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DISCUSSION
For the Late Miocene, we defined some CO2 climate
modelling sensitivity scenarios 1) to test how much CO2 is
necessary to produce ice-free conditions on the Northern Hemisphere in the
Miocene, 2) to analyse the Miocene climate sensitivity with respect to
variations of CO2, and 3) to validate the consistency of the model
results with proxy data in order to estimate how high CO2 might
have been in the Late Miocene.
The first question can be answered now "easily". Based on our
model results, a pCO2 of at least 1500 ppm is necessary to
produce an ice-free Arctic Ocean. Even the most "optimistic" estimations for
the Miocene carbon dioxide concentration, however, give values of about 1000
ppm or less (e.g., Cerling 1991;
Retallack 2001). Thus, our
model results suggest that an ice-free Arctic Ocean in the Miocene is unlikely
in the absence of other processes, which might have caused additional warming.
Recently found evidences from the Miocene fossil record also suggest some
significant cooling events and support sea ice cover on the Northern
Hemisphere (e.g., Moran et al. 2006;
Kamikuri et al. 2007;
Jakobsson et al. 2007).
What is the Late Miocene climate sensitivity with respect
to different concentrations of CO2? For the present-day
simulations TORT-700 vs. TORT-360, the global temperature increase is +2.5°C.
McGuffie et al. (1999)
demonstrated that a doubling of CO2 under present-day conditions
leads to a warming of +2.5°C to +4.5°C. The most recent future climate change
projections of the IPCC (Meehl et
al. 2007), which consider a doubling of CO2, give a similar
temperature increase between +2°C to +4.5°C. Our present-day sensitivity
experiments are at the lower end but within the range of these climate change
scenarios. Our Late Miocene simulations demonstrate a global temperature
increase of +1.9°C (TORT-560 vs. TORT-280, TORT-700 vs. TORT-360) due to a
doubling of CO2. The Late Miocene climate sensitivity on changed
pCO2 is weaker than today.
Steppuhn et al. (2007) observed that a doubling of CO2 under
Miocene boundary conditions leads to a global warming of +3°C. This is well
within future climate change predictions, but stronger than in our
simulations. The sea ice cover in
Steppuhn et al.'s (2007) Tortonian reference run is close to the modern
situation. In our simulations, even TORT-200 has a lower ice volume than
CTRL-360 (cf. Figure 4). Thus, the
lower sea ice-albedo feedback dampens the Late Miocene climate sensitivity on
a CO2 increase, although the Late Miocene is still comparable to
the modern situation. The amount of sea ice is lower in our Miocene
simulations than in previous Tortonian experiments (Micheels
et al. 2007;
Steppuhn et al. 2006,
2007) because we specified the modern ocean flux correction (cf.
Figure 3), whereas the previous
studies considered a weaker-than-present ocean heat transport. The reduced sea
ice cover in our Tortonian runs as compared to the present-day simulations is
explained by the warming effect of Greenland (no glaciers and lower elevation,
cf. Figure 1) and the larger forest
cover (cf. Figure 2) in the
palaeoclimate experiments. These results are consistent to the previous
studies.
Future climate change projections also demonstrated that
continents are much more affected by the global warming (e.g.,
Meehl et al. 2007). This is
consistent to our simulations. However, the climate change predictions
represent a pronounced warming of higher latitudes (e.g., Meehl et al. 2007).
This is in agreement to TORT-700 vs. TORT-360. In contrast, the Late Miocene
simulations do not show as much pronounced high-latitude warming (cf.
Figure 4). The reduced ice-albedo
feedback in the Tortonian runs as compared to the present-day situation
reduces the response to a CO2 increase in higher latitudes. In the
lower latitudes, future climate change projections and our Miocene runs are
quite comparable. In contrast to
Steppuhn et al. (2007), in our simulations the different settings of
boundary conditions (Miocene vs. modern) make a difference in the climate
response to enhanced CO2-scenarios. In general, our Miocene
experiments demonstrate a weaker sensitivity on higher CO2 than
future climate change scenarios because sea ice is already reduced in the
Miocene reference run.
How consistent are the different Late Miocene CO2-scenarios
as compared to the fossil record and can we estimate how high CO2
was in the Late Miocene? Considering the fossil record, our model fits
quite well with proxy data for a pCO2 of 360 to 560 ppm (cf.
Figure 8). TORT-200 to TORT-460
represent a global temperature difference of less than ±1°C as compared to
proxy data.
Micheels et al. (2007) find a global discrepancy to proxy data of –2.4°C
from a Tortonian simulation with the AGCM ECHAM4/ML using almost the same
boundary conditions and proxy data base. If this difference is acceptable,
then even TORT-700 could still be a realistic scenario for the Late Miocene (Table
2).
There are, however, some crucial points, which limit our
interpretations. Most Late Miocene proxy data cover the European realm,
whereas most other (key) regions such as the high latitudes, Africa and Asia
are poorly covered. Our sensitivity runs demonstrate that lower to
mid-latitudes are warmer than suggested by proxy data, but this statement is
based on only a few localities. With regard to the quality of proxy data,
there are some shortcomings that may influence detailed data intercomparison.
This includes the time span covered by the proxy data that may hide temporal
climatic variability, palaeogeographical changes that may change the exact
position of data points with respect to the grid cell compared with (e.g. in
the Pannonian realm, cf. Erdei et
al. 2007) and possible taphonomic biases that may influence the results of
different reconstruction methods (e.g.,
Liang et al. 2003;
Uhl et al. 2003,
2006). Despite some possible shortcomings, quantitative climate proxy data
based on plant fossils are consistent on a larger scale (Bruch
et al. 2004,
2006,
2007), and they provide reliable information to validate global climate
model results (Micheels
et al. 2007;
Steppuhn et al. 2007).
For our purposes, we consider that proxy data are more
reliable than the model results. The model experiments can be unrealistic
because of weak points in the model and its boundary conditions. The EMIC
Planet Simulator with its simplified parameterisation schemes and the boundary
conditions explain rather more inconsistencies in our experiments. For some
localities (e.g., in Africa, North America), the orography in the model might
be unrealistic because of the coarse model resolution, the spectral
transformation method or simply because the reconstruction of the orography is
not fully correct.
The coarse model resolution also does not allow for a
representation of details of the land-sea distribution. For example, the model
cannot resolve Iceland (cf. Figure 8).
This can explain why TORT-200 to TORT-630 represent (more or less) conditions
in the North Atlantic region that are too cool. In addition, the settings for
the ocean include some uncertainties. As mentioned in the model description,
the sea ice model tends to overestimate the amount of ice and the performance
of the ice model for seasonal ice is better than for multiyear ice. However,
with increasing CO2 concentrations in our runs, the amount of
multiyear ice successively reduces, and the model performance should increase.
The absence of ocean and sea-ice dynamics is a potential
source of errors in our study, but it is computationally expensive to run
fully-coupled atmosphere-ocean general circulation models in particular for a
series of sensitivity experiments. For this reason, AGCM experiments for the
Miocene used either prescribed sea surface temperatures and sea ice (e.g.,
Ramstein et al. 1997;
Lunt et al. 2008) or slab ocean
models (e.g., Dutton and Barron
1997;
Micheels et al. 2007). For past climates, ocean dynamics plays an
important role (e.g., Bice et al.
2000). Due to an open Panama Isthmus, the northward heat transport in the
Atlantic Ocean was weaker than today in the Miocene (e.g.,
Bice et al. 2000;
Steppuhn et al. 2006). Because of using the present-day flux correction,
the climate in Europe should be too warm in our sensitivity experiments.
If we consider that temperatures in Europe might need to be
corrected to slightly cooler conditions, the scenarios TORT-460 to TORT-630
would be more realistic. Taking all weak points into account, the scenarios
TORT-360 and TORT460 fit best with the fossil record. Hence with some
limitations, the simulations support a slightly higher-than-present
('intermediate') pCO2 of higher than 360 ppm and less than
460 ppm in the Late Miocene. Consistent to this result,
MacFadden (2005) proposed a
pCO2 of 500 ppm in the Miocene and for Middle Pliocene model
simulations an atmospheric carbon dioxide of 400 ppm is a reasonable value
(e.g.,
Haywood and Valdes 2004,
2006).
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