Douglas Isbell
Headquarters, Washington, DC                November 13, 1996
(Phone: 202/358-1547)

Diane Ainsworth
Jet Propulsion Laboratory, Pasadena, CA
(Phone: 818/354-5011)

Diane Farrar
Ames Research Center, Mountain View, CA
(Phone: 415/604-3934)

RELEASE: 96-236

U.S. SOIL EXPERIMENT READY FOR LAUNCH ABOARD RUSSIA'S MARS `96

     An instrument developed by the United States to measure
the rate at which metals and organics corrode when exposed to
the Martian environment is set for launch on Nov. 16, aboard
two small landing stations on the Russian Mars '96 spacecraft.

     The instrument, called the Mars Oxidant Experiment
(MOx), was built at the Jet Propulsion Laboratory, Pasadena,
CA, and is part of expanding U.S.-Russian cooperative
efforts in space exploration.

     Integration and final testing of the experiment on the
Russian landers, also referred to as "small autonomous
stations," was completed in late October at the Lavochkin
Research and Production Association in Moscow,  where the
landers were designed and assembled, said Mark Herring,
manager of the experiment at JPL. Two of the MOx instruments
will fly on the mission, one on each of its two landers.

     "This was a major engineering milestone for the U.S.
experiment,  culminating a development effort which started
in 1992," Herring said. "In the course of integration on the
landers, the U.S. team was required to take numerous trips to
Helsinki and Moscow during the past year. We've gained
valuable experience in what is involved with participation on
an international mission."

      The goal of the Mars '96 mission, set for launch aboard
a Russian Proton launch vehicle from Baikonur Cosmodrome in
Kazakstan, is to investigate  the evolution of the Martian
atmosphere, surface and interior by acquiring comprehensive
measurements of the physical and chemical processes that
occur on Mars today and those that may have taken place in
the past.

     The Mars Oxidant Experiment was developed to further
investigate the  presence of a strong oxidizing agent in the
Martian soil that was inferred from the results of the
biology experiments onboard the NASA Viking landers in the
mid-1970s.

     "We hope MOx will be able to tell us more about the
surprisingly reactive properties of the Martian soil first
detected by the Viking biology experiments and tell us if
this reactivity is the cause of the complete absence of
organics in the surface soil on Mars," said
Dr. Christopher McKay, project scientist at NASA's Ames
Research Center, Mountain View, CA.

     "If we plan to search for the organic remnants of early
life on Mars with future missions, then we have to understand
the processes that are destroying these organics on the
surface so that we know how deep we have to dig to reach
unoxidized material," he added. "Viking, for instance, dug
under a rock as deep as 4 inches (11 centimeters) but found
only oxidized sand."

     MOx uses chemical sensor technology originally developed
at the Sandia National Laboratories, Albuquerque, NM. The
instrument measures  the oxidizing power of the Martian soil
and atmosphere using a detector that monitors the change in
reflectivity of a thin chemical film that is exposed  to  the
Martian environment. The instrument, which weighs only three
pounds, relies on its own power source  -- a set of batteries
-- to carry out the measurements.

     Upon landing and deployment, MOx will operate
autonomously, Herring said, according to a sequence that is
programmed into its internal "read-only memory." While the
mission is designed for a one-year lifetime, the operating
life of MOx will be limited by its battery power source.
Depending on the actual conditions on the surface of Mars,
the operating time will be between 80 and 160 days.

     "The instrument's sensor head is located on a petal of
each of the two Russian small stations and is comprised of
eight sensor cell assemblies,  four of which are designed to
contact the soil and four that will be exposed to the
atmosphere," Herring said. "Within each cell assembly there
are six active sensing sites and six reference sites, for a
total of 96 sites.

     "The active sites are protected by thin membranes of
silicon nitride, which protect the sensor films from
premature oxidation," he explained. "These membranes will be
broken upon deployment, exposing the active films. The
reference sites will remain permanently sealed. The sensor
films have been selected to provide a broad range of chemical
reactions. Each film type is duplicated in the air and soil cells."

      Each of the 96 sensor sites is illuminated by two
light-emitting diodes  (LEDs), one operating at a wavelength
of 590 nanometers and the other at 870 nanometers. The
reflected signal will be measured by a silicon photodiode
detector array. The sensor sites are coupled to the LEDs and
the detector array through fiber optics.

      A  key feature of the experiment's data transmission
sequencing is its ability to transmit data three times in
order to reduce the data loss associated with various
communications links. During the mission, the experiment team
will distribute calibration data and mission data sets in
which data from the instruments are merged with pertinent
mission information.

      Another U.S. instrument aboard Mars '96  is the Tissue-
Equivalent Proportional Counter (TEPC).  The TEPC instrument
was developed at NASA's Johnson Space Flight Center, Houston,
TX, to measure and store accumulated radiation spectra during
the interplanetary cruise phase of the mission, as well as
upon arrival in Mars orbit.  This information should yield
important insight into the space radiation environment and
potential health risks involved in future human spaceflight.

     Also aboard the spacecraft, attached to the MOx
electronics case, is a CD-ROM, entitled "Visions of Mars,"
produced by The Planetary Society,  Pasadena, CA, which is
analogous to the records carried into space in 1977 by the
twin Voyager spacecraft. The Mars `96 CD-ROM contains a
collection of science fiction stories, sounds and artwork
which chronicle humanity's fascination with Mars over four
centuries of human history, 10 alphabets,
17 languages and 26 nations. The collection covers the
earliest references to Mars in science fiction to present day
stories about the red planet. A label pointing to the
location of the CD-ROM is mounted on the outside of the
spacecraft and includes a microdot of 100,000 names of
Planetary Society members and instructions on how to use the
CD-ROM.

     If launched on time, Mars `96 will reach the orbit of
Mars in mid-September 1997, at about the same time as NASA's
Mars Global Surveyor (MGS) orbiter,  which was launched
successfully on Nov. 7.  Mars '96 will deploy the two small
stations and two penetrators on the surface of the planet
shortly after arriving in Mars orbit. On-time launches of
both spacecraft will enable MGS to assist in relaying data
from the Russian small stations once
the MGS primary mapping mission begins in March 1998.

                        -end-