stands next to a model of a
Viking lander to provide scale Each lander comprised a six-sided aluminium base with alternate long sides, supported on three extended legs attached to the shorter sides. The leg footpads formed the vertices of an equilateral triangle with sides when viewed from above, with the long sides of the base forming a straight line with the two adjoining footpads. Instrumentation was attached inside and on top of the base, elevated above the surface by the extended legs. Each lander was enclosed in an
aeroshell heat shield designed to slow the lander down during the entry phase. To prevent contamination of Mars by Earth organisms, each lander, upon assembly and enclosure within the aeroshell, was enclosed in a pressurized "bioshield" and then
sterilized at a temperature of for 40 hours. For thermal reasons, the cap of the bioshield was jettisoned after the Centaur upper stage powered the Viking orbiter/lander combination out of Earth orbit. Astronomer
Carl Sagan helped to choose landing sites for both
Viking probes.
Entry, Descent and Landing (EDL) Each lander arrived at Mars attached to the orbiter. The assembly orbited Mars many times before the lander was released and separated from the orbiter for descent to the surface. Descent comprised four distinct phases, starting with a
deorbit burn. The lander then experienced
atmospheric entry with peak heating occurring a few seconds after the start of frictional heating with the Martian atmosphere. At an altitude of about and traveling at a velocity of 900 kilometers per hour (600 mph), the parachute deployed, the aeroshell released and the lander's legs unfolded. At an altitude of about 1.5 kilometers (5,000 feet), the lander activated its three retro-engines and was released from the parachute. The lander then immediately used
retrorockets to slow and control its descent, with a
soft landing on the surface of Mars. At landing (after using rocket propellant) the landers had a mass of about 600 kg.
Propulsion Propulsion for deorbit was provided by the
monopropellant hydrazine (N2H4), through a rocket with 12
nozzles arranged in four clusters of three that provided thrust, translating to a
change in velocity of . These nozzles also acted as the control
thrusters for
translation and
rotation of the lander. Terminal
descent (after use of a
parachute) and
landing used three (one affixed on each long side of the base, separated by 120 degrees) monopropellant hydrazine engines. The engines had 18 nozzles to disperse the exhaust and minimize effects on the ground, and were
throttleable from . The hydrazine was purified in order to prevent contamination of the Martian surface with Earth
microbes. The lander carried of propellant at launch, contained in two spherical
titanium tanks mounted on opposite sides of the lander beneath the RTG windscreens, giving a total launch mass of . Control was achieved through the use of an
inertial reference unit, four
gyros, a
radar altimeter, a terminal descent and landing
radar, and the control thrusters.
Power Power was provided by two
radioisotope thermoelectric generator (RTG) units containing
plutonium-238 affixed to opposite sides of the lander base and covered by wind screens. Each Viking RTG was tall, in diameter, had a mass of and provided 30 watts of continuous power at 4.4 volts. Four
wet cell sealed nickel-cadmium 8
Ah (28,800
coulombs), 28 volt
rechargeable batteries were also on board to handle peak power loads.
Payload Communications Communications were accomplished through a 20-watt S-band transmitter using two
traveling-wave tubes. A two-axis steerable high-gain parabolic antenna was mounted on a boom near one edge of the lander base. An
omnidirectional low-gain S-band antenna also extended from the base. Both these antennae allowed for communication directly with the Earth, permitting Viking 1 to continue to work long after both orbiters had failed. A
UHF antenna provided a one-way relay to the orbiter using a 30 watt relay radio. Data storage was on a 40-Mbit tape recorder, and the lander computer had a 6000-
word memory for command instructions.
Instruments The lander carried instruments to achieve the primary scientific objectives of the lander mission: to study the
biology, chemical composition (
organic and
inorganic),
meteorology,
seismology,
magnetic properties, appearance, and physical properties of the Martian surface and atmosphere. Two 360-degree cylindrical scan cameras were mounted near one long side of the base. From the center of this side extended the sampler arm, with a collector head,
temperature sensor, and
magnet on the end. A
meteorology boom, holding temperature, wind direction, and wind velocity sensors extended out and up from the top of one of the lander legs. A
seismometer, magnet and camera
test targets, and magnifying
mirror are mounted opposite the cameras, near the high-gain antenna. An interior environmentally controlled compartment held the
biology experiment and the
gas chromatograph mass spectrometer. The
X-ray fluorescence spectrometer was also mounted within the structure. A
pressure sensor was attached under the lander body. The scientific
payload had a total mass of approximately .
Biological experiments The Viking landers conducted
biological experiments designed to detect
life in the Martian soil (if it existed) with experiments designed by three separate teams, under the direction of chief scientist
Gerald Soffen of NASA. One experiment turned positive for the detection of
metabolism (current life), but based on the results of the other two experiments that failed to reveal any
organic molecules in the soil, most scientists became convinced that the positive results were likely caused by non-biological chemical reactions from highly oxidizing soil conditions. Although there was a pronouncement by NASA during the mission saying that the Viking lander results did not demonstrate conclusive
biosignatures in soils at the two landing sites, the test results and their limitations are still under assessment. The validity of the positive 'Labeled Release' (LR) results hinged entirely on the absence of an oxidative agent in the Martian soil, but one was later discovered by the
Phoenix lander in the form of
perchlorate salts. It has been proposed that organic compounds could have been present in the soil analyzed by both
Viking 1 and
Viking 2, but remained unnoticed due to the presence of perchlorate, as detected by Phoenix in 2008. Researchers found that perchlorate will destroy organics when heated and will produce
chloromethane and
dichloromethane, the identical chlorine compounds discovered by both Viking landers when they performed the same tests on Mars. The question of microbial life on Mars remains unresolved. Nonetheless, on April 12, 2012, an international team of scientists reported studies, based on mathematical speculation through
complexity analysis of the
Labeled Release experiments of the 1976 Viking Mission, that may suggest the detection of "extant microbial life on Mars." In addition, new findings from re-examination of the Gas Chromatograph Mass Spectrometer (GCMS) results were published in 2018.
Camera/imaging system The leader of the imaging team was
Thomas A. Mutch, a geologist at
Brown University in
Providence, Rhode Island. The camera uses a movable mirror to illuminate 12
photodiodes. Each of the 12 silicon diodes are designed to be sensitive to different frequencies of light. Several broad band diodes (designated BB1, BB2, BB3, and BB4) are placed to focus accurately at distances between six and 43 feet away from the lander. A low resolution broad band diode was named SURVEY.
Mass Breakdown of Viking Landers , days before the landing of Viking 1. ==Control systems==