Record-breaking heat waves have become a staple of summers in the United States. At the heart of these heat waves are “heat domes,” sprawling zones of strong high pressure, beneath which the air is compressed and heats up.
High pressure
pushes warm air down
toward the ground
Hot air masses
expand vertically
into the atmosphere
The dome diverts clouds around them.
As the air
sinks, it warms
by compression.
As the ground warms, it loses moisture, which makes it easier to heat even more.
High pressure
pushes warm air down
toward the ground
Hot air masses
expand vertically
into the atmosphere
The dome of high pressure diverts clouds around it
As the air
sinks, it warms
by compression
As the ground warms, it loses moisture, which makes it easier to heat even more
High pressure
pushes warm air down
toward the ground
Hot air masses
expand vertically
into the atmosphere
The dome of high pressure diverts clouds around it
As the air
sinks, it warms
by compression
As the ground warms, it loses moisture, which makes it easier to heat even more
High pressure
pushes warm air down
toward the ground
Hot air masses
expand vertically
into the atmosphere
The dome of high pressure diverts clouds around it
As the air
sinks, it warms
by compression
As the ground warms, it loses moisture, which makes it easier to heat even more
High pressure
pushes warm air down
toward the ground
Hot air masses
expand vertically
into the atmosphere
The dome of high
pressure diverts
clouds around it
As the air
sinks, it warms
by compression
As the ground warms, it loses moisture,
which makes it easier to heat even more
As high-pressure systems become firmly established, subsiding air beneath them heats the atmosphere and dissipates cloud cover. The high summer sun angle combined with those cloudless skies then further heat the ground.
But amid drought conditions, the vicious feedback loop doesn’t end there. The combination of heat and a parched landscape can work to make a heat wave even more extreme. With very little moisture in soils, heat energy that would normally be used on evaporation — a cooling process — instead directly heats the air and the ground.
Jane Wilson Baldwin, a postdoctoral researcher at the Lamont-Doherty Earth Observatory at Columbia University, said that given the severe drought in the West right now, many feedbacks between the land and the atmosphere are combining to make heat domes worse.
“When the land surface is drier, it can’t cool itself through evaporation, which makes the surface even hotter, which strengthens the blocking high [heat dome] further,” she said in an interview.
The situation is intensified by increasing background temperatures due to the burning of fossil fuels.
“You would be hard-pressed to come up with a metric of heat waves that isn’t getting worse under global warming,” she said, adding that the increasing intensity and duration of heat waves is particularly clear.
One way to gauge the magnitude of a heat dome is to measure the height of the typical halfway point of the lower atmosphere — at the 500 millibar pressure level. The higher this pressure level is, the hotter it is, because hot air is less dense than cold air and expands the atmosphere vertically.
For this pressure level to stretch to heights of 600 dekameters, or 19,685 feet, is quite rare, but several of the heat domes this summer and in recent summers have come close to or eclipsed that threshold.
For the nerds: Map showing the 70-year (1951-2020) trend in annual 500 mb heights from R1 Reanalysis. 6000 -meter (600 dm) Highs are easier to attain than before. pic.twitter.com/jnNq5CuYx5
— Brian Brettschneider (@Climatologist49) July 3, 2021
Evidence suggests climate change is increasing the frequency of heat domes this intense, pumping them up higher into the atmosphere, not unlike adding more air to a hot-air balloon.
Matthew Cappucci contributed to this article.