Since the 1970s, planetary geologists
have known that volcanic features cover large swaths of Mars. Early Mariner 9 images revealed massive shield volcanoes and lava plains on a scale unlike anything on Earth. Olympus Mons, the tallest volcano in the solar system, stands nearly three times
higher than Mount Everest. Alba Mons, the planet's widest volcano, spans a distance comparable to the length
of the continental United States.
Both Olympus Mons and Alba Mons were
primarily built by basaltic effusive eruptions—relatively calm outpourings of "runny" lavas that spread
across the surface in sheets. This is thought to be the most common type of
volcanism on Mars, accounting for the vast majority of its volcanic landforms.
However, a small portion was produced by explosive volcanism of the sort that forms volcanic cones, pyroclastic flows, and ashfalls.
The dearth of explosive volcanic
features on Mars has long puzzled geologists. With an average atmospheric
pressure 160 times lower than Earth's and only a third of the gravity,
explosive eruptions should theoretically occur more easily on the Red Planet,
said Petr Brož, a planetary geologist with the Czech Academy of Sciences. That
rarity is part of what makes features like the volcanic cones (shown above)
found in Mars' Ulysses Colles region so compelling to planetary geologists.
"They appear to be scoria cones—a clear sign of explosive volcanism," Brož added. "They were
the first identified in the Tharsis region in the 2010s, and they helped paint
a broader and more complete picture of Martian volcanism."
The CTX (Context
Camera) on NASA's Mars Reconnaissance Orbiter captured this image (second image above) of Ulysses Colles above
on May 7, 2014. Ulysses Colles is located at the southern edge of Ulysses Fossae, a group of troughs within the Tharsis volcanic region.
The OLI (Operational Land Imager) on Landsat 8 captured an image with similar
cones in the San Francisco Volcanic Field (SFVF) in northern Arizona on June
19, 2025 (top). Planetary geologists consider the cones in the two locations to
be highly analogous. Both images also include grabens—linear blocks of crust that have
shifted downward.
In both images, the scoria cones appear as rounded hills crowned with circular vents, while lava flows spread outward as dark, textured areas around the bases of the cones. At both locations, seemingly younger and smaller lava flows appear to spill from some cones, while older, more weathered flows lie in the background.
"Understanding similar features on
Earth helps us know what to look for on Mars and interpret processes
that we can’t observe directly," said Patrick Whelley, a NASA
volcanologist who is part of a team that develops field equipment and techniques for Moon and Mars
exploration.
SP Crater (above left), located in Arizona’s
San Francisco Volcanic Field, features a 7-kilometer-long lava flow that
extends northward and has been used for NASA astronaut geology training. In two places, the flow has spilled into a graben, creating a
distinctive half-moon pattern along its left side.
On Earth, scoria cones form when
gas-rich magmas soar high into the air and solidify into small particles of
material called scoria that accumulate in steep-sided structures. While similar processes
create cones on Earth and Mars, there are important differences. Martian scoria
cones are typically taller, wider, and have gentler slopes, Flynn said. That
makes sense. With lower gravity and atmospheric pressure, volcanic fountains
can loft erupted magma higher and farther from the vent, producing larger
cones.
There are far more scoria cones on
Earth, where tens of thousands exist and account for about 90 percent of
volcanoes on land. On Mars, "we have only identified tens to a few hundred
candidates," Broz said. It could be that explosive volcanism was never
common on Mars, or it could be that it was but that explosive features have
been covered up by younger, effusive flows or destroyed by erosion, he added.
Whelley noted that on Mars, it remains
unclear whether the Martian lava flows or the scoria cones formed first. The
lava flow could be older, with the cone forming on top. Or, the cone may have
formed first and later become plugged, forcing lava to spill from its side.
Determining the order of events is one of the "puzzles of geology"
that planetary geologists try to solve when studying Martian features remotely,
he said. "Visiting places like the San Francisco Volcanic Field and
studying the geology of analogous features up close on Earth helps us know what
clues to look for when interpreting Martian geology."
Below (left) is a closer view of a scoria cone on Earth, southeast of SP Crater, called Sunset Crater. It erupted about 800 years ago, making it the youngest scoria cone in the San Francisco Volcanic Field. The analogous cone in Ulysses Colles (right), in contrast, is thought to be billions of years old.
Note that eruptions that create scoria
cones are "mildly explosive," usually Strombolian events, characterized by intermittent lava fountains, said Ian Flynn, a planetary geologist at the University of Pittsburgh.
They differ from the far more violent explosive eruptions that send ash columns
billowing tens of kilometers into the air, as happened at Hunga Tonga-Hunga Ha'apai in the South Pacific, he added.
Mars also shows evidence of highly
explosive "super eruptions," but that type of eruption leaves behind a different geologic
signature: large depressions called paterae and broad, thin deposits of ash and other erodible material
sculpted into landforms such as yardangs.
Planetary comparison is valuable for
understanding the geology of distant worlds, Brož said. Without such
comparisons, it becomes harder to determine how landforms on other planets or
moons may have formed at all.
But caution is essential. "In
planetary science, it's often said—only half-jokingly—that even if something
looks like a duck, behaves like a duck, and sounds like a duck, it may not
actually be a duck," he added. It's easy, for instance, to confuse scoria
cones with mud volcanoes.
Researchers are highly confident that
the Ulysses Colles cones formed through explosive volcanism based on the
surrounding volcanic landscape, but in more ambiguous terrain it can be
difficult to tell. Mars is fundamentally different from Earth, he cautioned.
Brož's laboratory research suggests, for
instance, that mud flows on Mars can look much like certain types of lava
flows, and that, under certain conditions, they can even boil and levitate. "We also have
to avoid being constrained by terrestrial experience," he said. "If
we fail to think outside the box, we may overlook important
possibilities."
NASA Earth Observatory images by Lauren Dauphin, using Landsat data from the U.S. Geological Survey and CTX data from the Mars Reconnaissance Orbiter. Story by Adam Voiland.
