MEDIA RELATIONS OFFICE JET PROPULSION LABORATORY CALIFORNIA INSTITUTE OF
TECHNOLOGY NATIONAL AERONAUTICS AND SPACE ADMINISTRATION
FOR IMMEDIATE RELEASESeptember 11, 1998
MARTIAN MOON
PHOBOS HIP-DEEP IN POWDER
New
temperature data and close-up images of the Martian moon Phobos gathered by
NASA's Mars Global Surveyor indicate the surface of this small body has been
pounded into powder by eons of meteoroid impacts, some of which started
landslides that left dark trails marking the steep slopes of giant craters.
New temperature measurements show
the surface must be composed largely of finely ground powder at least one meter
(three feet) thick, according to scientists studying infrared data from the
thermal emission spectrometer instrument on the spacecraft. Measurements of the
day and night sides of Phobos show such extreme temperature variations that the
sunlit side of the moon rivals a pleasant winter day in Chicago, while only a
few kilometers away, on the dark side of the moon, the climate is more harsh
than a night in Antarctica. High temperatures for Phobos were measured at -4
degrees Celsius (25 degrees Fahrenheit) and lows at -112 Celsius (-170 degrees
Fahrenheit).
The extremely fast
heat loss from day to night as Phobos turns in its seven-hour rotation can be
explained if hip-deep dust covers its surface, said Dr. Philip Christensen of
Arizona State University, Tempe, principal investigator for the experiment on
the Mars Global Surveyor spacecraft.
"The infrared data tells us that
Phobos, which does not have an atmosphere to hold heat in during the night,
probably has a surface composed of very small particles that lose their heat
rapidly once the Sun has set," Christensen said. "This has to be an incredibly
fine powder formed from impacts over millions of years, and it looks like the
whole surface is made up of fine dust."
New images from the spacecraft's
Mars orbiter camera show many never-before seen features on Phobos, and are
among the highest resolution ever obtained of the Martian satellites. A
10-kilometer-diameter (six-mile) crater called Stickney, which is almost half
the size of Phobos itself, shows light and dark streaks trailing down the slopes
of the bowl, illustrating that even with a gravity field only about 1/1000th
that of the Earth's, debris still tumbles downhill. Large boulders appear to be
partly buried in the surface material.
Infrared measurements of Phobos
were made on August 7, 19 and 31 from distances ranging between 1,045-1,435
kilometers (648-890 miles), far enough away to capture global views of the
Martian moon in a single spectrum. The instrument has been able to obtain the
first global-scale infrared spectra of Earth and Mars in addition to the new
Phobos data, bringing new insights about the composition of these three very
different worlds.
"Of the three,
Earth has the most complex infrared spectra, primarily due to the presence of
carbon dioxide, ozone and water vapor in its atmosphere," Christensen said.
"Mars, which is much colder than Earth because of its distance from the Sun, is
less complex and shows only significant amounts of carbon dioxide. The spectrum
of Phobos, however, has little structure because it has no atmosphere and the
energy it emits is coming entirely from its surface."
On Monday, September 14, Mars
Global Surveyor begins its second phase of aerobraking, using the friction from
repeated passes through Mars' atmosphere to lower and circularize the
spacecraft's orbit. Over the next four-and-a-half months, the spacecraft's
flight path will be lowered from the current 11.6- hour elliptical orbit to a
two-hour, nearly circular orbit over the Martian polar caps. The magnetometer
and thermal spectrometer will be turned on through December to gather data each
time the spacecraft passes closest to Mars' surface. In addition, the radio
science team will be conducting gravity field experiments by measuring small
shifts in the spacecraft's velocity as it passes behind the planet or is blocked
from view by the Sun.
The
spacecraft team at JPL and Lockheed Martin Astronautics, Denver, is continuing
to study possible options for deployment of the spacecraft's high-gain antenna
once it has reached its low-altitude mapping orbit next spring.
Mars Global Surveyor is part of a
sustained program of Mars exploration, managed by the Jet Propulsion Laboratory
for NASA's Office of Space Science, Washington, DC. Lockheed Martin
Astronautics, Denver, CO, which built and operates the spacecraft, is JPL's
industrial partner in the mission. JPL is a division of the California Institute
of Technology, Pasadena, CA.
September 11, 1998