Alien Moons --Emerging as Prime Suspects in the Kepler Mission's Search for Life Beyond Our Solar System
Are Exomoons prime suspects in our search for extraterrestrial life? Astronomers have their fingers crossed that within the haul of data collected by NASA's Kepler mission, which has already detected nearly three thousand possible exoplanets, hide the signatures of the very first exomoons. "The first exomoons that we find will be large – maybe Mars- or even Earth-sized – and therefore intrinsically more likely to be habitable than small moons," says René Heller, a postdoctoral research associate at the Leibniz Institute for Astrophysics in Potsdam, Germany. "With Kepler finding many more giant planets than terrestrial planets in stellar habitable zones, it's really important that we try to figure out what conditions might be like on the moons of these giants to gauge if they can host extraterrestrial life."
The discovery of alien moons will open up an exciting new frontier in the continuing hunt for habitable worlds outside the Solar System. With the confirmation of exomoons likely right around the corner, researchers have begun addressing the unique and un-Earthly factors that might affect their habitability.
Because exomoons orbit a larger planetary body, they have an additional set of constraints on their potential livability than planets themselves. Examples include eclipses by their host planet, as well as reflected sunlight and heat emissions. Most of all, gravitationally-induced tidal heating by a host planet can dramatically impact a moon's climate and geology. In essence, compared to planets, exomoons have additional sources of energy that can alter their "energy budgets," which, if too high, can turn a temperate, potential paradise into a scorched wasteland.
"What discriminates the habitability of a satellite from the habitability of a planet in general is that it has different contributions to its energy budget," said René Heller, a postdoctoral research associate at the Leibniz Institute for Astrophysics in Potsdam, Germany.
An example of a circumstellar irradiation habitable zone, the orbital band around a star where water can exist in liquid form on a planet or exomoon's surface. The habitable edge is rather different. It is defined as the innermost circumplanetary orbit in which an exomoon will not undergo what is known as a runaway greenhouse effect. "To be habitable, moons must orbit their planets outside of the habitable edge," said Heller.
A runaway greenhouse effect occurs when a planet’s or moon's climate warms inexorably due to positive feedback loops. An example is thought to have taken place right next door, so to speak, to the other planet most like Earth that we know of: Venus.
There, the heat from a young, brightening Sun could have increasingly evaporated a primordial ocean. This evaporative process put ever more heat-trapping water vapor in the atmosphere, which led to more evaporation, and so on, eventually drying the planet out as the water was broken apart into hydrogen and oxygen by the Sun's ultraviolet radiation. The atmospheric hydrogen on Venus escaped into space, and without hydrogen, no more water could form. *Moons situated in fairly distant orbits from their planets should be safely beyond the habitable edge wherein this desiccation takes place.
"Typically, and especially in the solar system, stellar illumination is by far the greatest source of energy on a moon," said Heller. "In wide planetary orbits, moons will be fed almost entirely by stellar input. But if a satellite orbits its host planet very closely, then the planet's stellar reflection, its own thermal emission, eclipses and tidal heating in the moon can become substantial."
The cumulative effects of the non-tidal heating effects are small, but could be the difference between an exomoon being inside or outside the habitable edge.
A figure belwo shows the different kinds of illumination that an exomoon can receive from both its star and its host planet during four phases of an orbital period. Note that the image is not to scale and that penumbras – partial shadows – are ignored for conceptual ease. Here on Earth, we get a little extra energy from the Moon in the form of moonlight, which is reflected light from the Sun.
Moons, though, get bathed in a lot more sunlight from their planetary neighbors; Earth shines almost 50 times as brightly in the lunar sky as the Moon does in our night sky. In addition to reflected sunlight, planets also emit absorbed sunlight as thermal radiation onto their exomoons.
This "planetshine" can add a not-insubstantial amount of energy to an exomoon's overall intake. Imagine a gas giant planet orbiting a Sun-like star at about the same distance that Earth orbits our Sun. For a moon with a relatively close orbit around this planet, like Io’s orbit around Jupiter, Heller calculates that the moon could absorb an additional seven or so watts per square meter of power. (Earth absorbs about 240 watts per square meter from the Sun).
Eclipses can potentially offset some of the extra energy input from planetshine. For eclipses, Heller calculated that lost stellar illumination for an exomoon in a close orbit (similar to the closest found in our solar system) is up to 6.4 percent.
Interestingly, because most moons including ours are tidally locked to their planet – that is, one side of the moon constantly faces the planet – eclipses, as well as planetshine, would only darken and lighten one hemisphere. This phenomenon could modify the climate, as well as the behavior of life forms, in ways not seen on Earth.
"Asymmetric illumination on the moon could induce wind and temperature patterns, both in terms of geography and in time, which are unknown from planetary climates," Heller noted. "Life on a moon with regular, frequent eclipses would surely have to adapt their sleep-wake and hunt-hide rhythms as well, but only those creatures on the planet-facing hemisphere."
Although the eclipse-related loss of several percentage points of illumination is not a huge loss of energy, a moon-planet duo might need to be closer to its star to compensate for this deficit if the moon were still to be considered habitable from a Goldilocks zone perspective.
However, this situation introduces another hurdle to habitability: The closer a planet is to its star, the stronger the star's gravitational pull is on the planet's moons. This extra pull can tug moons into non-circular, or eccentric orbits about their planets. Eccentric orbits, in turn, result in varying amounts of gravitational stress exerted on the moon as it orbits.
These “tidal forces,” as they are called, cause heating due to friction. The ocean tides we experience on Earth occur partly as a result of the Moon's gravity tugging more on the water and land nearest it, which distorts Earth's shape. The effect goes both ways, of course, but not equally, with planets inducing significantly greater tidal heating within their much smaller moons.
If an exomoon's orbit takes it too close to its planet, tidal heating could push the energy budget too high, culminating in a runaway greenhouse effect. At the extremes, the tidal heating could unleash massive volcanic activity, leaving the satellite covered in magma and distinctly inhospitable, like the "pizza moon" Io.
On the other hand, it should be noted, tidal heating might be a savior for life. Tidal heating could help sustain a subsurface ocean, like the one suspected to exist within Saturn's moon Europa, alternatively making an otherwise unwelcoming exomoon outside the traditional habitable zone potentially livable.
Another factor comes into play as eclipses rob a bit of energy from an exomoon and require the moon-planet pair to be closer to their star. To remain gravitationally bound to a planet and not be ripped away by the star's gravity, a moon must fall within a so-called “Hill radius” – the planet's sphere of gravitational dominance. This radius shrinks with greater proximity to the host star. The closer the planet and moon are to their star, the less space is available outside the habitable edge.
For planets and attendant moons around dim, cool, low-mass stars called red dwarfs, this dynamic becomes important. The habitable zone around red dwarf stars is very tight; for a star with a quarter of the Sun's mass, for instance, the Goldilocks zone is thought to be around just 13 percent the Sun-Earth distance – in other words, a third of Mercury's orbital distance from the Sun.
In a red dwarf solar system, not only must a moon then be closer to its habitable zone planet, but given the planet's necessary proximity to its star, the moon's orbit will tend to be eccentric. These qualities increase the chances that the moon will fall within the habitable edge. Heller calculated that for many red dwarf stars, the odds of them hosting habitable moons is accordingly slim.
"There is a critical stellar mass limit below which no habitable moon can exist," Heller said. "Around low-mass stars with masses of about twenty percent the mass of the Sun, a moon must be so close to its habitable zone planet to remain gravitationally bound that it is subject to intense tidal heating and cannot under any circumstances be habitable."
Many factors beyond habitable edge considerations, of course, ultimately determine an exomoon's habitability. To be considered broadly habitable by creatures other than, say, subsurface bacteria, an exomoon must meet some of the same basic criteria as a habitable, Earth-like exoplanet: It must have liquid surface water, a long-lived substantial atmosphere, and a magnetic field to protect it from solar radiation (and, in the case of exomoons around gas giants like Jupiter, from the charged particles created in the giant exoplanet's magnetosphere).
To possess these qualities, which scientists say grow likelier with increasing mass, a habitable exomoon will likely be quite large compared to those in the solar system – more on the order of the size of Earth itself. The biggest moon in our Solar System, Jupiter's Ganymede, is just 2.5 percent of Earth's mass. But previous studies have suggested that monstrous moons by the solar system's standards are indeed possible.
The Kepler mission is expected to be able to detect exomoons down to about 20 percent of the mass of the Earth. The data, which consists of measuring the extremely small dips in the amount of starlight as their planets (or moons) block it from our point of view – should reveal a moon’s mass and orbital parameters as well. Armed with this information – and now with habitable edge considerations – astronomers can thus hope to make some ballpark speculations on any soon-to-be-discovered exomoon’s propensity to support living beings.
Heller hopes that there will be a list of candidate exomoons ready for observing by next-generation instruments, such as the James Webb Space Telescope and thirty meter-class ground telescopes. These observatories, coming online in the next decade, could be able to characterize exomoon atmospheres and offer tantalizing evidence of life.
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Image credits: Credit: NASA/JPL-Caltech; Artist's concept of a pair of exomoons orbiting a gas giant. R. Heller, AIP; A ringed gas giant planet and its moon bathed in the crimson rays of a red dwarf star. Credit: NASA/ESA/G.Bacon (STScI)