labs_title

Caldeira Lab Research:Land Plants, Carbon, and Climate

Climate effects of global land cover change

S. Gibbard, K. Caldeira, G. Bala, T.J. Philips & M. Wickett

When land cover is changed from open areas such as grass and croplands to a more dense and covered area of forest, it creates an albedo effect and an evapotranspiration effect, which respectively create opposite warming and cooling effects on the climate. Using a model of global replacement of vegetation by forest and a model of global replacement by grassland, the strength of each effect is investigated. The results are not definitive but they suggest that more research should be done before afforestation is implemented as a way to combat global warming.


Gibbard, S., K. Caldeira, G. Bala, T.J. Philips and M. Wickett, Climate effects of global land cover change. Geophysical Research Letters 32 (23) L23705, 2005.

Different types of vegetation and their effects on altitude: the increase in temperature following the replacement of bare ground with trees (green), current vegetation (blue), and grass (red) are shown above. Temperature with only trees falls fairly far above that of current vegetation, while grassland falls below. This implies that vegetation that is mainly trees creates an overall warming effect on the climate.

Global afforestation's effect on temperature: The model's simulation predicted that if current vegetation was globally changed to forests, the Earth would experience a strong warming effect.

Abstract

When changing from grass and croplands to forest, there are two competing effects of land cover change on climate: an albedo effect which leads to warming and an evapotranspiration effect which tends to produce cooling. It is not clear which effect would dominate. We have performed simulations of global land cover change using the NCAR CAM3 atmospheric general circulation model coupled to a slab ocean model. We find that global replacement of current vegetation by trees would lead to a global mean warming of 1.3ºC, nearly 60% of the warming produced under a doubled CO2 concentration, while replacement by grasslands would result in a cooling of 0.4ºC. It has been previously shown that boreal forestation can lead to warming; our simulations indicate that midlatitude forestation also could lead to warming. These results suggest that more research is necessary before forest carbon storage should be deployed as a mitigation strategy for global warming.