Universe Today
In the past few decades, thousands of
extra-solar planets
have been discovered within our galaxy. As of
July 28th, 2018
, a total of 3,374 extra-solar planets have been confirmed in 2,814 planetary systems. While the majority of these planets have been gas giants, an increasing number have been terrestrial (i.e. rocky) in nature and were found to be orbiting within their stars' respective
habitable zones
(HZ).
However, as the case of the Solar System shows, HZs do not necessary mean a planet can support life. Even though Venus and Mars are at the inner and the outer edge of the Sun's HZ (respectively), neither is capable of supporting life on its surface. And with more potentially-habitable planets being discovered all the time, a
new study
suggests that it might be time to refine our definition of habitable zones.
The study, titled "
A more comprehensive habitable zone for finding life on other planets
", recently appeared online. The study was conducted by Dr. Ramses M. Ramirez, a research scientist with the
Earth-Life Science Institute at the Tokyo Institute of Technology
. For years, Dr. Ramirez has been involved in the study of potentially-habitable worlds and built climate models to assess the processes that make planets habitable.
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A diagram depicting the Habitable Zone (HZ) boundaries, and how the boundaries are affected by star type. Credit: Wikipedia Commons/Chester Harman
[/caption]
As Dr. Ramirez indicated in his study, the most generic definition of a habitable zone is the circular region around a star where surface temperatures on an orbiting body would be sufficient to maintain water in a liquid state. However, this alone does not mean a planet is habitable, and additional considerations need to be taken into account to determine if life could truly exist there. As Dr. Ramirez told Universe Today via email:
This is what can be referred to as the "low-hanging fruit" approach, where scientists have looked for signs of habitability based on what we as humans are most familiar with. Given that the only example we have of habitability is planet Earth, exoplanet studies have been focused on finding planets that are "Earth-like" in composition (i.e. rocky), orbit, and size.
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Diagram showing GJ 625's habitable zone in comparison's to the Sun's. Credit: IAC
[/caption]
However, in recent years this definition has come to be challenged by newer studies. As exoplanet research has moved away from merely detecting and confirming the existence of bodies around other stars and moved into characterization, newer formulations of HZs have emerged that have attempted to capture the diversity of potentially-habitable worlds.
As Dr. Ramirez explained, these newer formulations have complimented traditional notions of HZs by considering that habitable planets may have different atmospheric compositions:
One such study was conducted by Dr. Ramirez and
Lisa Kaltenegger, an associate professor with the Carl Sagan Institute at Cornell University. According to a paper they produced in 2017, which appeared in the Astrophysical Journal Letters, exoplanet-hunters could find planets that would one day become habitable based on the presence of
volcanic activity - which would be discernible through the presence of hydrogen gas (H2) in their atmospheres.
[caption id="attachment_133797" align="aligncenter" width="580"]
Stellar temperature versus distance from the star compared to Earth for the classic habitable zone (shaded blue) and the volcanic habitable zone extension (shaded red). Credit: R. Ramirez, Carl Sagan Institute, Cornell
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This theory is a natural extension of the search for "Earth-like" conditions, which considers that Earth's atmosphere was not always as it is today. Basically, planetary scientists theorize that billions of years ago, Earth's early atmosphere had an abundant supply of hydrogen gas (H
2
) due to volcanic outgassing and interaction between hydrogen and nitrogen molecules in this atmosphere is what kept the Earth warm long enough for life to develop.
In Earth's case, this hydrogen eventually escaped into space, which is believed to be the case for all terrestrial planets. However, on a planet where there is sufficient levels of volcanic activity, the presence of hydrogen gas in the atmosphere could be maintained, thus allowing for a greenhouse effect that would keep their surfaces warm. In this respect, the presence of hydrogen gas in a planet's atmosphere could extend a star's HZ.
According to Ramirez, there is also the factor of time, which is not typically taken into account when assessing HZs. In short, stars evolve over time and put out varying levels of radiation based on their age. This has the effect of altering where a star's HZ reaches, which may not encompass a planet that is currently being studied. As Ramirez explained:
Finally, there is the issue of what kinds of star system astronomers have been observing in the hunt for exoplanets. Whereas many surveys have examined G-type yellow dwarf star (which is what our Sun is),
much research
has been focused on
M-type (red dwarf) stars
of late because of their longevity and the fact that they believed to be the most
likely place to find rocky planets
that orbit within their stars' HZs.
"Whereas most previous studies have focused on single star systems,
recent work
suggests that habitable planets may be found in binary star systems or even red giant or white dwarf systems, potentially habitable planets may also take the form of desert worlds or even ocean worlds that are much wetter than the Earth," says Ramirez. "Such formulations not only greatly expand the parameter space of potentially habitable planets to search for, but they allow us to filter out the worlds that are most (and least) likely to host life."
In the end, this study shows that the classical HZ is not the only tool that can be used to asses the possibility of extra-terrestrial life. As such, Ramirez recommends that in the future, astronomers and exoplanet-hunters should supplement the classical HZ with the additional considerations raised by these newer formulations. In so doing, they just may be able to maximize their chances for finding life someday.
"I recommend that scientists pay real special attention to the early stages of planetary systems because that helps determine the likelihood that a planet that is currently located in the present day habitable zone is actually worth studying further for more evidence of life," he said. "I also recommend that the various HZ definitions are used in conjunction so that we can best determine which planets are most likely to host life. That way we can rank these planets and determine which ones to spend most of our telescope time and energy on. Along the way we would also be testing how valid the HZ concept is, including determining how universal the carbonate-silicate cycle is on a cosmic scale."
Further Reading: arXiv
