Chandrayaan 1, India's
first deep space mission, successfully entered lunar orbit early Saturday after
a circuitous two-and-a-half week journey from a seaside launch pad to the moon.
The car-sized
spacecraft fired its liquid-fueled engine for 817 seconds to place
Chandrayaan 1 in an oval-shaped parking orbit around the moon with a high point
of 4,662 miles and low point of 313 miles. That orbit will eventually be
lowered to a circular path about 62 miles above the lunar surface.
Engineers monitored the
critical maneuver from the Indian Space Research Organization's Spacecraft
Control Center in Bangalore.
The probe had fired its
engine five times since
its Oct. 22 launch aboard a Polar Satellite Launch Vehicle dispatched from
the Satish Dhawan Space Center on India's east coast. The burns gradually
raised the high point of Chandrayaan 1's orbit from about 14,200 miles to more
than 235,000 miles, according to ISRO.
A graphic depicting the
craft's orbital trek can be seen here.
Controllers also turned on
the probe's main camera at the end of October. The black-and-white stereo
terrain mapping camera took pictures of Earth while zooming away from the
planet.
The spacecraft's other
payloads will be turned on and tested by the end of this month, before the
spacecraft begins an operational mission lasting at least two years, officials
said.
Plans call for Chandrayaan
1 to release a 64-pound impactor around Nov. 15 for a suicidal nosedive into
the moon. The trip from orbit to the lunar surface will take about a half-hour,
and the small craft will relay imagery, altitude information and spectral data
back to Earth through the Chandrayaan mother ship.
Chandrayaan means
"moon craft" in Sanskrit, the ancient language of India.
The $80
million mission is India's answer to a pair of lunar missions launched last
year by Japan and China. Both countries' moon orbiters are still collecting
imagery and scientific data.
But unlike the Japanese and
Chinese missions, India invited large contributions from other nations to put
instruments on Chandrayaan 1. Scientists from Europe and the United States
answered the call.
More than half of the
probe's 11 instruments come from outside India. The European Space Agency spent
$8 million to fund three payloads, while NASA provided two more sensors.
Bulgarian scientists also contributed a radiation monitor to the mission.
Scientists expect data from
Chandrayaan 1 to help create the most detailed global chemical map of the moon
showing mineral concentrations across the lunar surface. Researchers will also
make a three-dimensional terrain map of the moon based on information yielded
by the mission.
"We are going to look
at the moon slightly differently than the people who are looking at it (now).
We're looking at the moon very systematically," said Mylswamy Annadurai,
Chandrayaan 1 project director at ISRO. "We're going to make a repository
of the whole moon and its contents."
ESA's three instruments
come from teams led by scientists in the United Kingdom, Germany and Sweden.
"In an era of renewed
interest for the moon on a worldwide scale, the ESA-ISRO collaboration on
Chandrayaan 1 is a new opportunity for Europe to expand its competence in lunar
science while tightening the long-standing relationship with India an ever
stronger space power," said David Southwood, ESA director of science and
robotic exploration.
The ESA-funded X-ray and
near-infrared imaging spectrometers, called C1XS and SIR 2, will detect mineral
signatures in soil on and just below the lunar surface. Both instruments are
based on similar sensors that flew aboard Europe's SMART 1 spacecraft, which
was deliberately crashed into the moon in 2006.
"European scientists
will have the fantastic opportunity to continue our work on the moon,"
said Detlef Koschny, ESA's Chandrayaan 1 project scientist.
Europe's instruments aboard
Chandrayaan 1 will work closely with other countries' payloads to help fill in
the blanks in what scientists know about the moon.
"The Apollo missions
went down to the surface, but only in a limited number of spots, whereas
Chandrayaan tries to do detailed imaging of the entire sphere of the
moon," said Christian Erd, ESA's Chandrayaan 1 project manager.
SARA, the other ESA
payload, will observe solar wind particles contacting the moon's surface to
study its effects on the top layer of soil.
NASA provided a pair of
instruments, the Moon Mineralogy Mapper and the MiniSAR radar, as part of the
agency's effort to return to robotic exploration of the moon.
"The opportunity to
fly NASA instruments on Chandrayaan 1 undoubtedly will lead to important
scientific discoveries," said Michael Griffin, NASA administrator.
"This exciting collaboration represents an important next step in what we
hope to be a long and mutually beneficial relationship with India in future
civil space exploration."
The Moon Mineralogy Mapper,
nicknamed M3, is a visual and near-infrared imaging spectrometer designed to
plot mineral resources at higher resolutions than any instrument before. M3
scientists from the Jet Propulsion Laboratory hope the device will help them
create mineral maps to find science-rich landing sites for future missions.
M3 will also look for
direct evidence of pockets of water ice hidden inside craters near the lunar
poles. Scientists believe there are frozen water deposits deep within the
eternally dark craters due to high concentrations of hydrogen found there on
previous missions.
The MiniSAR payload was
developed by the Johns Hopkins University Applied Physics Laboratory. The
instrument will bounce radar beams off the lunar surface to look for signs of
water ice packed inside the walls of deep craters near the moon's poles.
The combination of data
from the M3 and MiniSAR instruments will allow researchers to determine how
many craters could harbor the frozen water, NASA officials said.
India's indigenous suite of
science payloads include a terrain camera designed to take detailed
black-and-white pictures of the whole lunar surface. The stereo camera will be
able to spot features as small as about 16 feet, according to ISRO.
ISRO scientists also built
two spectral imagers, one focusing on near-infrared and another in the X-ray
range, to help produce precise global maps of the minerals and soil contents on
the moon's surface.
A laser system was also
bolted to the spacecraft to determine its altitude above the moon and chart
lunar surface topography.
Indian engineers also
constructed the moon impact probe.
"It has been the dream
of Indian scientists to send a satellite around the moon and then collect more
data about the surface features, minerals and so on," Nair said.
"That dream is going to come true through this mission."
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