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MYTH #15: Carbon dioxide emissions do not correlate with carbon dioxide concentration

DENIERS SAY:

Human emissions of CO2 don’t vary much from year to year, but the concentration of CO2 in the atmosphere varies a lot. It clearly doesn’t come from us.

SCIENCE SAYS:

We're putting more carbon into the atmosphere than nature can handle. That causes global warming.

The concentration of carbon dioxide in the atmosphere correlates closely — but not perfectly — with the amount of carbon pollution emitted by human activities. That’s because plants, soils and the ocean take some of the carbon back out of the atmosphere. This is a good thing, because otherwise the planet would be heating up even faster than it is now. Unfortunately, we’re putting more carbon pollution into the atmosphere than natural systems can absorb, and that's why the planet is warming.

Additional info from NASA 


Left unperturbed, the fast and slow carbon cycles maintain a relatively steady concentration of carbon in the atmosphere, land, plants and ocean. But when anything changes the amount of carbon in one reservoir, the effect ripples through the others. 

In Earth’s past, the carbon cycle changed in response to climate change (Figure 1). Variations in Earth’s orbit alter the amount of energy Earth receives from the sun and lead to a cycle of ice ages, which alternate with warm periods like Earth’s current climate. Ice ages developed when Northern Hemisphere summers cooled and ice built up on land, which in turn slowed the carbon cycle. Meanwhile, a number of factors including cooler temperatures and increased phytoplankton growth may have increased the amount of carbon the ocean took out of the atmosphere. The drop in atmospheric carbon caused additional cooling. Similarly, at the end of the last Ice Age, 10,000 years ago, carbon dioxide in the atmosphere rose dramatically as temperatures warmed.

Figure 1. Levels of carbon dioxide in the atmosphere have corresponded closely with temperature over the past 800,000 years. Although the temperature changes were touched off by variations in the Earth’s orbit, the increased global temperatures released CO2 into the atmosphere, which in turn warmed the Earth in turn. Graphs by Robert Simmon, using data from Lüthi et al. 2008 and Jouzel et al. 2007. Source: NASA. 

Shifts in Earth’s orbit are happening constantly, in predictable cycles. In about 30,000 years, Earth’s orbit will have changed enough to reduce sunlight in the Northern Hemisphere to the levels that led to the last ice age. 

Today, changes in the carbon cycle are happening because of people. We perturb the carbon cycle by burning fossil fuels and clearing land (Figure 2).

Figure 2: Emissions of carbon dioxide by humanity (primarily from the burning of fossil fuels) have been growing steadily since the onset of the Industrial Revolution. About half of these emissions are removed by the fast carbon cycle each year; the rest remain in the atmosphere. Graph by Robert Simmon, using data from the Carbon Dioxide Information Analysis Center and Global Carbon Project. Source: NASA. 

When we clear forests, we remove a dense growth of plants that had stored carbon in wood, stems, and leaves — called “biomass.” By removing a forest, we eliminate plants that would otherwise take carbon out of the atmosphere as they grow. We tend to replace the dense growth with crops or pasture, which store less carbon. We also expose soil that vents carbon from decayed plant matter into the atmosphere. Humans are currently emitting just under a billion tons of carbon into the atmosphere per year through land use changes. 

Since the beginning of the Industrial Revolution, when people first started burning fossil fuels, carbon dioxide concentrations in the atmosphere have risen from about 280 parts per million to 392 parts per million, a 40 percent increase. This means that for every million molecules in the atmosphere, 392 of them are now carbon dioxide — the highest concentration in two million years. Methane concentrations have risen from 715 parts per billion in 1750 to more than 1,808 parts per billion in 2010, the highest concentration in at least 650,000 years.