Data from Cassini’s composite infrared spectrometer of Enceladus’ south polar terrain, which is marked by linear fissures, indicate that the internal heat-generated power is about 15.8 gigawatts, approximately 2.6 times the power output of all the hot springs in the Yellowstone region, or comparable to 20 coal-fueled power stations. This is more than an order of magnitude higher than scientists had predicted, according to Carly Howett from the Southwest Research Institute in Boulder, Colorado.
“The mechanism capable of producing the much higher observed internal power remains a mystery and challenges the currently proposed models of long-term heat production,” said Howett.
It has been known since 2005 that Enceladus’ south polar terrain is geologically active and the activity is centered on four roughly parallel linear trenches, 80 miles (130 kilometers) long and about 1 mile (2 kilometers) wide, informally known as “tiger stripes.” Cassini also found that these fissures continually eject great plumes of ice particles and water vapor into space. These trenches have elevated temperatures due to heat leaking out of Enceladus’ interior.
A 2007 study predicted the internal heat of Enceladus, if principally generated by tidal forces arising from the orbital resonance between Enceladus and another moon, Dione, could be no greater than 1.1 gigawatts averaged over the long term. Heating from natural radioactivity inside Enceladus would add another 0.3 gigawatt.
The latest analysis, which also involved the composite infrared spectrometer team members John Spencer from the Southwest Research Institute and John Pearl and Marcia Segura from NASA’s Goddard Space Flight Center in Greenbelt, Maryland, uses observations taken in 2008, which cover the entire south polar terrain. They constrained Enceladus’ surface temperatures to determine the region’s surprisingly high output.
A possible explanation of the high heat flow observed is that Enceladus’ orbital relationship to Saturn and Dione changes with time, allowing periods of more intensive tidal heating separated by more quiescent periods. This means Cassini might be lucky enough to be seeing Enceladus when it’s unusually active.
The new, higher heat flow determination makes it even more likely that liquid water exists below Enceladus’ surface, Howett noted.
Recently, scientists studying ice particles ejected from the plumes discovered that some of the particles are salt-rich, and are probably frozen droplets from a saltwater ocean in contact with Enceladus’ mineral-rich rocky core. The presence of a subsurface ocean, or perhaps a south polar sea between the moon’s outer ice shell and its rocky interior, would increase the efficiency of the tidal heating by allowing greater tidal distortions of the ice shell.
“The possibility of liquid water, a tidal energy source, and the observation of organic (carbon-rich) chemicals in the plume of Enceladus make the satellite a site of strong astrobiological interest,” Howett said.
Data from Cassini’s composite infrared spectrometer of Enceladus’ south polar terrain, which is marked by linear fissures, indicate that the internal heat-generated power is about 15.8 gigawatts, approximately 2.6 times the power output of all the hot springs in the Yellowstone region, or comparable to 20 coal-fueled power stations. This is more than an order of magnitude higher than scientists had predicted, according to Carly Howett from the Southwest Research Institute in Boulder, Colorado.
“The mechanism capable of producing the much higher observed internal power remains a mystery and challenges the currently proposed models of long-term heat production,” said Howett.
It has been known since 2005 that Enceladus’ south polar terrain is geologically active and the activity is centered on four roughly parallel linear trenches, 80 miles (130 kilometers) long and about 1 mile (2 kilometers) wide, informally known as “tiger stripes.” Cassini also found that these fissures continually eject great plumes of ice particles and water vapor into space. These trenches have elevated temperatures due to heat leaking out of Enceladus’ interior.
A 2007 study predicted the internal heat of Enceladus, if principally generated by tidal forces arising from the orbital resonance between Enceladus and another moon, Dione, could be no greater than 1.1 gigawatts averaged over the long term. Heating from natural radioactivity inside Enceladus would add another 0.3 gigawatt.
The latest analysis, which also involved the composite infrared spectrometer team members John Spencer from the Southwest Research Institute and John Pearl and Marcia Segura from NASA’s Goddard Space Flight Center in Greenbelt, Maryland, uses observations taken in 2008, which cover the entire south polar terrain. They constrained Enceladus’ surface temperatures to determine the region’s surprisingly high output.
A possible explanation of the high heat flow observed is that Enceladus’ orbital relationship to Saturn and Dione changes with time, allowing periods of more intensive tidal heating separated by more quiescent periods. This means Cassini might be lucky enough to be seeing Enceladus when it’s unusually active.
The new, higher heat flow determination makes it even more likely that liquid water exists below Enceladus’ surface, Howett noted.
Recently, scientists studying ice particles ejected from the plumes discovered that some of the particles are salt-rich, and are probably frozen droplets from a saltwater ocean in contact with Enceladus’ mineral-rich rocky core. The presence of a subsurface ocean, or perhaps a south polar sea between the moon’s outer ice shell and its rocky interior, would increase the efficiency of the tidal heating by allowing greater tidal distortions of the ice shell.
“The possibility of liquid water, a tidal energy source, and the observation of organic (carbon-rich) chemicals in the plume of Enceladus make the satellite a site of strong astrobiological interest,” Howett said.
