSCILLATION (or Southern Annular Mode)
is the primary mode of atmospheric variability poleward of 30°S, and may also
account for much of the variability in ocean circulation and sea ice in this region.
Thompson and Wallace (2000)
A schematic of the hypothesized relationships among
atmospheric, ocean, and ice components of the Southern
Hemisphere climate system associated with the positive
phase of the AAO. These relationships were seen in a
coupled ocean-atmosphere simulation (Hall and
Visbeck, 2002).
Climate Change happens!
over a wide range of temporal and spatial scales;
for lots of reasons, both natural and societal;
the network of positive and negative feedbacks between the
various elements of the climate system and imperfect
observation system makes detection, understanding and
modeling a real challenge.