Washington, August 15 : NASA's Cassini spacecraft has pinpointed precisely where the icy jets erupt from the surface of Saturn's geologically active moon Enceladus, which can be called a feat of interplanetary sharpshooting.
New carefully targeted pictures reveal exquisite details in the prominent south polar "tiger stripe" fractures from which the jets emanate.
The images show the fractures are about 300 meters (980 feet) deep, with V-shaped inner walls. The outer flanks of some of the fractures show extensive deposits of fine material.
Finely fractured terrain littered with blocks of ice tens of meters in size and larger (the size of small houses) surround the fractures.
"This is the mother lode for us," said Carolyn Porco, Cassini imaging team leader at the Space Science Institute, Boulder, Colorado, US. "A place that may ultimately reveal just exactly what kind of environment - habitable or not - we have within this tortured little moon," she added.
One highly anticipated result of this flyby was finding the location within the fractures from which the jets blast icy particles, water vapor and trace organics into space.
Scientists are now studying the nature and intensity of this process on Enceladus, and its effects on surrounding terrain.
This information, coupled with observations by Cassini's other instruments, may answer the question of whether reservoirs of liquid water exist beneath the surface.
The high-resolution images were acquired during an August 11, 2008, flyby of Enceladus, as Cassini sped past the icy moon at 64,000 kilometers per hour (40,000 miles per hour).
A special technique, dubbed "skeet shooting" by the imaging team, was developed to cancel out the high speed of the moon relative to Cassini and obtain the ultra-sharp views.
"Knowing exactly where to point, at just the right time, was critical to this event," said Paul Helfenstein, Cassini imaging team associate at Cornell University, Ithaca, New York, who developed and used the skeet-shoot technique to design the image sequence.
"Enceladus was streaking across the sky so quickly that the spacecraft had no hope of tracking any feature on its surface," said Helfenstein.
"Our best option was to point the spacecraft far ahead of Enceladus, spin the spacecraft and camera as fast as possible in the direction of Enceladus' predicted path, and let Enceladus overtake us at a time when we could match its motion across the sky, snapping images along the way," he added.
For scientists, having the combination of high-resolution snapshots and broader images showing the whole region is critical for understanding what may be powering the activity on Enceladus.