Mars Wind Currents Reveal a Surprising Feature – Transcript
[Music]
Early
in its history, Mars had a far more hospitable climate than the one that we see
today, with a thick atmosphere and abundant flowing water.
So
how did it evolve from warm and wet to cold and dry?
Since
2015, NASA's MAVEN mission has been investigating this question by studying the
red planet’s upper atmosphere.
Now,
it has mapped high-altitude global wind patterns at Mars for the first time.
[Wind
sound effect]
During
the closest part of its orbit, MAVEN skims through the upper atmosphere, ingesting
air molecules and determining their composition with an instrument called
NGIMS.
MAVEN can also
rotate NGIMS back and forth to measure the air’s velocity.
These
measurements provide a snapshot of windspeed and direction along a track of
MAVEN’s orbit.
Because the
orbit evolves over time, or precesses, the spacecraft’s closest approach to
Mars drifts across the planet, allowing it to take snapshots at different
locations.
Over the past
four years, MAVEN’s tracks have added up, crisscrossing Mars at many locations
and at various seasons and times of day, wrapping the planet in a web of
observations.
The
measurements reveal how the winds vary with location, and evolve throughout the
Martian year.
Now, scientists
have used MAVEN data to build a global map wind currents roughly 200 kilometers
above Mars: the first time that winds have been mapped globally and at such
high altitude anywhere beyond Earth.
Within the new
map, scientists discovered an unexpected feature: imprints of rugged terrain
far below.
As an example,
during two of its orbits MAVEN saw winds above the Tharsis plateau diverting
away from elevated terrain, driven by giant shield volcanoes reaching twice the
height of Mount Everest.
[Wind
sound effect]
Here’s how the
process works: Down at the Martian surface, winds are forced around and over
obstacles when they encounter mountainous terrain.
Disturbances in
surface-level winds also disturb the air above, propagating up through the
atmosphere as gravity waves.
When they reach
the upper atmosphere, the gravity waves block the high-altitude winds, causing
them to alter course, and allowing MAVEN to sense the presence of mountains and
valleys on the surface, while skimming the edge of space.
High above
Mars, MAVEN is studying the upper atmosphere, and reaching out to feel the
breeze.
It has now made
the first measurement of high-altitude, global circulation patterns, and
discovered a surprising connection to features on the surface.
These
measurements also shed new light on ancient Mars, with its thick atmosphere,
and its warm, wet climate.
By revealing
how the climate of Mars works today,
MAVEN is helping scientists piece together the early chapters of its dramatic history.
[Music]