3.4: Future Geographies - Predicting Atmospheric Composition

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It is undeniable that the climate of Earth has seen numerous changes over geological time but that our current climate is undergoing changes in unprecedented ways for modern times. Measurements of atmospheric temperature show a clear upward trend, and records are broken, while many regions are gripped in years-long drought. This current warming trend is undeniably related to human activities.

To understand how climate has changed in the past, and more importantly, what will happen in the future, geoscientists must rely on models. Models are merely representations of the real world and are created from our mathematical understanding of earth processes. Scientist must make assumptions to fill in gaps where understanding or data is lacking. As a result, the output of a model inherently has a degree of uncertainty associated with it.

Predicting the changes in gaseous composition of the atmosphere is a difficult exercise. How the gaseous composition of the atmosphere will change in the future depends a great deal on the impact of human activities and our ability and willingness to control emissions. In addition to the crucial changes brought about by humans, increasing temperatures as a result of an enhanced greenhouse effect will themselves slightly impact the concentration of various gases in earth's atmosphere.

Prediction versus Projection

Uncertainty over how populations will grow, economies develop, and about technological advancement makes it difficult at best to predict the future composition of the atmosphere. Bodies like the global Intergovernmental Panel on Climate Change (IPCC) make projections based on models. Though quite sophisticated, models of earth systems are constrained by our imperfect knowledge of some environmental processes. The unpredictability of human advancement and the state of our understanding of climate dynamics creates uncertainty in these projections.

Concentrations of greenhouse gases are mostly globally homogeneous due to the fluid nature of the atmosphere. The exception may be water vapor, due to the unequal distribution of available water to evaporate into the air. However, the human contributions to the gaseous composition of the atmosphere are certainly geographically variable. A large majority of human-caused increase in greenhouse gases has come from industrialized nations, initially without knowledge of the negative impact. The race toward economic development will shift the largest contributors to the developing world unless all nations together work to reduce emissions.

Global_annual_CO2_emissions_by_world_region_since_1750.png — Figure \(\PageIndex{1}\): Carbon dioxide emissions by world region (Source: Wikimedia Commons)

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