1. How the Greenhouse Effect Works/Feedback factors
Chapter 3—Part 4
How the Greenhouse
Effect Works/Feedback factors

2. incoming
radiation
Solar energy reaches the Earth’s surface

3. incoming
radiation
infrared radiation
Earth’s surface warms, emits radiation

4. incoming
radiation
greenhouse
gases
infrared radiation
Greenhouse gases absorb IR leaving the surface

5. incoming
radiation
greenhouse
gases
infrared radiation
Gases are energized, then emit radiation (IR)

6. incoming
radiation
greenhouse
gases
infrared radiation
Some of this IR reaches the planet surface, warming it further

7. incoming
radiation
greenhouse
gases
infrared radiation
This process is what we call the GREENHOUSE EFFECT!

8. Earth’s Energy Balance
and now the details…

9. Follow the fate of a 100 units of solar radiation
Incoming solar radiation
atmosphere
Earth
Follow the fate of a 100 units of solar radiation

10. 30 units are reflected, and 70 units enter the atmosphere
100
incoming
30 reflected 70
30 units are reflected, and 70 units enter the atmosphere

11. This is matched by 70 units radiated from the Earth
100
incoming
70 radiated
from Earth
30 reflected 70
This is matched by 70 units radiated from the Earth

12. 25 are absorbed directly by the atmosphere,
100
incoming
70 radiated
from Earth
30 reflected 70
25 directly
to atmosphere
45 absorbed by Earth
25 are absorbed directly by the atmosphere,
and 45 units reach the Earth’s surface

13. 100 70 radiated 30 reflected 70 133 from 25 directly
incoming
70 radiated
from Earth
30 reflected 70
133 from
surface
25 directly
to atmosphere
45 absorbed by Earth
A large amount of energy is radiated by the Earth to the atmosphere

14. 100 70 radiated 30 reflected 70 133 from 25 directly 88
incoming
70 radiated
from Earth
30 reflected 70
133 from
surface
25 directly
to atmosphere 88
greenhouse
radiation
45 absorbed by Earth
The greenhouse effect captures radiation leaving the surface, warming the lower atmosphere and Earth’s surface

15. 100 70 radiated 30 reflected 70 133 from 25 directly 88
incoming
70 radiated
from Earth
30 reflected 70
133 from
surface
25 directly
to atmosphere 88
greenhouse
radiation
45 absorbed by Earth
A net of 45 units leave the earth, plus 25 units from the atmosphere yields 70 emitted to space

16. Climate feedbacks
The greenhouse effect itself can be calculated quite accurately
Example: Doubled CO2
The direct temperature effect of doubled CO2 (with no feedbacks) is to increase surface temperature by ~1.2oC
In the language of Daisyworld (and Earth 2)
T0 = 1.2oC

17. Climate feedbacks For doubled CO2: T0 = 1.2oC
But the predicted equilibrium response from climate models is
2oC < Teq < 5oC
Hence, in the models at least, there are positive feedbacks that tend to amplify the forcing by CO2. What are these?

18. Climate feedbacks Water vapor feedback Ice/snow albedo feedback
Cloud feedback

19. Water vapor feedback (+)  Positive feedback loop Surface temperature
Atmospheric
H2O
(+)
Greenhouse
effect
 Positive feedback loop

20. Snow/ice albedo feedback
Surface
temperature
Snow and ice
cover
(+)
Planetary
albedo
 Another positive feedback loop

21. What about clouds? Some reflection Cirrus clouds (Thin)
10 km
Cirrus clouds
(Thin)
More reflection
Altitude
Cumulus/stratus clouds
(Thicker)

22. What about clouds? Cirrus clouds High and cold Altitude
10 km
Cirrus clouds
High and cold
Tc4
Altitude
Cumulus/stratus clouds
Tw4
Low and warm
Tw4
Ts4 Tc
Temperature Tw Ts

23. What about clouds? Cumulus and stratus clouds Cirrus clouds
Low and warm
Small greenhouse effect
Big effect on albedo
These clouds cool the climate
Cirrus clouds
High and cold
Large greenhouse effect
Smaller effect on albedo
 These clouds warm the climate

24. Cloud feedback
Most models predict that cloudiness should increase as the climate warms
If low clouds increase the most, then the feedback will be negative
If high clouds increase the most, then the feedback will be positive
The balance of evidence suggests that cloud feedback is negative. However, this is highly uncertain, as clouds are sub-grid-scale in size and are therefore difficult to model.