The Contrail Effect
By Peter Tyson - Inquiry
The vapor trails from aircraft
influencing the climate, and if so, should we worry?
I've always wanted
to hate contrails, the "condensation trails" streaming out from
behind jets. They're man-made. They force lines on nature, which knows no
lines. They arise out of pollution, and they generate visual
pollution—aircraft graffiti that can erase blue from the sky and light from the
sun. All good reasons to despise these artificial clouds.
But I don't.
I've always been drawn to them. When I see one above, I like
to run my eye along its length until I find the plane, a tiny silver toy.
I like to wonder at the blank space between the plane and the start of the
contrail—emptiness full of potential—and then to see the churning new cloud as
it forms, a tumbling cascade. When the roiling slows and the newborn cloud
settles into a contrail proper, I admire its perfection: a straight white line
sharply etched against the blue. Even when numerous contrails made fat by the
wind crisscross the sky, I don't mind.
Well, I might
now. After a lifetime of enjoying contrails, it came as a surprise to me to
learn recently that something so ephemeral may not be a harmless by-product of
the jet age but may in fact impact the climate. This is of particular concern
in well-traveled air corridors, where contrails by
the hundreds can spread into man-made cirrus clouds that can both block
sunlight from reaching the Earth and trap radiated heat from escaping to space.
Whether
contrails cause a net cooling or a net warming, even whether their effect is
something to worry about, remains unclear. But with air traffic expected to double or even triple by
2050, leading contrail researchers say the influence of these artificial clouds
cannot be ignored.
Out of the blue
A contrail will
form behind a jet if, as exhaust gases cool and mix with surrounding air, the
humidity is high enough and the temperature low enough for liquid water to
condense. The air needs to be supersaturated and the temperature generally
below -40°F, something that typically occurs only in the upper troposphere, the
atmospheric layer several miles up where airliners cruise. Under those
conditions, water vapor from the jet's exhaust and
secondarily from the atmosphere condenses into water droplets. Within a few
tens of feet behind the aircraft, these droplets freeze into the snow-white
particles that bring the contrail to life.
How long a newly
formed condensation trail sticks around depends on the ambient humidity. If
humidity is low, contrails will rapidly dissipate, looking like a comet's tail.
The ice particles sublimate—meaning go straight from ice to vapor—and
you're back to blue sky. If humidity is high, however, contrails can
persist—and those are the ones that trouble climatologists.
A lingering concern
If conditions
are right, newly formed contrails will begin feeding off surrounding water vapor. Like vaporous cancers, they start growing and
spreading. In time, they can expand horizontally to such an extent that they
become indistinguishable from cirrus clouds, those thin, diaphanous sheets
often seen way up high. These artificial cirrus clouds can last for many hours,
and the amount of sky they end up covering can be astonishing: one study showed
that contrails from just six aircraft expanded to shroud some 7,700 square
miles.
Climatologists
realized they had an unprecedented opportunity to scrutinize individual
contrails.
What consequence
might these jet-triggered clouds have? Well, most clouds fall into one of two
categories. High, thin cirrus clouds are normally warming clouds: they let
sunlight through but are good at trapping heat radiating back upwards from the
Earth. Low, thick stratus clouds, on the other hand, are typically cooling clouds,
because they tend to be more efficient at blocking and reflecting sunlight than
they are at trapping radiated heat. Contrails are initially thick, bright,
highly reflective clouds, but over time they morph into wispy cirrus clouds.
Are they then warming or cooling clouds?
For a long time,
scientists didn't even have a baseline from which to begin to answer that
question. Studying contrails has always been difficult: they're high in the sky
and either so fleeting that they're gone in minutes or so persistent that
dozens or even hundreds can crisscross one another, making the study of
individual contrails to get a baseline all but impossible.
Contrail hiatus
At least that
was the case until
One study looked
at the aforementioned contrails that grew to cover 7,700 square miles. Those
condensation trails arose in the wake of six military aircraft flying between
Another study
that took advantage of the grounding gave striking evidence of what contrails
can do. David Travis of the University of Wisconsin-Whitewater
and two colleagues measured the difference, over those three contrail-free
days, between the highest daytime temperature and the lowest nighttime temperature across the continental
These results
suggest that contrails can suppress both daytime highs (by reflecting sunlight
back to space) and nighttime lows (by trapping
radiated heat). That is, they can be both cooling and warming clouds. But what
is the net effect? Do they cool more than they warm, or vice versa? "Well,
the assumption is a net warming," Travis says, "but there is a lot of
argument still going on about how much of a warming effect they produce."
Ongoing debate
In a study
published in 2004, for example, Minnis and colleagues
reported that contrails are capable of increasing average surface temperatures
sufficiently to account for a warming trend in the
Even if Minnis's estimates are correct, other climate experts feel
that any warming from contrails is not something to fret about. In a study
published in 2005, James Hansen of NASA's Goddard Institute for Space Studies
in
I
too will be looking at contrails with a new eye, a jaundiced one.
"Aircraft
are likely to be a significant factor in future climate, but probably not via
their contrails," Hansen told me. "I think our main concern about
aircraft will be their CO2
emissions, not contrails, which are a pretty small climate forcing."
Minnis
counters that Hansen's model, while on target on the global front, doesn't
account as accurately for regional temperature changes. "In zones of
greatest air traffic, like between 30° and 50° North, there's
a large bulge in the actual increase in temperature that's not reflected in the
models," he says. "Until they model that bulge, that thing's still up
in the air." For his part, Minnis intends to
keep his eye on condensation trails and their aftereffects.
Taking action
So does Travis,
who feels the fact that we can measure a change of any sort should be
cause for concern. Even a slight alteration of the daily temperature range, for
instance, can have repercussions, he says. "To you and I,
that may seem like a nice comfortable-sounding scenario—the days are not
as hot, the nights are not as cold—but for natural ecosystems, this could be a
real problem. For one thing, you need to have extreme temperatures to weed out
the weaker species—it's classic Darwinism."
For this reason,
Travis believes we shouldn't sit by and wait to see what happens with
contrails. "Anytime we can see an effect from something artificial like
that, I think we want to try to do something about it," he says. The
British government, for one, may be about to. It's considering requiring planes
to fly at lower altitudes over
I too will be
looking at contrails with a new eye, a jaundiced one—though I'll admit if they
were black as soot, it would be a lot easier. 