This illustration shows HD 189733b, a huge gas giant that orbits very close to its host star HD 189733. The planet's atmosphere is scorching with a temperature of over 1,000 degrees Celsius, and it rains glass, sideways, in howling 7000 kilometer-per-hour winds. Image released on July 11, 2013
A new way to weigh the mass of distant alien worlds could help reveal key details about how friendly they may be to life, scientists say.
In the past two decades, astronomers have confirmed the existence of more than 900 planets outside the solar system and discovered more than 2,300 potential worlds. Now, instead of just detecting these exoplanets, scientists want to analyze them in detail, helping answer questions such as whether they are potentially habitable.
Knowing the mass of a planet can help scientists understand more about the exoplanet's atmospheric makeup and whether its insides are rocky or gassy. Both of these factors are linked to each planet's ability to support life. Knowing the mass of a planet can also lend some insight into how it cools, its plate tectonics, how it generates magnetic fields and whether gas escapes from its atmosphere, researchers said. [The Strangest Alien Planets (Gallery)]
"The mass affects everything on a planetary level," Julien de Wit, a researcher at MIT and the study's lead author, said in a statement. "If you don't get it, there is a large part of the planet's properties that remains undetermined."
However, current methods for weighing exoplanets are limited. The main technique scientists use now is radial velocity strategy. This method looks for repeated wobbles in a star's movements, which are signs of a planet's gravity yanking it back and forth; a planet's gravitational pull is linked to its mass.
The problem is that the radial velocity method does not work on a large variety of worlds that do not visibly tug much on their stars. This includes planets with low masses, those orbiting a fair distance away from their stars, those around faint stars, and those circling highly active stars where a planet's tugging can be masked by disturbances on the star.
Now, scientists have developed a strategy to weigh a planet just by looking at its atmosphere.
To understand how this method works, imagine that an exoplanet's atmosphere gets thinner with altitude, just as Earth's does. This is because the strength of a planet's gravitational pull weakens the greater the distance from the planet.
Since the strength of a planet's gravitational pull depends on its mass, researchers can deduce an exoplanet's mass by seeing how the planet's atmosphere thins with altitude. This involves gazing at exoplanets as they pass in front of their stars and looking at starlight shining through the atmospheres of those worlds to determine the atmospheric pressure drops with altitude. (A limitation of this approach is that it only works on planets with atmospheres, de Wit noted.)
To test this method, known as MassSpec, the researchers applied it on an exoplanet known as HD 189733b, a world about 63 light-years away from Earth discovered in 2005. The estimate they calculated for its mass closely agreed with estimates calculated via the radial velocity technique: about 1.15 times Jupiter's mass.
Currently, MassSpec only works on gas giants — worlds about the size of Jupiter and Saturn, the researchers said, adding that this method could help pin down the mass of gas giants whose stars are too active to allow mass estimates via the radial velocity method.
If and when space telescopes such as NASA's James Webb Space Telescope and the European Space Agency's potential Exoplanet Characterisation Observatory (EChO) launch, MassSpec will be able to weigh planets with a mass about the same as Earth's; super-Earth planets with a mass of up to 10 times Earth's mass; and gaseous planets known as mini-Neptunes that have a mass of up to 10 times Earth's mass.
"We now have a method to get the mass of Earth-sized planets that are far enough from their stars to be potentially habitable," de Wit told Space.com. "We show that our method could be applicable to potentially habitable Earth-sized planets within the next decade."
De Wit and colleague Sara Seager will detail their findings in Friday's issue of the journal Science.
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First published December 19 2013, 11:58 AM