The lightness of water vapor adds heft to global climate models

Clouds form over the California coast in 2002.
Credit: Jacques Descloitres, NASA/GSFC

Climate models without the lightness of water vapor risk uncertainty in cloud simulations.

Clouds are notoriously hard to pin down, especially in climate science.

A study from the University of California, Davis, and published in the journal Nature Geoscience shows that air temperature and cloud cover are strongly influenced by the buoyancy effect of water vapor, an effect currently neglected in some leading global climate models.

Global climate models are the primary tools used to study Earth’s climate, predict its future changes and inform climate policymaking. However, climate models often differ on the precise degree of future warming, largely due to their representation of clouds.

“Climate models are the best tool we have to predict future climate change,” said lead author Da Yang, an assistant professor of atmospheric science at UC Davis and faculty scientist at Lawrence Berkeley National Lab. “It’s important that we actively try to improve them.”

Cold air rises?

While conventional wisdom has it that hot air rises, the reverse is true in the tropical atmosphere, the study notes. Previous research by Yang and his colleagues proposed that cold air rises in the tropics because humid air is lighter than dry air. This effect is known as vapor buoyancy, and it regulates the amount of low clouds over the subtropical ocean.

“Vapor buoyancy influences the distribution of low clouds—the kind of clouds we have off the California coast, which contribute greatly to the global energy balance,” said Yang. “The biggest challenge in accurately predicting future climate change is clouds, so we have to get vapor buoyancy right.”

The study reported that six of the 23 widely-used climate models analyzed do not yet include this effect because water vapor is a trace gas, so its buoyancy effect has been considered negligible. But the study shows the vapor buoyancy effect is more significant than previously realized. In climate models without vapor buoyancy, the low cloud cover can be off by about 50% in certain regions.

How clouds affect climate change

Low clouds are among the most important clouds for climate change and the energy balance of the planet because they reflect so much sunlight. Fewer low clouds can result in more absorbed sunlight and a warmer planet. More low clouds can make for a cooler landscape.

“In a warmer climate, the buoyancy effect of water vapor would be increasingly important due to more atmospheric water vapor,” Yang said. “It is worth spending more effort to understand how water vapor buoyancy regulates Earth’s climate.”

The study’s additional co-authors include UC Davis graduate student Seth Seidel and Wenyu Zhou, a former member of Yang’s group, now at the Pacific Northwest National Laboratory.

The study was funded by Packard Fellowship for Science and Engineering, National Science Foundation, Lawrence Berkeley National Laboratory, and the U.S. Department of Energy.

Journal: Nature Geoscience
DOI: 10.1038/s41561-022-01033-x
Method of Research: Meta-analysis
Article Title: Substantial influence of vapour buoyancy on tropospheric air temperature and subtropical cloud
Article Publication Date: 3-Oct-2022

Media Contact

Kat Kerlin
University of California – Davis
kekerlin@ucdavis.edu
Office: 530-752-7704
Cell: 530-750-9195
 @@ucdavis

Media Contact

Kat Kerlin
University of California - Davis

All latest news from the category: Earth Sciences

Earth Sciences (also referred to as Geosciences), which deals with basic issues surrounding our planet, plays a vital role in the area of energy and raw materials supply.

Earth Sciences comprises subjects such as geology, geography, geological informatics, paleontology, mineralogy, petrography, crystallography, geophysics, geodesy, glaciology, cartography, photogrammetry, meteorology and seismology, early-warning systems, earthquake research and polar research.

Back to home

Comments (0)

Write a comment

Newest articles

Illustration of the thermodynamics-inspired laser beam shaping process in optical thermodynamics research.

Thermodynamics-Inspired Laser Beam Shaping Sparks a Ray of Hope

Inspired by ideas from thermodynamics, researchers at the University of Rostock and the University of Southern California have developed a new method to efficiently shape and combine high-energy laser beams….

Covalent Organic Framework COF-999 structure for CO2 absorption

A Breath of Fresh Air: Advanced Quantum Calculations Enable COF-999 CO₂ Adsorption

Quantum chemical calculations at HU enable the development of new porous materials that are characterized by a high absorption capacity for CO2 Climate experts agree: To overcome the climate crisis,…

Satellite imagery showing vegetation loss due to multi-year droughts

Why Global Droughts Tied to Climate Change Have Left Us Feeling Under the Weather

A study led by the Swiss Federal Institute for Forest, Snow and Landscape Research WSL shows that there has been a worrying increase in the number of long droughts over…