An extensive and previously unknown “twilight zone” of particles in the atmosphere could complicate scientists’ efforts to determine how much the Earth's climate will warm in the future, a new study finds.
In addition to greenhouse gases, which absorb infrared radiation, or heat, emitted from Earth’s surface and sent back to the ground, cloud droplets and aerosols in the atmosphere also affect the planet’s temperature.
The exact overall effect of these two types of particles is still uncertain: while clouds block incoming solar radiation, water vapor also acts as a greenhouse gas, trapping heat like a blanket.
Now, recent satellite observations have found a zone of “in-between particles” in the air around clouds that was previously considered clear.
“The area around clouds has given us trouble,” said study team member Lorraine Remer of NASA’s Goddard Space Flight Center in Greenbelt, Md. “The instruments detected something there, but it didn’t match our understanding of what a cloud or an aerosol looked like. What we think we’re seeing is a transitional zone where clouds are beginning to form or are dying away, and where humidity causes dry particles to absorb water and get bigger.”
Scientists have been aware of an indistinct “halo” surrounding individual clouds, but the newly detected zone is much more extensive, taking up as much as 60 percent of the atmosphere previously labeled as cloud-free.
The previously unknown ingredient in the atmospheric mixture of particles will have to be factored into models that try to predict how the atmosphere influences the change of global temperatures.
“The effects of this zone are not included in most computer models that estimate the impact of aerosols on climate,” said lead author Ilan Koren of the Weizmann Institute of Science, in Israel. “This could be one of the reasons why current measurements of this effect don’t match our model estimates.”
The study was published in the April 18 issue of the journal Geophysical Research Letters.