 Quicktime Movie of PWS Ganymede Audio
One approach scientists use to make sense of the data from instruments
is to make pictures and graphs to represent the data. This is called
"data visualization". Some types of data, especially radio signals, are
very similar in many ways to sound. The power of a radio signal is
analogous to the volume of a sound. The radio signal also varies in
terms of the frequency and wavelength of the radio waves, which is like
the variation in pitch of sound waves. So scientists sometimes translate
radio signals into sound to better understand the signals. This approach
is called "data sonification". Click the button above to hear the sound
that corresponds to this graph.
On June 27, 1996, the Galileo spacecraft made the first flyby of Jupiter's largest moon, Ganymede. The Plasma Wave Experiment
(PWS), using an electric dipole antenna, recorded the signature of a magnetosphere at Ganymede. This is the first example of a
magnetosphere associated with a moon. The PWS data are represented here as both sounds and a rainbow-colored spectrogram.
Approximately 45 minutes of PWS observations are transformed and compressed to 60 seconds. Time increases to the right and
frequency (pitch) increases vertically. Color is used to indicate wave intensity, red corresponding to strong waves, blue corresponding
to weak waves.
The audio track represents the PWS data and is synchronized with the display of the rainbow-colored spectrogram. The pitch of the
sound is reduced by a factor of 9 from the measured frequency and follows the location of the signal on the rainbow-colored
spectrogram. The entrance into the Ganymede magnetosphere is marked by a strong burst of noise about 6-10 seconds into the
recording. As the spacecraft approaches Ganymede, an irregular tone can be heard rising in frequency, reaching a peak and then
declining. The pitch of this tone is a measure of the density of charged particles near Ganymede. Both the plasma wave and
magnetometer data show that a strong magnetic field exists around Ganymede.
More information on the PWS instrument and other Galileo science instruments is available at http://www.jpl.nasa.gov/galileo/instruments/.
Audio of Voyager 1 Crossing Jupiter's Bow Shock
All of the planets are bathed by a hot plasma called the
solar wind which boils off the sun and moves outward at speeds of
a million miles per hour. The planets are a little like supersonic
aircraft in Earth's atmosphere. Should a supersonic jet fly over
your house, you would hear a sonic boom caused by the jet moving
faster than sound waves in the air. Since the solar wind is
moving past the planets at supersonic speeds, a similar 'sonic
boom' is created in the solar wind. The signals in this sound
file were acquired as Voyager 1 was approaching the 'sonic
boom' (or bow shock, as scientists refer to it) of Jupiter. The
chirps heard at the beginning of the interval are waves generated
by electrons coming from the shock and moving 'upstream' into
the approaching solar wind. These soon die out and, except for
a slight hum from one of the science instruments onboard and
the firing of one of Voyager's thrusters (making a short thud)
things become quiet. Then, suddenly, the spacecraft enters
the bow shock and is enveloped by the turbulence in this
planetary 'sonic boom'. The bow shock is nature's way of slowing,
deflecting, and heating the solar wind as it runs into an
object, in this case the Jovian magnetosphere. In fact, the
waves you are hearing are at least partly responsible for
heating the solar wind as it is slowed and deflected around
the magnetosphere.
Audio
of Voyager 2 Passing Through Jupiter's Outer Magnetosphere
These melodious tones are created at a special frequency in
a plasma with a magnetic field. The frequency is set by the number
of electrons in a given volume (the electron density) and the
strength of the magnetic field. Hence, the frequency of these
waves, called upper hybrid waves, can provide a very accurate
measure of the density of the plasma; a fundamental property of
the Jovian environment of interest to scientists. These
emissions were acquired by Voyager 2 as it passed through the
outer magnetosphere in 1979.
Audio
of Jupiter's Lightning Taken By Voyager
While somewhat difficult to hear, this whistling tone provided
Voyager investigators confirmation that there was lightning in
Jupiter's atmosphere. This emission is called a 'whistler'
because of its whistling sound. These have been studied at
Earth for many decades. Whistlers are just one part of the
electromagnetic spectrum of a lightning stroke which happens
to propagate away from the planet, into the magnetized plasma
above. An interesting thing occurs when these waves reach
the plasma; the higher frequency waves travel faster along
the planets magnetic field than the lower frequencies. So,
a satellite detecting these signals some distance from the
planet will first pickup the high frequencies, then the
low ones from an individual lightning stroke, thereby generating
the whistling tone. We know of no other way of producing such
a distinct tone, hence, the discovery of whistlers like this
one at Jupiter provides strong evidence of lightning there.
At about the same time, Voyager's cameras took time exposures
of the dark side of Jupiter and saw regions of light which
have been identified as clouds momentarily lit by lightning
within them. So, the plasma wave instrument and cameras
together provided the first definitive evidence for lightning at
a planet other than Earth.
Additional details of the PWS instrument and PWS science can be found at http://www-pw.physics.uiowa.edu/plasma-wave/galileo/home.html |
