Title: Annual-mean TOA radiation (ERBE, W/m2)
1 2Annual-mean TOA radiation (ERBE, W/m2)
Absorbed SW
Outgoing LW
3Surface temp (NCEP, oC)
January
July
4Surface wind (NCEP, m/s)
January
July
5(No Transcript)
6(No Transcript)
7Temperature (oC) and zonal wind (m/s) (NCEP)
January
July
8Temperature and potential temperature surfaces
J
T
decreases by 6oC/km
increases by 4oC/km
9Potential temperature (K) and zonal wind (m/s)
(NCEP)
January
July
10The bare rock temperature
In steady state, Ein Eout Ein p R2 S
(1?) Eout 4p R2 ? T4 R radius ?albedo
Putting it all together
11Radiative-convective equilibrium(Manabe
Strickler, 1964)
12CloudSW interaction
13CloudLW interaction
14Net cloud forcing from simple model(Hartmann, p.
74)
15Annual-mean cloud water path (g m2)
16Annual-mean total cloud amount ()
17Annual mean low cloud amount
18Annual mean middle cloud amount
19Annual mean high cloud amount
20Annual mean SW cloud forcing (ERBE, W m2)
21Annual mean LW cloud forcing (ERBE, W m2)
22Annual mean net cloud forcing (ERBE, W m2)
23Climate feedback the general ideaWhat happens
if we perturb the climate away from its
equilibrium,for instance by increasing CO2
concentration?
24- In the real world, both positive and negative
feedbacks act simultaneously - Overall, the negative feedbacks win otherwise
temperature would run away to very high values
(runaway greenhouse) - However, the presence of positive feedbacks means
that the temperature increase we get for a given
increase in CO2 is greater than we would get in
their absence more bang for the buck - Dominant feedbacks
- Negative
- Planck (radiative) feedback
- Lapse rate feedback
- Positive
- Surface albedo feedback
- Water vapour feedback
- Cloud feedback?
25Ice albedo feedback
- As surface temperature increases, some of the ice
in the polar ice caps melts, exposing ocean or
boreal forest - Ice is much more reflective to sunlight than
ocean or forest - So the feedback goes like this
- Increased CO2
- raises T
- melts some ice
- decreases reflectivity
- more insolation is absorbed
- raises T even further
26Water vapour feedback
- Relative humidity stays roughly constant as
climate warms - Since RH w/ws(T) and ws(T) increases
exponentially with T, then humidity increases
rapidly with T - So the feedback goes like this
- Increased CO2
- raises emission level
- raises T
- raises humidity
- raises emission level even further
- raises T even further
27Feedback strengths in climate models (SodenHeld,
2006)
28(No Transcript)
29(No Transcript)
30(No Transcript)
31(No Transcript)
32(No Transcript)
33Absorbed insolation
Insolation at TOA
34Absorbed insolation
Insolation at TOA
35(No Transcript)
36(No Transcript)
37SHF into ground!
38The moist equations of motion
evaporation
condensation
39Energetics
Total energy per unit mass
- Rate of change of
- kinetic energy
- potential energy
- thermal internal energy
- latent internal energy
40Energetics
Rate of change of total energy per unit volume
but
Finally
Note that
moist static energy
small
41(No Transcript)
42(No Transcript)
43(No Transcript)
44Seasonal cycle of surface temperature
Amplitude of seasonal cycle (oC)
Temp (oC)