A Neptune-sized planet orbiting another star has one oddatmosphere ? analysis has shown that it lacks methane, a common ingredient for manyplanets in our solar system and a possible signature of life.
The discovery was made after NASA's SpitzerSpace Telescope captured the extrasolar planet's light in six infraredwavelengths, allowing researchers to analyze the components of the exoplanet'satmosphere.
"The observations are quite telling," Stevensontold SPACE.com. "The ball is in the theorists' court now. They will have toimprove their models, taking into account the disequilibrium processes thatcould account for what is happening. The current models are a very good firststep in determining the atmospheres of these planets, but now we need to go astep further."
GJ 436b is located 33 light-years away in the constellationLeo, the Lion. The planet rides in a tight, 2.64-day orbit around its small star,an "M-dwarf" class star that is much cooler than our sun. The planetcan be viewed from Earth as it crosses in front of its star.
The study's findings will help move astronomers one stepcloser to probing and characterizing the atmospheres of distant planets thesize of Earth.
"Ultimately, we want to find biosignatures on a small,rocky world," Stevenson said. "Oxygen, especially with even a littlemethane, would tell us that we humans might not be alone."
In fact, any planet with the common atmospheric mix ofhydrogen, carbon and oxygen, and a temperature of up to 1,340 degreesFahrenheit (727 degrees Celsius) is expected to have a large amount of methaneand a small amount of carbon monoxide. That's because under these temperatures,any carbon present should be chemically favored to be in the form of methane.
?"A lot of the larger planets and brown dwarfs arethought to have similar atmospheric behavior," said Joseph Harrington, anassociate professor at the University of Central Florida and the study'sprincipal investigator. "Brown dwarfs pretty much all follow a fairlystraight-forward atmospheric chemistry that is not difficult to predict. Manytheorists have applied these models to hot exoplanets, but in this case itdoesn't work."
"What this does tell us is that there is room forimprovement in our models," Harrington explained. "The lesson here isthat planets really do have individual personalities."
As the planet disappears from sight, the total lightobserved from the star system drops ? this reduction is measured to find thebrightness of the planet at various wavelengths. This technique was firstpioneered by Spitzer in 2005 and has since been used to measure the atmosphericcomponents of several Jupiter-sized exoplanets, or so-called "hotJupiters."
"The Spitzer technique is being pushed to smaller,cooler planets more like our Earth than the previously studied hotJupiters," said Charles Beichman, director of NASA's Exoplanet ScienceInstitute at NASA's Jet Propulsion Laboratory and the California Institute of Technology,both located in Pasadena, Calif.
"In coming years, we can expect that a space telescopecould characterize the atmosphere of a rocky planet a few times the size of theEarth. Such a planet might show signposts of life," he added.
This research was performed before Spitzer ran out of itsliquid coolant in May 2009, officially beginning its "warm"mission.
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