voyager 2 jupiter encounter press kit
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First Decade...
. 9 X-NationalAeronauticsandi4j ,Space Administration.41 196-1979 Washington, D.C. 20546AC 202-755-8370
For Release IMMEDIATE
Press Kit Project Voyager 2Jupiter Encounte r
RELEASE NO: 79-86
Contents
GENERAL R E L E A S E ........... . . . . . . . . . . . . . . . . . . . .. 1-11
TWO VIEWS OF VOYAGER 2 FLIGHT PAST JUPITER ........ 12
VOYAGER MISSION SUMMARY........................... 13-18
VOYAGER 1 SCIENCE RESULT' ......................... 19-23
Jupiter 's Atmosphere. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9Satel l i tes an d Ring ............................ 21
Magnetosphere ................................... 22
June 26 , 1979
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IsICONTENTS (cont 'd . )
JUPITER SCIENCE OBJECTIVES ........... ........ 24-36
Magnetic Fields Investigation.. . . . . . . . . . . . . . . . 25
Cosmic Ray Invest igat ion. . . . . . . . . . . . . . . . . . . . . . . 26
Planetary Radio Astronomy. . . . . . . . . . . . . . . . . . . . . . . . . 26
Infrared Interferometer Spectrometer
an d Radiometer ... .............. .... 27Photopolarimeter . . . . . . . . . . . . . . . . . . . . . . . . ..... 28Radio Science. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
Imaging ............................................ 29
Low-Energy Charged Particles ....................... 32
Plasma Experiment ........................ 33
Plasma Wave Experiment ............................. 34
Ultraviolet Spectrometer ........................... 36
VOYAGER EXPERIMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37-38
THE PLANET JUPITER ................................... 39-42
THE SATELLITES OF JUPITER............................ 43
PLANET COMPARISON.................................... 44
VOYAGER SCIENCE INVESTIGATORS . . . . . . . . . . . . . . . . . . . . . . . . 45-49
VOYAGER TEAM.......................................... 50-51
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Fit Decade.News#Zs -~ it T National Aeronautics and
5 *;, -^4'-\ g Space Administration" , g ; 09-1979 Washington, D.C. 20546
, AC 202 755-8370
For Release:Joe-McRoberts
Headquarters, Washington, D.C. IMMEDIATE(Phone: 202/755-3680)
Robert MacMillin .NASA Jet Propulsion Laboratory, Pasadena, Calif.(Phone: 213/354-5011)
RELEASE NO: 79-86
VOYAGER 2 TO TAKE JUPITER CLOSE LOOK JULY 9
Just four months after Voyager l' s startling discoveries
about Jupiter, it s major satellites an d the complex Jovian
environment, a twin NASA spacecraft , Voyager 2, is homing in
fo r a follow-up close encounter with th e g i a n t p l a n e t on
Monday, July 9.
Voyager 1 began a seven-month Jupiter surveillance on
Jan. 6, ending it s encounter activities on April 13. Voyager 2
opened it s observatory phase on April 25 and will monitor the
Jovian system until Aug. 28.
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iIj Both spacecraft will continue on to Saturn, and Voyager 2
ma ybe retargeted there for Uranus.
The dual-spacecraft expedition could span a decade and
produce a wealth of ne w information on as many as 15 major
bodies of the solar system.
During its surprise-packed excursion through the Jovian
system, Voyager 1 discovered a wispy ring of particles around
Jupiter, bolts of lightning and immense auroras in the planet's
violently churning atmosphere and towering volcanic eruptions
on the satellite lo.
More than 18,000 pictures of Jupiter, the Galilean satel-
lites.. -- Io, Europa, Ganymede, Callisto an d tiny Amalthea --
were obtained with Voyager l's two-camera imaging system during
the 98-day observation period.
Voyager 2's science sequences, partially modified by the
findings of Voyager 1, are programmed for nearly 15,000 pictures.
At the time of Voyager 2's closest encounter, Jupiter will be
931,360,333kilometers (572,720,483 miles) from Earth.
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Scien t i s t s on th e Voyager experiment teams found th e
var ious , bodies in the Jovian system explored by Voyager1 do
not closely resemble the planets nearer the Sun, nor one another.
The wide range of unexpected findings, they determined, is due
to both th e real differences between th e outer and inner systems
and to th e lack of prior knowledge, the latter due in part to
the great distance separating Earth and Jupiter.
Voyager 2 wa s launched Aug. 20, 1977, from Cape Canaveral,
Fla., aboard a Titan-Centaur rocket combination. On Sept. 5,
1977, Voyager 1 was boosted onto a faster, shorter trajectory
and moved ahead of Voyager 2 before th e end of the year.
At Saturn encounter, th e gap between th e two Voyagers will
be about nine months. Using Jupiter's enormous gravity, the
trajectories are curved and th e Voyagers accelerated fo r th e
Saturn leg of the mission. Voyager 1 will arrive at Saturn in
November 1980 and Voyager 2 in August 1981. An option exists
fo r controllers to target Voyager 2' s trajectory past Saturn fo r
a January 1986 Uranus encounter.
After completing their planetary missions, both spacecraft
will search fo r the outer limit of th e solar wind, that boundary
somewhere in our part of th e Milky Way where th e influence of
the Sun gives way to th e other stars of the galaxy.
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Each Voyager uses 10 instruments an d the spacecraft radio
system to study th e planets, their principal satellites, rings
of the planets, the magnetic an d radiation regions surrounding
th e planets, and th e interplanetary medium.
The Voyagers are carrying telescope-equipped slow-scan TV
cameras, cosmic ray detectors, infrared spectrometer-radiometers,
low-energy charged-particle detectors, magnetometers, photo-
polarimeters, planetary radio astronomy receivers, plasma detec-
tors, plasma wave instruments and ultraviolet spectrometers.
One-hundred-six scientists make up the Voyager science
experiment teams.
The television investigation, probably th e most interesting
to most people because of the universal appeal of th e visual
image, will result in at least 50,000 pictures of Jupiter, Saturn,
the rings of th e planets, 11 of their moons an d black space near
f |the planets in a search fo r new Jovian an d Saturnian satellites.Jupiter's thin ring was discovered in on e of Voyage.- l' s black
space pictures. Uranus, it s recently discovered ring system an d
on e or more moons, also may become targets fo r th e Voyager 2
cameras.
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The other Voyager instruments will study the planetary
and satellite atmospheres and ionospheres; the magnetospheres
of Jupiter and Saturn and the relationships between these regions
and th e solar wind that streams from the Sun through interplane-
tary space; and radio signals from Jupiter which, after the Sun,
emits the strongest radio noise in ou r sky. Other objectives
include all-sky surveys of interplanetary space and th e measure-
ment of cosmic rays which invade th e solar system from other
regions of th e galaxy.
Measurements of Voyager's radio communications waves will
provide information on th e gravitational fields and atmospheres
of th e planets and their satellites, the rings of Saturn, an d
th e solar corona.
Jupiter an d Saturn ar e by fa r the largest planets an d
together hold in their regimes more than two-thirds of all the
moons in the solar system. Jupiter's diameter is 11 times that
of Earth an d contains more matter than al l of the other planets
an d moons combined. With 13 known moons, four of them the size
of small planets, Jupiter is a kind of miniature solar system.
Saturn ha s 10 satellites an d a spectacular ring system which
appears to be made up of tiny pieces of ic e an d snow.
Until recently ou r knowledge of Jupiter an d Saturn was
ru d m. n %a ry
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Ground-based studies by optical, infrared And radio
astronomy have defined the most basic properties of Jupiter
and Saturn and their satellites and hinted at the unique scien-
tific potential of these systems. Even less is known about
Uranus and its environs.
In 1973 and 1974, Pioneer 10 and Pioneer 11 made recon-
naissance flights to Jupiter. As the spacecraft sped past
Jupiter, their instruments began to reveal the complexity of
it s atmosphere and the extent and strength of the Jovian magneto-
sphere. (Both spacecraft are still operating. Pioneer 11 will
fly close by Saturn in September 1979.) Building on the Pioneer
experience, Voyager '%.s the next step in the exploration of the
Jovian and Saturnian systems.
Voyager 2 begnn its observatory phase on April 25 by study-
ing large-scale atmospheric processes on Jupiter and phenomena
associated with the relationship between Jupiter's magnetosphere
and the large inner moons. From 56 million km (35 million mi.),
the first Jupiter pictures by Voyager 2 already exceeded the best
resolution with Earth telescopes.
Just as Voyager 1 observations during the approach to
Jupiter in January showed dramatic broad-scale changes in ihe
planet from the Pioneer 11 observations four years earlier,
Voyager 2 has recorded visible differences in the huge Jovian
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Voyager 2 makes its closest approach to the planet at
7:20 p.m. EDT,* July 9 at a distance of about 650,000 km
(404,000 mi.) from the visible cloud tops. Activity will reach
a peak during the "near encounter" phase, a 40-hour period sur-
rounding closest approach.
In March 1979, Voyager l's trajectory curved past the
planet to a point just 273,000 km (173,000 mi.) above the cloud-
tops. The greater flyby distance for Voyager 2 results in less
radiation exposure and a slower flight to Saturn.
The distance between Jupiter and Earth also varies greatly
in the four months separating the two encounters. Voyager 1 was
about 250 million km (150 million mi.) closer to Earth at the
time of its Jupiter rendezvous on March 5. This is du e to the
planets' relative positions in their orbits around the Sun. By
July 9, Earth will have traveled a distance equivalent to a
third of its entire orbit around the Sun.
The trajectory for each spacecraft is unique and wa s de-
signedfor specific observations at both Jupiter and Saturn.
*The spacecraft actually flies closest to Jupiter at 6:29 p.m. EDT,
July 9. Bu t if one were able to watch the event from Earth, theeye would see the close encounter 51 minutes, 49 seconds, later-- the time it takes light to travel 931 million km (573 millionmi.). The same velocity is true using the Voyager radio to watchthe event. Hence, all times listed here are Earth-received t i rmes.
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The first spacecraft flew past Jupiter just south of th e
equator, while Voyager 2 makes its Jupiter pass deep in the
southern hemisphere.
Voyager 2 will receive a lesser radiation dose than
Voyager 1. It will be closest to Europa, Ganymede and Callisto
before it reaches the planet; will not have a close encounter
with Io; and will remain outside Europa's orbit. First pictures
of the planet-size moons will be obtained on June 25, Callisto;
June 30, Ganymede; and July 3, Europa. The spacecraft is expected
to cross Jupiter's bowshock about July 5 and enter the planet's
magnetosphere.
By encountering the Galilean satellites during approach
to Jupiter rather than on the outward passage, as done by
Voyager 1, the second Voyager will obtain high-resolution photos
and other measurements of their opposite sides. Closest approach
to Callisto will occur at 9:13 a.m. EDT, July 8 at a range of
215,000 km (133,600 mi.); Ganymede, 4:06 a.m., Jnly 9, 62,000 km
(38,600 mi.); Europa, 2:43 p.m., July 9, 206,000 km (.128,000 mi.);
and Amalthea, 4:53 p.m., July 9, 559,000 km (348,000 mi.).
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Someof th e Voyager 2 near encounter highlights include:
* The first high-resolution pictures of Europa. Voyager 1
showed Europa to be laced with huge intersecting linear features,
even from a range of nearly 2,000,000 km (1,250,000 mi.).
Voyager 2 will improve upon the resolution of the Marchphotos
of Europa by about a factor of 10.
v Further examination of the thin ring of particles
Voyager 1 found circling Jupiter. Voyager 2 will cross the
equatorial plane twice -- at 8:00 p.m. EDT on July 8 and again
at 9:00 p.m. EDT on July 10. An attempt will be made to obtain
a color picture of th e ring.
* An lo "volcano watch."The discovery of active volcanism
on the Jovian moon Io by Voyager 1 has prompted planning fori6n-
tensive Io imaging operations shortly after Jupiter closest
approach on July 9. Although the trajectory takes the spacecraft
to a far greater Io encounter distance (1,130,000 km or 702,000
mi.) than the March encounter (less than 20,000 km or 12,000mi.),
a time-lapse imaging sequence will be executed to providea
possible history of erupting volcanos on the satellite. From
7:30 p.m. EDT, July 9 until 5:30 a.m. EDT, July 10, Voyager2
remains within 1,215,000 km (755,000 mi.) of Io.
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The Voyager 2 trajectory also carries the spacecraft
behind Jupiter, relative to Earth and the Sun. As Earth dis-
appears behind Jupiter, then emerges after two hours of occul-
tatior, th e changes in th e signal characteristics of the space-
craft radio link with Earth will give information about the
vertical structure of the atmosphere, ionosphere and clouds.
As the Sun is occulted by Jupiter, the ultraviolet spectrometer
observes the Sun as it Luoves behind the limb of the planet ob--serving similar scattering effects on sunlight as it penetrates
the atmosphere. The Earth occultation experiment begins at
5:20 p.m. EDT, July 10 and continues until 7:08 p.m. EDT. Sun
occultation extends from 8:07 p.m. EDT, until 9:30 p.m. EDT.
(At Saturn, Voyager 1 will conduct Sun and Earth occulta-
tion experiments with the planet, the moon Titan and Saturn's
rings. If Voyager 2 goes on to Uranus, only occultation of the
planet will be possible.)
NASA's Office of Space Science has assigned project manage-
ment and operation of the Voyager missions to the Jet Propulsion
Laboratory (JPL), Pasadena, Calif., which is managed for NASA by
the California Institute of Technology. JP L designed, assembled
and tested the spacecraft, and conducts tracking, communications
and mission operations. JPL operates the Deep Space Network for
NASA's Office of Tracking and Data Systems.
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NASA program manager is Rodney A. Mills. JPL project
manager is Raymond L. Heacock. Dr. Milton A. Mitz is NASA
program scientist. Dr. Edward C. Stone of Caltech is project
scientist.
Estimated cost of the Voyager Project, exclusive of launch
vehicles, tracking and data acquisition and flight support
activities, is $343 million.
(END OF GENERAL RELEASE,; BACKGROUND INFORMATION FOLLOWS.)
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VOYAGER MISSION SUMMARY
August 1977 - June 1979
Voyager 2, first of the two Jupiter and Saturn-boundspacecraft launched during the 1977 opportunity,, lifted
off Complex 14 at Cape Canaveral, Fla., aboard a TitanCentaur launch vehicle at 10:29 a.m., EDT, on Aug. 20, 1977.
Liftoff occurred less than five minutes into the window onthe first day of the 30-day launch period.
Sixteen days later, an identical spacecraft, Voyager 1,
was boosted onto a faster, shorter trajectory which wouldcarry it past Jupiter four months earlier and Saturn nine
months earlier than its twin. The second launch was de-
layed four days when it was no t immediately certain that
Voyager 2's science boom had fully deployed and locked it-self in place. Voyager 1 lifted off at 8:46 a.m., EDT,
Labor Day, Sept. 5, 1977.
On Dec. 15, 1977, Voyager 1 had caught up with and
passed Voyager 2 at a distance of about 170 million km(105 million mi.) from Earth. Both spacecraft had begun
passage through the asteroid belt just a few days earlier --on Dec. 10 -- Voyager 1 exiting Sept. 8, 1978, and Voyager 2on Oct. 21. The debris-strewn asteroid belt, which circlesthe Sun between the brbits of Mars and Jupiter, is about360 million km (223 million mi.) wide and, at one time, wasbelieved to present a hazard to intruding spacecraft. The
Voyagers were the third and fourth spacecraft to make sucha crossing, following the early Jupiter reconnaissanceflights of Pioneer 10 and 11 in 1973 and 1974.
As many as eight trajectory correction maneuvers are
planned for each spacecraft to refine the flight paths ana
assure the precise arrival times and encounter distancesrequired by the mission. Voyager 1 has executed five maneu-
vers, th e last on March 16, 1979 -- 11 days after Jupiterclosest approach. Voyager 2's fourth maneuver is scheduledfor June 27, 1979.
Two major engineering problems -- one with each space-
craft -- arose during th e long cruise phase of th e mission.
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During a calibration of Voyager i's scan platform onFeb. 23, 1978, the platform's azimuth gears slowed and stal-led to a standstill. During the next three months, engineersdetermined that a small amount of soft, pliable debris --apparently retained in th e unit during it s assembly -- hadfound its way into the gears. By maneuvering the platformthrough the problem area, the bits of debris were crushedapparently by th e gears, freeing th e platform.
Voyager's scan platform, upon which are mounted theplanet tracking instruments including the two-camera tele-vision experiment, can be rotated on two axes for precisionpointing. No problems arose during the rigorous maneuveringof the platform as Voyager 1 made its Jovian system recon-naissance.
Voyager 2's primary radio receiver failed on April 5,1978, and the spacecraft's computer command subsystem auto-matically switched in the backup receiver. Unlike the Voy-ager 1 scan platform problem which has been resolved, Voy--ager 2's radio emergency remains a concern. Only a singlereceiver is available to the spacecraft which may be expectedto operate through Uranus encounter (January 1986), and itis functioning with a failed tracking-loop capacitor.
The existing receiver can no longer normally follow achanging signal frequency. Telecommunication engineers,however, have developed a technique of determining the fre-quency at which the Deep Space Network station must transmitcommands. This procedure has worked successfully sincemid-April, 1978.
Because of the loss of the redundant receiver capa-bility, a backup mission sequence wa s transmitted to Voyager 2and stored in the on-board computer. The backup sequencewould assure a minimum-science encounter at Saturn in theevent ground command capability is lost. The sequencewill be updated periodically.
During the long cruise, numerous tests and calibrationshave been conducted to allow scientists to evaluate theirinstrumentsand the acquired data.
All of the instruments on both spacecraft made measure-ments during th e cruise -- interplanetary magnetic fields,the solar wind and sky scans by the spectral instruments(ultraviolet spectrometer, infrared interferometer andspectrometer and photopolarimeter).
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The TV camera system has been exercised throughout the
flight. Two weeks after launch, as part of an optical na-vigation and video recording and playback test, Voyager 1captured both the Earth and the Moon in the same picture.The two crescent bodies, never before photographed to-gether, were more than 11 1/2 million km (7 million mi.)from the spacecraft camera.
By Dec. 10, 1978, still 85 days and 85 million km(53 million mi.) from Jupiter, Voyager l's narrow angle
TV camera obtained a series of pictures of the planet re-vealing more detail than the very best ground-based tele-scopic photographs. Only a few Jovian disk images ob-tained by Pioneer 10 in December 1973 and Pioneer 11 inDecember 1974
during their final 24 hours of approach tothe planet exceed the resolution in the distant Voyager pic-tures.
The December photos as well as others obtained duringperiodic camera calibrations have shown dramatic changes inthe visible appearance of Jupiter during the past fouryears. These broad-scale differences in the huge featuresof the planet have been observed also by Earth-based astron-omers.
Voyager l's Jupiter observatory phase, that segment ofthe mission when all science activity was directed towardthe planet, its satellite system and the Jovian environmentwithin the solar system, began on Jan. 4, 1979, with thespacecraft 61 million km (38 million mi.) from Jupiter andcontinued through the end of the month.
Activities during the 26-day period were designed toprovide scientists with a long-distance, long term look atthe entire Jovian system and Jupiter's large-scale atmos-pheric processes in preparation for near encounter opera-tions on March 4 and 5.
The narrow-angle television camera recorded four images,each through a different color filter, every two hours --th e time it takes Jupiter to rotate 72 degrees -- provid-ing a "zoom" effect at five selected longitudes.
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The pictures obtained at on e of the five longitudes --
that which centers the Great Red Spot on the face of theplanet -- were assembled into a time-lapse film which showsthe complexity of the Jovian atmosphere in the region of thehuge feature.
During a four-day period beginning Jan. 30, the nar-row-angle camera took a picture of Jupiter every 96 secondsusing three color filters. Some 3,500 images are beingprocessed into a color film record of the planet's rapidrotation with a ne w color image each 3 degrees for 10 fullJupiter days. A two-rotation segment has been transfer-red to motion picture film.
Despite th e intense radiation environment -- perhaps100 times that which would be lethal to humans -- only tw oproblems arose with Voyager l's sensitive electronics. Cir-cuitry in the photopolarimeter, which ha d experienced er-ratic analyzer wheel operation during Earth-to-Jupitercruise, failed about six hours before closest approach toJupiter. Even this failure may not be due to radiation.High accuracy photometry, which would have provided thebest data on cloud heights and cloud particle size and
shape, wa s lost. The instrument wa s turned off and it isdoubtful that it will be operable at Saturn.
A brief loss of synchronization between two spacecraftcomputers occurred at the peak of radiation buildup and re-sulted in the smearing of some of the lo and Ganymede images.The timing reference between the two systems was reset whenthe radiation intensity diminished.
Voyager 1 recorded five crossings of the bowshock asJupiter's magnetosphere expanded and contracted under vary-ing pressure of the solar wind. The wind crossing occurredFeb. 28 at about 6,000,000 km (3,800,000 mi.) from theplanet. Th e final crossing, on March 2, was at 3,600,000 km(2,100,000 mi.).
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Although Voyager l's encounters with Jupiter's inner
moons occurred after the spacecraft passedthe planet,
long-range satellite observations began some two weeks
earlier -- Callisto on Feb. 18, Ganymede on Feb. 25,Europa
on March 1, 1o on March 2 and tiny Amalthea, closest toJu-
piter, on March 4.
On March 4, just 17 hours before closest approach,
Jupiter's ring was photographed half-way between Amalthea's
orbit and the planet's cloudtops. Th e very long exposure
(11 minutes, 12 seconds) was planned for the brief period
when Voyager crossed the equatorial plane of Jupiter.I
Voyager 1 reached its closest point to Jupiter at
7:05 a.m., EST(spacecraft time) on March 5 at an altitude
of 278,000 km (173,000 mi.) above the cloudtops. Distancefrom Earth at that moment was 679,675,000 km (422,330,000
mi.) or 37 43 seconds, light time. Voyager's
radio signal radiated at closest approach reached the Deep
Space Network station in Canb-arra, Australia, at 7:42
a.m., EST.
Jupiter's enormous gravity accelerated the spacecraftto 135,000 km/hr (84,000 mph). The velocity enables Voyager
1 to cross paths with Saturn at a pre-selected timeand
range some 20 months later.
Encounters with the Galilean satellites occurred on
the outbound leg: within 19,000 km (11,800 mL) of Io at10:51 a.m., EST, on March 5; Ganymede, 112,000 km (69,600
mi.), at 9:53 p.m., EST, March 5; and Callisto, 124,000 km
(77,000 mi.) at 12:47 p.m., EST, on March 6.
Although Voyager 1 came within 732,000 km (455,000
mi.) of Europa, final images were obtained at a far greater
range -- 1,800,000 km ('.119,000 mi.) It remains fo r Voy-
ager 2 to acquire the h.gh-resolution imAges of Europa for
determination of the nature of the intr iguing pattern of
linear features scarring the face of the satellite.
Voyager l's close passage at Io was designed to send
the spacecraft through the so-called Io flux tube, a mag-netic link between the moon and the planet where charged
particles spiral along the Jovian magnetic lines of force.
Voyager's fields and particles instruments measured an elec-
tric current across the flux tube at five million amperes,
some five times areater than oredicted.
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Voyager did not penetrate th e flux tube, because thegreater-than-predicted current had deflected the flux tubefrom its expected location.*X
The Voyager 1 trajectory also carried the spacecraftbehind Jupiter, relative to Earth and th e Sun. As Earthdisappeared behind Jupiter, then emerged after two hours of
"occultation," the changes in the signal characteristicsof th e spacecraft radio link with Earth provided infor-mation about th e vertical structure of th e atmosphere, ionosphereand clouds. As the Sun was occulted by Jupiter, the ultra-violet spectrometer observed the Sun as it moved behindth e limb of the planet observing similar scattering ef-fects on sunlight as it penetrated the atmosphere. TheEarth occultation experiment began at 11:14 a.m., EST,
March 5, an d continued until 1:20 p.m., EST; Sun occultationextended from 12:07 p.m., EST, until 2:24 p.m., EST.
Though hundreds of images of Io had already been ob -tained and had already received cursory examination, activevolcanism on the satellite was first identified with aphoto taken March 8 not fo r geological study, but specifi-cally fo r optical navigation purposes. A special over-exposure of the Io crescent with a known pattern of stars,acquired three days after encounter, revealed a plume ofgases an d solid particles above th e moon's limb. Furtherexamination of earlier photos and other Io observationssubsequently led to the identification of seven actively-erupting volcanos.
Other phenomena observed by Voyager 1 as it lookedback at th e receding planet included auroras at Jupiter'snorth pole and superbolts of lightning crackling in th e upperatmosphere on the dark side.
Voyager 1 concluded it s Jupiter observations onApril 13, 40 days after closest approach. Th e spacecraftand it s instruments will remain at a low-level of opera-tion throughout Voyager 2's Jovian system activities an dwill gather and record interplanetary measurements along
the billion-mile flight path to Saturn.
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VOYAGER 1 SCIENCE REULTS
Voyager 1 's encounter with. Jupiter and its majorsate l l i tes hias provided evidence of an entirely new se t ofphenomena in that 'mini-solar system.'
Scientis ts-are now- beginning to unders-tand that veryimportant phlysical, geological and atmospheric processesare going on -- in the planet, satellites and magnetosphere -that are neti to observers.
Discovery of active volcanism on lo was probably thegreatest surprise - and may turn out to have the most far-reaching effects. It is likely that activity on 10 may beaffecting the entire Jovian system. 1o appears to be thesource of matter that pervades the Jovian magnetosphere.Sulfuri oxygen and sodium, apparently erupted by the sat-
ellite's many volcanoes, were detected by Voyager 1 as faraway as the outer dege of the magnetosphere. Particles ofthe same material were detected inside 1o's orbit, wherethey are accelerated to greater than 10 per cent of thespeed of light.
* It ia clear to scientists that a comparision of datafrom Pioneer 10 and Voyager 1 shows that something haschanged in the five and one-half years since the firstspacecraft reached Jupiter.
It is no t clear just what the meaning is of thosechanges no r what has caused them. The changes ma y be re -
lated to Ionian activity.It is difficult, however, to imagine that Io's
volcanoes were not erupting when Pioneer 10 flew past inDecember 1973. Voyager scientists say it is also difficultto believe that Pioneer 10 instruments failed to see thamagnmetospheric concentrations of sulfur 4etected byVoyager 1. Pioneer 10 apparently saw no sulfur.
The following is a summary of the more importantVoyager 1 science results:
Jupiter's Atmosphere
* Atmospheric features of broadly different sizesappear to move with uniform velocities. That suggests toscientists that mass motion (movement of material) and notwave motion (movement of energy through a relatively station-ary mass) is being observed.
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* Rapid brightening of features in the atmospherewa s observed, followed by spreading of cloud material.That is probably the result of disturbances that triggerconvective (up and downwelling) activity.
* A belt-zone pattern of east-west winds was seen inthe polar regions, roughly similar to the pattern seen inthe more temperate areas. Previous investigations ledscientists to believe the polar regions are dominated byconvective upwelling and downwelling. Voyager 1 indicatesthey are not.
* Material associated with the Great Red Spot movesin a counterclockwise (anticyclonic) direction. Tie materialappears to have a rotation period of about si x days.
* Smaller spots appear to interact with the Great Red
Spot and with each other.
* Auroral emissions (similar to Earth's "northernlights") were observed in Jupiter".s polar regions. Theyhave been seen in both ultraviolet and visible light. Theultraviolet auroral emissions were not present during thePioneer 10 encounter in 1973.
v Cloud-top lightning bolts, similar to superbolts inEarth's high atmosphere, were detected.
* The atmospheric temperature at 5 to 10 millibars(1/200th to 1/100th Earth's surface atmospheric pressure)
is about 160 degrees Kelvin (-171 degrees Fahrenheit). Thereappears to be an inversion layer -- a warm region above acolder layer -- at the 35-mi'llibar level. (Earth's surfacepressure is approximately 1,000 millibars.)
* Voyager 1 observed an ionospheric temperature thatchanged with altitude, reaching about 1,100 K (1,520 F).That also was no t observed by Pioneer 10, and Voyagerscientists believe they are witnessing large temporal orspatial changes in the ionosphere of Jupiter.
* Helium in the upper atmosphere was measured. Itspercentage compared to hydrogen is important to scientiststo understand the composition and history of the atmosphere --and indirectly, the primordial cloud ou t of which the Sunand planets formed. There are about 11 per cent as manyhelium atoms as hydrogen molecules.
* The atmospheric temperature above the Great Re d Spotis substantially colder than in surrounding regions.
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Satellites and Ring
* Seven currently active (erupting) volcanoes, prob-ably driven by tidal heating, have been positively identi-fied on Io. Many
more are suspected. Plumes from thevolcanoes extend up to 250 km (155 mi.) above the surface.The material is being ejected at rates up to 3,600 km/hr(2,200 mph). By comparison, ejection velocities have
been measured at Mount Etna, one of Earth's most explosivevolcanoes, at 180 km/hx (112 mph). The volcanism on Iois apparently associated with heating of the satellite byt ida l pumping. Io's orbit is perturbed by Europa andGanymede, and then Io is yanked back again by Jupiter.That action causes t i da l bulging as great as 100 meters(330 feet), compared with typical t i da l bulges on Earth
of 1 m (3 ft.)
* Voyager 1 measured the temperatureof a large ho tspot on Io that is associated with a volcanic feature.
While the surrounding terrain has a temperature of -138 C(-216 F), th e hot spot 's temperature is about 20 C (68 F).
The hot spot may, some scientists believe, be a lava lake,although the temperature indicates that the surface of thespot is not molten; it is, at least, reminiscent of lavalakes on Earth. (A lava lake is formed by ejection of magmaand is directly connected to the magma source. "Islands"in th e lake are composed of blocky plas t ic lava cal led.epimagma, while th e lake i t se l f is composed of thin fluidmaterial called pyromagma.)
* Europa displays a large number of intersectinglinear features in the distant, low-resolution photos fromVoyager 1. The features ma y be caused by crustal rifting(tectonic) processes. The closer, higher-resolution photosfrom Voyager 2 are expected to provide addit ional informa-tion. There is a possibility that Europa ma y be internallyactive due to tidal heating at a level one-tenth or lessthan that on Io.
* Ganymede shows two distinct types of terrain --cratered and grooved. That suggests to scientists thatGanymede's entire, ice-rich crust has been under tensionfrom global tectonic processes.
* Callisto has an ancient, heavily cratered crust,with remnant rings of enormous impact basins. The basinsthemselves have been erased by the flow of the ice-ladencrust -- to the degree that almost no topographical reliefis apparent in Voyager l's high-resolution images.
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* Amalthea has an elliptical shape: it is 265 km(164 mi.) by 140 km (87 mi.). Amalthea is about 10 timesbigger than Mars' larger satellite, Phobos.
* A ring ofmaterial was discovered around Jupiter.The ring's outer edge is 128,000 km (79,500 mi.) from thecenter of the planet, an d is no more than 30 km (18.6 mi.)thick. Thus Jupiter joins Saturn and Uranus as one of theringed planets. (Since the Voyager 1 encounter, the ring'sexistence has been verified by ground-based observations.)
Magnetosphere
* An electric current of about 5 million amperes wasdetected in the flux tube connecting Jupiter and lo. Thatwas five times stronger than thecurrent predicted beforeVoyager l's arrival. The spacecraft did no t fly throughthe flux tube, as had been planned, since the increasedcurrent had twisted the flux tube 7,000 km (4,300 mi.)from the expected location.
9 Voyager 1 detected ultraviolet emissions from doublyand triply ionized sulfur and from doubly ionized oxygen.Since Pioneers 10 and 11 did not detect these same emissions,that indicates a ho t plasma was no t present in 1973-74 butwas seen by Voyager 1. The sulfur apparently originatesin Io's volcanoes.
a Plasma electron densities in some regionsof the 1otorus exceeded 4,500 per cubic centimeter.
* A somewhat cooler plasma, rotating with Jupiter,was discovered inside six Jupiter radii (428,000 km or266,000 mi.) from the planet. Ions of sulfur, oxygen andperhaps sulfur dioxide were detected.
* High-energy trapped part icles were also detected inth e same region near Jupiter. They had s igni f icant lyenhanced abundances of oxygen, sodium and sulfur.
* A hot plasma was measured near the Jovian magneto-pause (the outer edge of the magnetosphere), composedmostly of protons, oxygen and sulfur.
e Kilometric radio emissions were detected comingfrom Jupiter. The emissions, in the frequency range from10 kilohertz to 1 megahertz, may result from plasmaoscillations in the lo torus.1 - moorei, ., . , ,,, u ,IS
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O Plasma flows were detected in the dayside outermagnetosphere; they rotate with the planet at a 10-hourperiod.
*Voyger saw evidence of the transition from'.osed magnetic field lines to a magnetotail of the anti-
solar side of Jupiter. Although such a magnetotail wasnever in serious question, its existence never had beendetected.
* Whistler emissions were detected that are inter-preted as lightning whistlers from the Jovian atmosphere.
* Voyager also measured radio spectral arcs (fromabout 1 megahertz to more than 30 megahertz) in patternsthat correlate with Jovian longitude.
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JUPITER SCIENCE OBJECTIVES
Voyager l's science experiments at Jupiter fall intothree broad classifications:
* Jupiter's atmosphere and its dynamics includinglightning, studied by:
- Imaging;
- Infrared interferometer spectrometer andradiometer;
- Ultraviolet spectrometer;
- Photopolarimeter;
- Radio science.
* Five of the satellites of Jupiter - Io, Europa,Ganymede, Callisto and Amalthea, studied by:
- Imaging;
- Infared interferometer spectrometer andradiometer;
- Ultraviolet spectrometer;
- Photopolarimeter.
* Jupi te r ' s magnetic field and radiat ion environmentsand i t s interact ion with th e solar wind and the satellites,studied by:
- Plasma;
- Low-energy charged particles;
- Cosmic ray;
- Magnetometers;
- Planetary radio astronomy;
- Plasma wave;
- Radio science;
- Ult rav io le t spect rometer ;- Photopo la r imve te r.
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Magnetic Fields Investigation
The magnetic field of a planet is an externally measure-able indication of conditions deep within it s interior. Fourmagnetometers aboard Voyager 1 gather data on the planetarymagnetic fields at Jupiter, the satellites, solar wind andsatellite interactions with the planetary field, and the inter-planetary (solar) magnetic field.
The magnetometers reveal a great deal about the inter-planetary medium -- the tenuous, ionized an d magnetized ga sthat forms the solar wind.
The Sun constantly emits electrically charged particles-- mostly protons and electrons -- from th e ionization of hydro-gen. Those particles are in the fourth state of matter, calledplasma (the other three states are solid, liquid and neutralgas). The plasma is of extremely low density (less than 100particles per cubic centimeter); it fills all interplanetaryspace and forms the solar wind. Because it is ionized, thesolar wind is an electrically conducting medium.
The solar wind is deflected by planetary magnetic fields(such as the Earth's and Jupiter's), and streams around and
past the obstacle, confining the planet's magnetic field to aregion called the magnetosphere.
The shape of Jupiter's magnetic field is not very wellunderstood. Because Voyager 1 and Voyager 2 arrive four monthsapart, scientists can make long-term, continuous measurementsof the solar wind near Jupiter and of the magnetosphere itselfas it changes size and shape under changing pressure of thesolar wind.
Jupiter's magnetic field is shaped much differently fromEarth's. The planet's rapid rotation rate ma y be one explana-tion (the magnetic field rotates with the planet). At greatdistances from the planet, the magnetic field lines appear toform a spiral structure.
Interactions between the large satellitesand Jupiter'smagnetosphere depend on the properties of the satellite and its
ionosphere, on the characteristics of the field-and-particleenvironment and on the properties of Jupiter's ionosphere.
A strong factor in the choice of Voyager l's flight pathwas the desire to observe the region of interaction betweenJupiter and the satellite Io, called the flux tube. The fluxtube is defined by the magnetic lines of force from Jupiter thatpass through Io. An electric current of 5 million amperes wasmeasured in the flux tube by Voyager 1, producing dramatic effects.
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Voyager 1 passed near the Io flux tube about 20,000 km I(12,750 mi.) from the satellite. It wa s targeted to fly through ihe tube, but missedit because th e stronger-thaa-expected cur-rent twisted the flux tube away from its anticiplted location.(A current of 1 million amperes had been predicted.-)
Jupiter emits decametric radio bursts (from 10 to 40megahertz) that are probably connected with plasma instabili-ies within Jupiter's ionosphere. Io appearF to have someinfluence on those radio emissions by way of the flux tube.
Cosmic Ra v Investigation
Cosmic rays are the most energetic particles -La natureand are atomic nuclei, primarily protonsand electrons. Theycomprise all natural elements known to man. Over certain energyranges and at certain periods of time, the content of cosmicrays is similar in proportion to that of all the matter in thesolar system. Generally, however, their composition varies sig-nificantly with energy, indicating to scientists that a varietyof astrophysical sources and processes contributes to theirnumbers.
Cosmic rays may, as we search for their origins, tellmuch about the solar system and its origins and processes.Cosmic rays are material samples of the galaxy and can tell usmuch about ho w stars synthesize the various elements in theirinteriors.
Voyager's cosmic ra y instrument concentrates on the energycontent, origin and acceleration process, life history and dy-namics of cosmic rays, and measured the anomalous oxygen, sodiumand sulfur inside the orbit of Io.
Planetary Radio Astronomy
One discovery of the planetary radio astronomy experiment(along with several other instruments) is lightning in Jupiter'satmosphere; lightning has been postulated as a catalyst for theformation of life. Together with the plasma wave experiment andseveral optical instruments, Voyager l's planetary radio astronomydemonstrated the existence of lightning on Jupiter. Voyager 2will continue those studies.
A current theory says that lightning in an atmosphere ofhydrogen, methane, ammonia and water can set off reactions thateventually form complex organic molecules.
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The planetary radio astronomy measures radio emissionsfrom J u p i t e r in the low-frequency range from 20 kilohertz to40.5 megahertz. (A M radio s ta t ions broadcas t at frequenciesbetween 550 and 1,600 ki loher tz . ) Scien t i s t s say emissionsranging in wavelength from less than one centimeter to thou-sands of meters can result from wave-particle-plasma inter-action in th e magnetosphere and ionosphere of Jupiter.
While scientists ar e sure Io plays an important role inthe pattern of Jupiter's radio emissions, this big satelliteappears not to have anything at al l to do with Jupiter's 1megahertz emissions, at least in th e low-frequency ranges. Pre-liminary results from Voyager 1 data show no correlation'between1 megahertz bursts an d Io in the low frequencies.
Infrared Interferometer Spectrometer an d Radiometer
Jupiter, with it s colorful and distinctive bands of clouds,has puzzled scientists fo r centuries: Why are the bands (lightzones and dark belts) so well defined? What gives them theircolor? How deep is th e cloud cover? What lies beneath it ?
Voyager's infrared interferometer spectrometer and radio-meter is designed to probe the atmosphere fo r answers to thosequestions. It also explores Jupiter's satellites.
Each chemical compound ha s a unique spectral character. i
By measuring th e infrared an d visible radiation given off andreflected by an object, scientists ca n learn a great deal aboutatmospheric gas composition, abundance, clouds, haze, tempera-tures, dynamics an d heat balance.
Hydrogen, deuterium (heavy hydrogen), helium, methane,ammonia, ethane and acetylene have been identified in Jupiter satmosphere above the upper clouds. Deeper measurements --through holes in th e clouds -- indicate th e presence of water,deuterated methane, germane an d phosphene.
Once th e composition of an atmosphere is determined,knowledge of it s absorption properties can be used to measurethe temperature at various depths as it changes with pressure.
Jupiter's clouds appear to form well-defined layers inthe atmosphere; above the clouds is a tenuous haze. The easewith which those structures absorb or emit infrared radiation. nd light permits determination of cloud depth an d state (i.e.,ic e or aerosol).
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Jupiter's bands have been observed fcr centuries. Whyhave they persisted so long? Most theories explain the bandsas a result of convection -- circulation up andl down -- ofwarm and cool air. Jupiter appears to have an internal heatsource, and a relation appears to exist between cloud colorand temperature in th e zones an d belts.
Satellit. composition and temperature maps are beingconstructed using the distinctive- spectral signatures of icesand minerals found on the surfaces. The infrared instrumentalso measured several ho t spots on Io related to volcanicactivity. Together with pictures of the satellites, the mapsare used to study th e geology and evolution of the bodies, andhow they differ with distance from Jupiter.
Photopolarimeter
By studying the ways sunlight is scattered by the atmos-phere of Jupiter and the surfaces of its satellites, Voyager'sphotopolarimeter can answer many questions about those bodies.
Eight wavelengths in the ultraviolet and visible regionsof the spectrum (from 2,350 to 7,500 Angstroms) are measured inintensity to determine the physical properties of the atmosphereof Jupiter, the satellite surfaces and the sodium cloud and sul-fur torus of Io.
Th e photopolarimeter examines both the large-scale and
micro-scale structure and properties of the clouds of Jupiter.It measures the vertical distribution of cloud particles, andthe particle size and shape, and provides inferences on atmos-pheric composition.
Similar studies define the structures of major planetaryfeatures such as the Great Red Spot, zones and belts. Thephotopolarimeter searches for evidence of crystalline particlesin those features and will gather data on the effects of scat-tering and absorption of sunlight by the particles.
Jupiter's atmosphere will be compared with others thatar e already fairly well known -- those of Earth an d Venus.
The photopolarimeter studies the density of atmospheresat the satellites (if atmospheres exist there), the texture andcomposition of the surfaces, th e bulk reflectivity and the sodiumcloud and sulfur torus of Io.
The spectral reflectivity of a body can help determineits 3urface composition, whether it is rock, dust, frost, iceor the remains of meteors.
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In 1973 scientists first suggested that gases escapingfrom a satellite atmosphere might no t be able to escape thegravity f ield-of th e main planet and would form donut-shapedclouds around th e planet.
That kind of cloud has been found in the vicinity of lo;it is composed primarily of sodiumn and ionized sulfur, oxygenan d perhaps sulfur dioxide.
Io appears to be covered with evaporite salts, includingatomic hydrogen, sodium, potassium and sulfur and perhaps, mag-nesium, calcium and silicon. Materials appear to be spewed outin -near-continuous volcanic eruptions and ma y be sputtered offlo's surface by charged atomic particles trapped in Jupiter'sstrong magnetic field.
Radio Science
The radio tha t provides tracking and communication withVoyager also explores the planets and space.
Changes in frequency, phase, delay, intensity an d polari-zation of radio signals between spacecraft and Earth provideinformation about the space between the two and forces thataffect the spacecraft and alter its path.
When the spacecraft moves behind a body as viewed from
Earth (called occultation), radio waves coming from the space-craft pass through the ionosphere and atmosphere on their wayEarthward. Changes in signal characteristics during thoseevents give information about the vertical structure of theionosphere, atmosphere, clouds and turbulence.
Imaging
Astronomers have photographed Jupiter since at least thelate 1800s, starting first at Lick Observatory and continuinglater at Lowell Observatory. Until about 1960, photography ofJupiter was conducted in a more-or-less random way: if th e
night was clear and sometime wa s available at th e telescope
and someone was inclined, he might take a picture of Jupiter;the next opportunity might no t come for weeks.
That will work fo r an object l ike th e Moon or Mars, butJupiter is al l weather -- every observation ever made of theplanet is of weather and weather patterns; there is nothingelse to see.
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Random photos of Jupiter amount to little more than takingan occasional picture of some clouds somewhere on Earth and thentrying to forecast the weather. It doesn't give yo u much goodinformat ion.
In the early 1960s, astronomers began a ne w routine -an observation program in which they took pictures of Jupiterevery hour al l night long, on every night that was good forobserving. Many of those pictures were of poor quality -- fa rfrom th e textbook examples.
But they contain a wealth of information. In 10 yearsastronomers learned more about Jupiter than they had learned inall the time that preceded the ne w program.
They discovered, for example, that there is a periodicoscillation in the movement of Jupiter's Great Red Spot; th espot moves slowly around Jupiter (it isn't anchored at onelongitude). But the spot does not wander smoothly; it moves,then stops, then moves again. These oscillations occur almostprecisely every 90 days.
Another discovery: Th e Great Red Spot is no t a smoothblemish, bu t is a giant vortex (it has been compared with ahurricane on Earth). Observers do no t know if the vortexphenomenon exists al l the time or only occasionally.
A third example: There appears to be a semipersistenthigh-velocity je t stream at a constant latitude in Jupiter'snorthern hemisphere. The current flows in the same directionas Jupitc rotates. Planetary observers have measured thevelocity of the winds at 612 km/hr (380 mph).
But for its velocity, that jet stream resembles th e samephenomenon on Earth; Earth's stream meanders north and south,carrying storms from the tropics to temperate latitudes andfrom the Arctic southward. Bu t Jupiter's rapid rotation (aday is less than 10 hours long) nails the northern stream toone constant latitude.
There are many more fascinating features like these onJupiter. But even though astronomers try to photograph theplanet every hour, every night, they are at the mercy of Earth'sbubbling, boiling atmosphere and the material in it. Often ob -servers have seen "something" there, but have been unable toidentify it: ground-based pictures cannot answer the flood ofquestions scientists ask about the planet.
That is why Voyager observations are so important.
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While the two Pioneer spacecraft saw Jupiter at high-resolution for only a few days -- and thereby took a snapshotof th e planet -- th e two Voyagers have taken many thousands ofhigh-resolution pictures of Jupiter for almost eight months.
That is enough to provide a significant advance in ourknowledge of the planet.
The satellites, meanwhile, are another story. They arebodies the size of the Moon and the planet Mercury that cannotbe clearly seen from Earth because they are too far away. OneEarth-based photo of Io suggests an orange hue at the poles anda whitish appearance near the equator. A picture of Ganymedetaken by on e of th e Pioneers suggests mottling on the surface.
But th e Galilean satellites' discs are only 1/25th theapparent diameter of the planet Mars, and 1/12th the size ofthe planet Mercury in the eyepiece of a telescope. They are,one scientist says, too small to show anything that can be takenseriously.
So, before Voyager 1, no one knew what those big, moon-sized objects looked like. Scientists were surprised by thesatellite pictures from Voyager.
Io, for example, has a surface covered with volcanoesbu t with no meteoritic impact craters. Europa's surface isprobably covered with ice, bu t no one knows the depth. If theice is a few centimeters thick, Europa may look like Earth'sMoon covered with snow. However, scientists have no idea whatits surface ma y look like if the ice is tens of meters or evenkilometers thick. Europa's surface, photographed at low reso-lution by Voyager 1, will be seen close-up by Voyager 2.
Ganymede and Callisto are thought to be composed of almostone-half ice. But they must contain some silicates, and theysurely contain some radioactive material -- therefore, there issome internal heat. Ho w does that heat reach the surface?Uniformly? Or in convection cells as happens on Earth?
Impact craters cover the icy satellites. Bu t ice flows,and in a relatively short time the scars fade; Ganymede's hugering basins show very little topographic relief.
Finally there is an Earth application for the new know-ledge from the Voyager images of Jupiter:
Th e inner planets -- Venus, Earth and Mars -- have atmos-pheres dominated by solar heat that arrives at the equator andflows by a variety of methods toward the poles. The equator,
therefore, s hotter than the mores.I_____---- ore-la @ i H S i tV
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But Jupiter is no t that way. Jupiter's atmospheric tem-perature does no t appear to be dependent on latitude. There'sa lo t of heat moving from within Jlipiter to the surface -- with-out any regard fo r where th e equator is or th e poles or evenwhere th e Sun is. It wells up uniformly everywhere.
On Earth one region is different from a ll th e r e s t . Itis a convective region called th e Intertropical ConvergenceZone. In that region near the equator, warm, moist air wellsup to high altitudes. The moisture is condensed out of the airwhich then becomes very dry and cold. That dry, cold ai r movesoutward an d descends again, warming as it does. On either sideof the Intertropical Convergence Zone, where th e dry ai r reachesth e surface, there is an arid, nearly useless desert. NorthAfrica is the classic example. Th e zone is a region wherenature's forces overwhelm man's efforts.
There is a similarity, then, between Earth and Jupiter --one that may allow scientists studying the tw o planets toassist each other.
Low-Energy Charged Part icles
The low-energy charged part icle instrument is a strongcoupling factor in Voyager's complement of fields an d particlesinvestigations, contributing to many areas of interest, includ-ing the solar wind, solar flares, particle accelerations, mag-netic fields, cosmic rays an d satellite surface structure.
Two detectors allow measurements during the long inter-planetary cruise and the encounters. Th e wide dynamic range;combined with wide coverage in energy and species, allows charac-terization of almost al l energetic particle environments thatVoyager traverses.
The experiment measures particles traveling 2,400 to morethan 150,000 km (1,500 to more than 90,000 mi.) a second. (High-energy particles travel at or near the speed of light -- 299,792km a second or 186,282 mi. a second.)
Observations of particle accelerations aid in better under-standing of solar flare processes, cosmic ray accelerations, andprocesses in Earth's magnetosphere.
Next to tbe Sun, Jupiter is the solar system's most powerfulradio source. Th e reasons for that ar e no t understood completely,but may come, in part, from the interaction between Jupiter and1o. The Io-Jupiter interaction could be of importance in under-standing other astrophysical radio sources.
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Plasma Experiment
When th e atoms of chemical elements are broken apart intoelectrons and protons, the resulting gas is called a plasma.Measuring the plasmia that surrounds the spacecraft is a goodway to obtain information about the magnetic field through whichVoyager travels and the material flowing outward from th e Sun.
Traveling at supersonic speed (average 400 km or 250 mi.a second), plasma streams in al l directions from the Sun, form-ing the solar wind. When the solar wind reacts with Earthismagnetic field, many phenomena result, such as the northernlights and geomagnetic storms. Similar events have been observedat other planets.
Voyager's plasma experiment measures plasma propertiesincluding velocity, density and temperature for a wide rangeof flow directions in the solar wind and planetary magnetospheres.
At Jupiter, the plasma team will study the interaction ofthe solar wind with Jupiter; tL _ sources, properties, forms andstructure of Jupiter's magnetospheric plasma; and the interactionof the magnetospheric plasma with the Galilean satellites.
Io, second satellite from Jupiter (tiny Amalthea isclosest) is known to be a source of ionized sulfur an d oxygenthat form a donut-shaped ring close to Io's orbit.
It is possible, too, that Ganymede, fourth satellite ou tfrom Jupiter (Europa orbits between Io and Ganymede), has aring of neutral particles that serve as a source for ions inth e Jovian magnetosphere, If that is the case, the plasmainstrument should detect some of those ions when Voyager isnear Ganymede's orbit.
Jupiter's magnetosphere extends into space at least 100times the planetary radius. Since Jupiter's radius is about71,400 km (44,000 mi.), that places the leading edge of themagnetosphere about 7 million km (4,349,600 mi.) or fartherfrom the planet. That distance appears typical for a quietmagnetosphere. On at least seven occasions the magnetopause --
edge of the magnetic field -- was found at varying distance, asclose as 43 planetary radii, less than half the maximum distance.The magnetosphere is compressed when the solar wind's pressureincreases.
During Voyager l's encounter with Jupiter, the pressureof the solar wind at Jupiter and the size of Jupiter's magneto-sphere wa s predicted using data from Voyager 2 -- farther fromJupiter and closer to the Sun.
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By comparing data from both spacecraft during theVoyager 1 encounter, scientists showed how the Jovian mag-netosphere reacts to changes in the incoming solar wind.
Voyager 2's encounter with Jupiter's magnetosphere willbe detected when the spacecraft crosses the bo w shock wave, aregion of demarcation between the solar wind and the Jupiterenvironment.
Immediately behind the bo w shock is a transition regioncalled the magnetosheath that separates the solar wind fromthe magnetosphere. The inner boundary of the macnetosheath,the magnetopause, separates the modified solar wind plasma inthe Jovian magnetosheath from the plasma in the magnetosphereproper. Plasma in the magnetosheath slows down and is heatedby passage through the bow shock. Plasma in the magnetospherecomes from several sources -- Jupiter's ionosphere, ions fromsatellite surfaces and atmospheres and the solar wind.
In the inner magnetosphere, plasma trapped by the mag-netic field is forced to rotate with the planet. This regionof corotation ma y extend as far as the magnetopause; the far-ther from the planet, the more the centrifugal force causesstretching of the magnetic field lines, more or less parallelto Jupiter's equator.
The stretched field lines form a thin disk that confinesthe particles within an intense, thin sheet of current flowing
around the planet.
Plasma Wave Experiment
Voyager 2 is surrounded by a low-density, ionized gascalled a plasma. That plasma, composed entirely of atoms thatare broken apart into electrons and charged positive ions, isa good electrical conductor with properties that are stronglyaffected by magnetic fields.
Plasma sources include the Sun, the planets and perhapssome of their satellites. Low-density plasmas are unusual.;ordinary collisions between ions are unimportant, and individualions and electrons interact with the rest of the plasma by meansof emission and absorption of waves.
Localized interactions between waves and particlesstrongly control the dynamics of the entire plasma medium,and Voyager's plasma wave instrument provides the first mea-surements of these phenomena at the outer planets.
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Plasma waves are low-frequency oscillations that havetheir origins in instabilities within the plasma: They areof two types -- electrostatic oscillations (similar to soundwaves) or electromagnetic waves of very low frequency.
The plasma wave instrument measures the electric fieldcomponent between 10 and 56,000 hertz. By way of comparison,Voyager's magnetometers measure the magnetic vectors of elec-tromagnetic plasma waves below 10 hertz, while the planetaryradio astronomy instrument measures waves with frequenciesabove 20 kilohertz.
Plasma ions and electrons emit and absorb plasma waves.While the resulting particle-wave interactions affect the mag-netospheric dynamics of the outer planets and the propertiesof the distant interplanetary medium, they have never beendirectly observed in those regions, since plasma waves cannotgenerally be observed far from their source and since therehave been no previous wave studies at the outer planets.
Voyager is, therefore, returning the first direct obser-vations of wave-particle interactions at great distances fromthe Sun. Some effects to be studied include heating of solarwind particles at the outer planet bow shocks, acceleration ofsolar wind particles that produce high-energy trapped radia-tion, and the maintenance of boundaries between the rotatinginner magnetospheres and the solar wind streaming around theplanets.
Another objective of th e plasma wave experiment is tostudy the influence of wave-particle effects on the inter-actions between the inner satellites and the planet's rapidlyrotating magnetosphere.
Control of Jupiter's decametric radio bursts throughcoupling of lo's ionosphere with Jupiter's magnetic field isan example.
As Io moves through Jupiter's magnetic field, it producescurrent flow along the magnetic field lines connecting Io toJupiter (the flux tube).
Detection of lightning bolts in the atmosphere of Jupiterwas a significant discovery of the plasma wave instrument. Theinstrument detects audible whistler signals that escape intothe magnetosphere from lightning discharges.
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The descending-scale whistle that is characteristic oflightning is caused by scattering of similar velocitieswhenthe direction of travel is along magnetic lines of force:higher frequencies arrive at the receiver sooner than lowerfrequencies. Using the high-rate telemetry usually reservedfor transmission of imaging data, the plasma wave instrumentplays to Earth the entire audio signal of space -- plasma waves,spacecraft power, thruster firing and other instruments.
Ultraviolet Spectrometer
Voyager's ultraviolet spectrometer will study the compo-sition and structure of Jupiter's atmosphere an d the materialsurrounding several satellites.
Two techniques have been developed to probe a planet'satmosphere without entering that atmosphere:
* Airglow observations require a large area fo r maximumsensitivity to the weak emissions high in the atmosphere --where collisons between atoms and molecules are rare.* Occultation measurements require an instrument thatlooks at the Sun, reading its ultraviolet radiation to measureabsorption and scattering by the planet's atmosphere as thespacecraft moves into shadow.
Airglow observations measure atomic hydrogen and heliumin the upper atmosphere by recording the resonance scatteringof sunlight. Resonance scattering is what happens when atomsand molecules absorb solar ultraviolet at specific wavelengthsand reradiate at the same wavelengths. That differs fromfluorescence, in which the activating wavelength is absorbedand energy is reemitted at different wavelengths. Auroral-typeemissions were also observed at Jupiter -- on both day and nightsides of the planet.
As the spacecraft disappears behind Jupiter, th e planet'satmosphere passes between the Sun and the ultraviolet spectro-meter. Since the gases that make up an atmospherehave identi-fiable absorption characteristics at short wavelengths, theultraviolet spectrometer can measure how much of each gas ispresent at what temperature.
The important point is no t how much sunlight enters theatmosphere, but what happens to it after *' enters -- how itis absorbed and scattered.
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4A - 39 -
THE PLANET JUPITER
Everything about Jupi ter is enormous: when the solarsystem formed, 78 pe r cent of the material that did not endup in the Sun went to make Jupiter.,
Jupiter is the fifth planet from the Sun. It com-pletes one orbit every 11.86 Earth years.
A day on Jupiter is complete in 9 hours, 55 minutesand 30 seconds. Th e extremely rapid rotation caused theplanet to be flattened at the poles: equatorial radius is71,600 km (44,490 mi.), and the polar radius is 67,000 km (41,632 mi.)
Jupiter has 13 known satellites; a 14th ma y have beenseen by Charles T. Kowal of Caltech, wh o also found the13th in 1974. The four largest satellites were discoveredby the first ma n to aim a telescope at Jupiter -- GalileoGalilei in 1609-10. Galileo's discovery that Jupiter hassatellites provided evidence that the Copernican theory of thesolar system was correct and that Earth is not the center.The four satellites discovered by Galileo (grouped togetherand called the Galilean satellites) are Io, Europa, Ganymedeand Callisto. All range in size from the planet Mercury tothe Moon. All are being studied by the Voyagers.
Jupiter is comprosed primarily of hydrogen. Indeed,it is so massive that very little of its original materialcould have escaped in the 4.6 billion years since it formed.The second most abundant element in Jupiter is helium. Theratio of hydrogen to helium on Jupiter is about the same asin the Sun. The solar ratio is roughly one atom of heliumfor iO molecules -if ydrogen.
Three other substances have been identified spectro-scopically: ammonia, methane and water. The presence of hy-drogen sulfide has been inferred.
The currently popular model of Jupiter's structure be-gins with a small molten iron-silicate core only a fewthousand kilometers in diameter. The core is inferred be-cause cosmic abundances of the elements include small amountsof iron and silicates. The temperature there is thought to beabout 30,000 degrees K (53,000 degrees F).
Surrounding the suspected core is a thick layer inwhich hydrogen is the most abundant element. The hydrogenis separated into two layers.
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In both it is liquid, but in different states: th einner layer, about 46,000 km (28,500 mi.) radius, is liquidmetallic hydrogen, which means that the hydrogen is electri-cally conductive like ordinary metals. That form of hydro-
gen ha s not been observed in laboratories since it requiresimmense heat and pressure. On Jupiter it is thought toexist at temperatures around 11,000 degr~ees K (19,300 degreesF) an d at pressures about 3 million times Earth's sea-levelatmosphere.
The next layer -- liquid hydrogen in it s molecularform -- extends to about 70,000 km (43,500 mi.). Abovethat layer, reaching to the cloud tops fo r another, 1,000km (620 mi.) is th e atmosphere.
if th e model is correct, Jupiter has no solid surface,but exists as a rapidly spinning ball of ga s an d liquid al -most 779 million km (484 milliom
mi.) from th e Sun.One of th e puzzles about Jupiter is the fact that it
radiates about tw o an d a half times th e amount of heat thatit receives from th e Sun. Early models postulated nuclearreactions inside th e planet, or heat from gravitational con-traction. These ideas are no longer believed likely.
Because Jupiter is to o small an d to o cold to generatenuclear reactions, scientists now believe th e excess heatbeing radiated by th e planet is stored heat left over fromth e primordial heat generated when th e planet coalesced outof th e solar nebula.
The visible surface of Jupiter consists of bands ofclouds, alternating dark and light. The bands appear to beconvection cells that ar e stretched by Coriolis forces cre-ated by the planet's rapid rotation. By convention, th elight features ar e called zones an d th e dark ones belts.Th e light zones appear to be regions of greater altitudean d cooler temperatures than th e dark belts. Ga s wairmed byth e planet's internal heat rises an d cools in th e upper at -mosphere and forms clouds of ammonia crystals suspended ingaseous hydrogen. At th e top of the zones, th e cooler ma-terial moves towazd th e equator or the poles, is deflectedin an east-west direction by Coriolis forces, an d then sinksback to lower altitudes. A similar but much smaller mechanismon Earth caused th e Trade Winds.
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One of the most prominent features on Jupiter is theGreat Red Spot. It has been observed almost constantly since
its discovery 300 years ago by Giovanni Domenico Cassini.Its width is almost always about 14,000 km (8,700 mi.), but
it s length varies between 30,000 km (18,600 mi.) and 40,000km (24,800 mi.)
The Great Red Spot appears to resemble an immense hurri-
cane of Earth -- although it is much larger and has lasted
much longer than any terrestrial storms. At one time scien-
tists believed it might be a phenomenon known as TaylorColumin -- a standing wave above a mountain or depression on
the surface. But the current model of Jupiter has no solidsurface, and the Great Red Spot has wandered in longitudeseveral times around the planet.
Other spots have been observed in the Jovian atmospherethat are similar to but much smaller than the Great Red
Spot. They, too, appear in the equatorial regions, buthave relatively short lifetimes; the one most recently ob-
served lasted just under two years.
Radio astronomers found evidence for a magnetic field
around Jupiter during observations in the 1950s, when they
discovered radio-frequency emissions coming from the planet.
The emissions are confined to two regions of the spectrum -
with wavelengths measured in te-ns of meters (decametric) And
in tenths of meters (decimetric). Another radio-noise con-
tribution comes from non-thermal mechanisms that depend on
the planet's magnetic field. This "synchrotron radiation"comes from electrozns that uove near the speed of light.
The satellite Io appears to have some link with thedecametric radiation, since the bursts seem to occur when Iocrosses the face of Jupiter. All radio emmissions from
Jupiter are associated with rotation of the planet's mag-netic field.
While the Jovian magnetic field is essentially dipolar
(north and south, like Earth's), its direction is opposite
Earth's (the needle of a compass on Jupiter would point
south).
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a r i de
The axis of the field is offset about 10.8 degreesfrom
the the rotational axis, and the center of the axis is off-
set from the center o2 the planet by about cne-tenth of a
Jupiter radius. At the planet's cloud tops th e field ranges
between 3 and 14 gauss (Earth's magnetic field at the sur-
face averages about one-half gauss).
The shape cf Jupiter's magnetic field is about the
same as Earth's with some significant differences: the
movement of energetic particles near the equator is intense,
bu t at higher latitudes falls of f dramatically. There is
apparently an electric-current sheet along the magnetic
equator that traps and holds particles there.
The five inner satellites of Jupiter affect distribu-
tion of charged particles; as the satellites orbit Jupiter
they sweep particles ou t of their wa y and at the same time
acquire intense radioactivity.
Jupiter's outer magnetosphere is highly variable in
size, possibly due to changes in the solar-wind pressure;
Voyager 1 flew in and ou t of the magnetosphere five times
on its inbound leg.
High-energy electrons have also been observed in another
unexpected place: ahead of the bo w shock wave in interplane-
tary space. Scientists believe high-energy particles in
Jupiter's magnetosphere reach such velocity that they can
escape. Reexamination of records from Earth satellites turned
up the fact that these electrons has been observed for many
years. They were believed, however, to be of cosmic origin.
No w scientists think they spin down thesolar magnetic-
field lines and intersect Earth, since their peaks occur
every 13 months when Earth and Jupiter are connected by the
spiral lines of the interplanetary magnetic field.
Jupiter's satellites fall into three groups -- thelarge inner bodies, then a group of four that are small,
and a final group, also four in number, that are far distant
and have retrograde orbits.
The five inner satellites are Amalthea .- the smallest --about 265 km (164 mi.) by 140 km (87 mi.); Io, about the
size of Earth's moon; Europa, Ganymede and Callisto.
All the outer satellites appear to be very differentfrom the inner group. They are probably asteroids cap-
tured by Jupiter's gravity or the may be the remains of
broken up satellites.
Their orbits are fairly highly inclined (25 to 28 de-
grees from the equatorial plane), and the outermost four
Puraue retrograde paths.
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THE SATELLITES OF JUPITERPeriodDistance
Diameter Distance Cdays, hoursName (km, mi.) (km, mi.) min. sec.)
Amalthea (V) 240 (149) 181,500 llh57m22.7s(112,779)
Io (I; 3,636 (2,259) 422,000 1 d 1 8 h 27 m3 3 .5S(262,219)
Europa (II) 3,066 (1,905) 671,400 3d13 13m42s(417,189)
Ganymede (III) 5,216 (3,241) 1,071,000 7 d 3 h 4 2 m3 3s(665,489)
Callisto (IV) 4,890 (3,039) 1,884,000 16 d 1 6 h 3 2 11.21.170,663)
Leda (XIII) 7 (est.) (4) 11,094,000 2 3 8 . 7 d(6,893,492)
Himalia (VI) 170 (106) 11,487,000 250 57d(7,137,691)
Elara (VII) 80 (50) 11,747,000 259.65d(7,299,247)
Lysithea (X) 14 (est.) (9) 11,861,000 263.55d(7,370,084)
Ananke (XII) 14 (est.) 21,250,000 6 31 d(13,204,137)
Carme (XI) 14 (est.) 22,540,000 6 9 2 d(14,005,706)
Pasiphae (VIII) 16 (est.) (10) 23,510,000 7 3 9 d{ (14,608,436)
Sinope (IX) 14 (est.) 23,670,000 758d
(14,707,856)
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r'i --
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PLANET COMPARISON
Earth Jupiter Saturn
Radius 6,37- km 71,400 km 59,800 km(Equatorial) (3,963 mi.) (44,366 mi.) (37,158 mi.)
Satellites 1 14(?) 10 (?)
Year i 11.86 29.46
Day2 4 h 9 h 55m 33s 10 h 26 m (?)
Mass 1 317.9 95
Gravity 1 2.61 0.9
I Mean distance 1 AU 5.203 AU 9.523 AUfrom Su n
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VOYAGER SCIENCE INVESTIGATORS
Imaging Science
Bradford A. Smith, University of Arizona, team leader
Geoffrey A. Briggs, National Aeronautics and Space Administration
Allan F. Cook II, Smithsonian Institution
G. Edward Danielson Jr., California Institute of Technology
Merton E. Davies, Rand Corp.
Garry E. Hunt, University College London
Tobias Owen, State University of New York at Stony Brook
Carl Sagan, Cornell University
Laurence A. Soderblom, U;S, Geological Survey
Verner E. Suomi, University of Wisconsin
Harold Masursky, U.S. Geological Survey
Radio Science
Von R. Eshleman, Stanford University, team leader
John D. Anderson, Jet Propulsion Laboratory
Tom A. Croft, SR I International
Gunnar Lindal, Jet Propulsion Laboratory
Gerald S. Levy, Jet Propulsion Laboratory
G. Len Tyler, Stanford University
Gorden E. Wood, Jet Propulsion Laboratory
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Plasma Wave
Frederick L. Scarf, TR W Systems, principal investigator
Donald A. Gurnett,University of Iowa
Infrared Radiometry 'ad Spedtr~scopy
Rudolf A. Hanel, Goddard Space Flight Center,principal invest igator
Barney J. Conrath, Goddard Space Flight CenterP. Gierasch, Cornell University
Dan Gautier, Meudon,France
S. Kumar, Je t Propulsion LaboratoryVirgil G. Kunde, Goddard Space Flight CenterP.D. Lowman, Goddard Space Flight Center
William C. Maguire, Goddard Space Flight Center
John C. Pearl, Goddard Space Fl igh t Center
Joseph A. Pirraglia, Goddard Space Flight Center
Cyril Ponnamperuma, University of Maryland
Robert F. Samuelson, Goddard Space Flight Center
Ultraviolet Spectroscopy
A. Lyle Broadfoot, Kitt Peak National Observatory,principal investigator
Jean L. Bertaux, Service d'Aeronomie du CNRS
Jacques Blamornt, Service d'Aeronomie du CNRS
Thomas M. Donahue, University of Michigan
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Richard M. Goody, Harvard University
Alexander Dalgarno, Harvard University
Michael B. McElroy, Harvard University
John C. McConnell, York University
R. Warren Moos, Johns Hopkins University
Michael J.S. Belton, Kitt Peak National Observatory
Darrell F. Strobel, Naval Research Laboratory
Sushil K. Atreya, University of Michigan
Bill Sandel, University of Arizona
Donald E. Shemanksy, University of Arizona
Photopolarimetry
Charles W. Hord, University of Colorado, prinicpal investigator
David L. Coffeen, Goddard Institute for Space Studies
James E. Hansen, Goddard Institute fo r Space Studies
Kevin Pang, Science Applications Inc.
Planetary Radio Astronomy
James W. Warwick, University of Colorado; ScienceApplications Inc., principal investigator
Joseph K. Alexander, Goddard Space Flight Center
Andre Boischot, Observatoire de Paris
Walter E. Brown Jr., Je t Propulsion LaboratoryThomas D. Carr, University of Florida
Samuel Gulkis, Je t Propulsion Laboratory
Fred T. Haddock, University of Michigan
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rd M. Goody, Harvard University
nder Dalgarno, Harvard University
el B. McElroy, Harvard University
C. McConnell, York University
arren Moos, Johns Hopkins University
el J.S. Belton, Kitt Peak National Observatory
l F. Strobel, Naval Research Laboratory
K. Atreya, University of Michigan
Sandel, University of Arizona
d E. Shemanksy, University of Arizona
metry
s W. Hord, University of Colorado, prinicpal investigator
L. Coffeen, Goddard Institute for Space Studies
E. Hansen, Goddard Institute for Space Studies
Pang, Science Applications Inc.
Radio Astronomy
W. Warwick, University of Colorado, Sciencelications Inc., principal investigator
h K. Alexander, Goddard Space Flight Center
Boischot, Observatoire de Paris
E. Brown Jr., Jet Propulsion Laboratory
s D. Carr, University of Florida
l Gulkis, Jet Propulsion Laboratory
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Christopher C. Harvey, Observatoire de Paris
Yolande LeBlanc, Observatoirs de Paris
Robert G.Pletzer, University of Colorado
Roger J. Phillips, je t Propulsion Laboratory
David R. Staelin, Massachusetts Institute of Technology
Anthony Riddle, University of Colorado
Jeffrey Pearce, University of Colorado
Magnetic Fields
Norman F. Ness, Goddard Space Flight Center,principal inves