Lunar Reconnaissance Orbiter spectrometer detects helium in Moon’s atmosphere
Because helium also resides in the interplanetary background, several techniques were used to remove signal contributions from the background helium to determine the amount of helium native to the Moon.
August 16, 2012
Scientists using the Lyman Alpha Mapping Project (LAMP) spectrometer aboard NASA’s Lunar Reconnaissance Orbiter (LRO) have made the first spectroscopic observations of the noble gas helium in the tenuous atmosphere surrounding the Moon.
The Lyman Alpha Mapping Project (LAMP) aboard LRO (shown here in a pre-flight photo) uses a novel method to peer into the perpetual darkness of the Moon's so-called permanently shadowed regions. LAMP "sees" the lunar surface using the ultraviolet light from nearby space and stars, which bathes all bodies in space in a soft glow of ultraviolet light. Credit: NASA Goddard/Debbie McCallum
These remote-sensing observations complement in situ measurements taken in 1972 by the Lunar Atmosphere Composition Experiment (LACE) deployed by Apollo 17.
Although designed to map the lunar surface, the LAMP team expanded its science investigation to examine the far-ultraviolet emissions visible in the tenuous atmosphere above the lunar surface, detecting helium over a campaign spanning more than 50 orbits. Because helium also resides in the interplanetary background, several techniques were applied to remove signal contributions from the background helium and determine the amount of helium native to the Moon.
“The question now becomes: Does the helium originate from inside the Moon, for example, due to radioactive decay in rocks, or from an exterior source, such as the solar wind?” said Alan Stern from the Southwest Research Institute in Boulder, Colorado. “If we find the solar wind is responsible, that will teach us a lot about how the same process works in other airless bodies.”
If spacecraft observations show no such correlation, radioactive decay or other internal lunar processes could be producing helium that diffuses from the interior or that is released during lunar quakes.
“With LAMP’s global views as it moves across the Moon in future observations, we’ll be in a great position to better determine the dominant source of the helium,” said Stern.
Another point for future research involves helium abundances. The LACE measurements from the 1970s showed an increase in helium abundances as the night progressed. This could be explained by atmospheric cooling, which concentrates atoms at lower altitudes. LAMP will further build on those measurements by investigating how the abundances vary with latitude.
During its campaign, LACE also detected the noble gas argon on the lunar surface. Although significantly fainter to the spectrograph, LAMP also will seek argon and other gases during future observations.
“These ground-breaking measurements were enabled by our flexible operations of LRO as a science mission so that we can now understand the Moon in ways that were not expected when LRO was launched in 2009,” said Richard Vondrak from the Goddard Space Flight Center in Greenbelt, Maryland.