August 12th 05, 08:44 PM
The Johns Hopkins University Applied Physics Laboratory
Office of Communications and Public Affairs
Laurel, Maryland
Media contact: Michael Buckley
(240) 228 7536 or (443) 778 7536
August 12, 2005
FOR IMMEDIATE RELEASE
POWERFUL MINERAL MAPPER HEADED TO MARS
APL-Built Spectrometer on NASA's Latest Mission to the Red Planet
With today's launch of NASA's Mars Reconnaissance Orbiter spacecraft
from
Cape Canaveral Air Force Station, Fla., the Compact Reconnaissance
Imaging
Spectrometer for Mars -- or CRISM -- joins the set of high-tech
detectives
seeking traces of water on the red planet.
Built by the Johns Hopkins University Applied Physics Laboratory (APL)
in
Laurel, Md., CRISM is the first visible-infrared spectrometer to fly on
a
NASA Mars mission. Its primary job: look for the residue of minerals
that
form in the presence of water, the "fingerprints" left by evaporated
hot
springs, thermal vents, lakes or ponds on Mars when water could have
existed on the surface.
With unprecedented clarity, CRISM will map areas on the Martian surface
down to house-sized scales -- as small as 60 feet (about 18 meters)
across
-- when the spacecraft is in its average orbit altitude of about 190
miles
(more than 300 kilometers).
"CRISM plays a very important role in Mars exploration," says APL's Dr.
Scott Murchie, the instrument's principal investigator. "Our data will
identify sites most likely to have contained water, and which would
make
the best potential landing sites for future missions seeking fossils or
even traces of life on Mars."
Though certain landforms provide evidence that water may once have
flowed
on Mars, Murchie says scientists have little evidence of sites
containing
mineral deposits created by long-term interaction between water and
rock.
The NASA Rover Opportunity found evidence for liquid water in Meridian
Planum -- a large plain near Mars' equator -- but that is only one of
many
hundreds of sites where future spacecraft could land.
Peering through a telescope with a 4-inch (10-centimeter) aperture, and
with a greater capability to map spectral variations than any similar
instrument sent to another planet, CRISM will read 544 "colors" in
reflected sunlight to detect minerals in the surface. Its highest
resolution is about 20 times sharper than any previous look at Mars in
infrared wavelengths.
"At infrared wavelengths, rocks that look absolutely the same to human
eyes
become very different," Murchie says. "CRISM has the capability to take
images in which different rocks will 'light up' in different colors."
CRISM is mounted on a gimbal, allowing it to follow targets on the
surface
as the orbiter passes overhead. CRISM will spend the first half of a
two-year orbit mission mapping Mars at 650-foot (200-meter) scales,
searching for potential study areas. Several thousand promising sites
will
then be measured in detail at CRISM's highest spatial and spectral
resolution. CRISM will also monitor seasonal variations in dust and ice
particles in the atmosphere, supplementing data gathered by the
orbiter's
other instruments and providing new clues about the Martian climate.
"CRISM will improve significantly on the mapping technology currently
orbiting Mars," says CRISM Project Manager Peter Bedini of APL. "We'll
not
only look for future landing sites, but we'll be able to provide
details on
information the Mars Exploration Rovers are gathering now. There is a
lot
more to learn, and after CRISM and the Mars Reconnaissance Orbiter
there
will still be more to learn. But with this mission we're taking a big
step
in exploring and understanding Mars."
As the Mars Reconnaissance Orbiter cruises to its destination, the
CRISM
operations team continues to fine-tune the software and systems it will
use
to command the instrument and receive, read, process, and store a
wealth of
data from orbit -- more than 10 terabytes when processed back on Earth,
enough to fill more than 15,000 compact discs. The spacecraft is set to
reach Mars next March, use aerobraking to circularize its orbit, and
settle
into its science orbit by November 2006.
APL, which has built more than 150 spacecraft instruments over the past
four decades, led the effort to develop, integrate and test CRISM.
CRISM's
co-investigators are top planetary scientists from Brown University,
the
Jet Propulsion Laboratory, Northwestern University, Space Science
Institute, Washington University in St. Louis, University of Paris, the
Applied Coherent Technology Corporation, and NASA's Goddard Space
Flight
Center, Ames Research Center and Johnson Space Center.
The Jet Propulsion Laboratory, a division of the California Institute
of
Technology, Pasadena, manages the Mars Reconnaissance Orbiter mission
for
NASA's Science Mission Directorate.
For more information on CRISM and the Mars Reconnaissance Orbiter,
including instrument images, visit: http://crism.jhuapl.edu
###
The Applied Physics Laboratory, a division of the Johns Hopkins
University,
meets critical national challenges through the innovative application
of
science and technology. For information, visit http://www.jhuapl.edu/.
Office of Communications and Public Affairs
Laurel, Maryland
Media contact: Michael Buckley
(240) 228 7536 or (443) 778 7536
August 12, 2005
FOR IMMEDIATE RELEASE
POWERFUL MINERAL MAPPER HEADED TO MARS
APL-Built Spectrometer on NASA's Latest Mission to the Red Planet
With today's launch of NASA's Mars Reconnaissance Orbiter spacecraft
from
Cape Canaveral Air Force Station, Fla., the Compact Reconnaissance
Imaging
Spectrometer for Mars -- or CRISM -- joins the set of high-tech
detectives
seeking traces of water on the red planet.
Built by the Johns Hopkins University Applied Physics Laboratory (APL)
in
Laurel, Md., CRISM is the first visible-infrared spectrometer to fly on
a
NASA Mars mission. Its primary job: look for the residue of minerals
that
form in the presence of water, the "fingerprints" left by evaporated
hot
springs, thermal vents, lakes or ponds on Mars when water could have
existed on the surface.
With unprecedented clarity, CRISM will map areas on the Martian surface
down to house-sized scales -- as small as 60 feet (about 18 meters)
across
-- when the spacecraft is in its average orbit altitude of about 190
miles
(more than 300 kilometers).
"CRISM plays a very important role in Mars exploration," says APL's Dr.
Scott Murchie, the instrument's principal investigator. "Our data will
identify sites most likely to have contained water, and which would
make
the best potential landing sites for future missions seeking fossils or
even traces of life on Mars."
Though certain landforms provide evidence that water may once have
flowed
on Mars, Murchie says scientists have little evidence of sites
containing
mineral deposits created by long-term interaction between water and
rock.
The NASA Rover Opportunity found evidence for liquid water in Meridian
Planum -- a large plain near Mars' equator -- but that is only one of
many
hundreds of sites where future spacecraft could land.
Peering through a telescope with a 4-inch (10-centimeter) aperture, and
with a greater capability to map spectral variations than any similar
instrument sent to another planet, CRISM will read 544 "colors" in
reflected sunlight to detect minerals in the surface. Its highest
resolution is about 20 times sharper than any previous look at Mars in
infrared wavelengths.
"At infrared wavelengths, rocks that look absolutely the same to human
eyes
become very different," Murchie says. "CRISM has the capability to take
images in which different rocks will 'light up' in different colors."
CRISM is mounted on a gimbal, allowing it to follow targets on the
surface
as the orbiter passes overhead. CRISM will spend the first half of a
two-year orbit mission mapping Mars at 650-foot (200-meter) scales,
searching for potential study areas. Several thousand promising sites
will
then be measured in detail at CRISM's highest spatial and spectral
resolution. CRISM will also monitor seasonal variations in dust and ice
particles in the atmosphere, supplementing data gathered by the
orbiter's
other instruments and providing new clues about the Martian climate.
"CRISM will improve significantly on the mapping technology currently
orbiting Mars," says CRISM Project Manager Peter Bedini of APL. "We'll
not
only look for future landing sites, but we'll be able to provide
details on
information the Mars Exploration Rovers are gathering now. There is a
lot
more to learn, and after CRISM and the Mars Reconnaissance Orbiter
there
will still be more to learn. But with this mission we're taking a big
step
in exploring and understanding Mars."
As the Mars Reconnaissance Orbiter cruises to its destination, the
CRISM
operations team continues to fine-tune the software and systems it will
use
to command the instrument and receive, read, process, and store a
wealth of
data from orbit -- more than 10 terabytes when processed back on Earth,
enough to fill more than 15,000 compact discs. The spacecraft is set to
reach Mars next March, use aerobraking to circularize its orbit, and
settle
into its science orbit by November 2006.
APL, which has built more than 150 spacecraft instruments over the past
four decades, led the effort to develop, integrate and test CRISM.
CRISM's
co-investigators are top planetary scientists from Brown University,
the
Jet Propulsion Laboratory, Northwestern University, Space Science
Institute, Washington University in St. Louis, University of Paris, the
Applied Coherent Technology Corporation, and NASA's Goddard Space
Flight
Center, Ames Research Center and Johnson Space Center.
The Jet Propulsion Laboratory, a division of the California Institute
of
Technology, Pasadena, manages the Mars Reconnaissance Orbiter mission
for
NASA's Science Mission Directorate.
For more information on CRISM and the Mars Reconnaissance Orbiter,
including instrument images, visit: http://crism.jhuapl.edu
###
The Applied Physics Laboratory, a division of the Johns Hopkins
University,
meets critical national challenges through the innovative application
of
science and technology. For information, visit http://www.jhuapl.edu/.