It seems that all too frequently we read another exciting announcement that an extrasolar planet has been detected, one that is in the “habitable zone” and would likely be able to host life. The announcement is usually accompanied by an artist’s conception of the planet with oceans, continents, and an atmosphere with clouds that appear decidedly Earth-like.
Figure 1: Estimated habitable zones in the solar system compared to Kepler-452 and Kepler-186. Image credit: NASA
The circumstellar habitable zone (HZ) was given a rigorous definition in a 1993 paperby geoscientist James Kasting (Pennsylvania State University) and his team. This definition was then updated in 2013.1 As defined, an HZ has an inner edge where atmospheric water breaks down and hydrogen escapes. This results in a runaway greenhouse effect. At the outer edge, CO2 condenses into clouds and accelerates cooling, resulting in all surface water freezing. For the solar system, the HZ model has an inner edge at 0.99 astronomical units (AU) and an outer edge at 1.70 AU.2 Earth is just barely inside the inner edge, and Mars is just inside the outer edge at 1.52 AU.
Although often overlooked, the definition of an HZ is extremely dependent on the composition of an exoplanet’s atmosphere. Kasting’s model assumed not only an Earth-like atmosphere, but also a carbon-silicate feedback cycle that requires a fine-tuned mix of oceans, continents, plate tectonics, and steady volcanic outgassing of CO2. One exoplanet researcher notes, “Without knowledge of the major molecules of an exoplanet’s atmosphere, we can only speculate whether it resides in the habitable zone for liquid water.… Declaring a freshly detected exoplanet to be in the ‘habitable zone’ amounts to little more than media spin if its atmospheric composition is unknown.”3
How the Definition Is Changing
Recent studies demonstrate how fragile a planet’s atmosphere can be when subjected to steady stellar radiation and occasional coronal mass ejections. Several Earth-size exoplanets around M dwarf stars have been found in the classically defined HZ. However, the close orbits of these exoplanets lead to tidal locking, which results in the atmospheres being stripped over time by a constantly blowing stellar wind.4 NASA’s MAVEN spacecraft orbiting Mars indicates that the lack of a protective magnetic field may have resulted in a similar stripping of the planet’s atmosphere. Even planets like Venus that retain a dense atmosphere lose their water unless they have a strong magnetic field.
But how has Earth maintained its magnetic shield for billions of years? Recent work done by a French team informs us that complex gravitational interactions between the earth and the moon are responsible for the earth’s long-lasting geodynamo and protective magnetic shield. The team writes (emphasis added):
Finally, because the Moon appears to be a necessary ingredient to sustain the magnetic field, and because a magnetic field is needed to shield the Earth’s atmosphere from erosion by solar wind, the habitability of an Earthlike planet may be subordinated to the existence of a large satellite. While more than 1,000 exoplanets have already been observed, the detection of an accompanying exomoon is rare. Hence, our model could have major implications in future planetary missions as exoplanets with orbiting moons would more likely host extraterrestrial life.5
This research puts another severe constraint on planet habitability.
So What Does Habitable Really Mean?
The carbon-silicate cycle is a key mechanism in keeping Earth habitable. Now, strong planet-moon gravitational interactions join the list of necessary properties for habitable planets, and also the list of things scientists cannot yet measure. The Earth-Moon system is really a double planet and therefore a relatively rare planetary configuration.6This new result serves as a strong reminder that “habitable,” as currently defined, really has no connection with Earth’s abundant capacity to support a diverse, thriving array of life. It may also mean that Earth is unique in its ability to do so.
By Dr. Otis Graf
Otis Graf received his PhD in Aerospace Engineering from the University of Texas at Austin in 1973. He worked at the NASA Johnson Space Center and for IBM Government Systems. After retiring from IBM, he now serves as an online instructor for Reasons Institute and is living in Katy, Texas.
- James Kasting, Daniel Whitmire, and Ray Reynolds, “Habitable Zones around Main Sequence Stars,” Icarus 101 (January 1993): 108–28; Ravi Kumar Kopparapu et al., “Habitable Zones around Main-Sequence Stars: New Estimates,” Astrophysical Journal 765 (March 2013): 131, doi:10.1088/0004-637X/765/2/131.
- One astronomical unit is defined as roughly 93 million miles, the average distance from Earth to the sun.
- Kevin Heng, “The Imprecise Search for Extraterrestrial Habitability,” American Scientist 104 (May-June 2016): 146, doi:10.1511/2016.120.1.
- O. Cohen et al., “Magnetospheric Structure and Atmospheric Joule Heating of Habitable Planets Orbiting M-dwarf Stars,” Astrophysical Journal 790 (July 2014): 57, doi:10.1088/0004-637X/790/1/57.
- Denis Andrault et al., “The Deep Earth May Not Be Cooling Down,” Earth and Planetary Science Letters 443 (June 2016): 195–203, doi:10.1016/j.epsl.2016.03.020.
- Sebastian Elser et al., “How Common Are Earth-Moon Planetary Systems?,” Icarus 214 (August 2011): 357–65, doi:10.1016/j.icarus.2011.05.025.