Planetary habitability

Planetary habitability is the measure of an astronomical body's potential for developing and sustaining life. It may be applied both to planets and to the natural satellites of planets. Given that the existence of life beyond our own planet is at present unverified, delineating planetary habitability is largely an extrapolation of Earth conditions and the characteristics of our Sun and solar system which have proven particularly favourable to life's flourishing here. Observation and exploration of the other planets and moons within the solar system provide critical information on defining habitability criteria.

The only absolute requirement for life is an energy source (usually but not necessarily sunlight), but the notion of planetary habitability implies that certain other geophysical, geochemical, and astrophysical criteria must be met before an astronomical body is likely to give rise to life. This article is a discursive description of what conditions are presently considered essential in this regard and is not intended as a probability analysis of life emerging off of the planet Earth ^[1].

An understanding of planetary habitability must begin with stars, not planets themselves. While bodies with broadly Earth-like characteristics may be plentiful, it is equally vital that their larger system be amendable to life. Under the auspices of SETI's Project Phoenix, scientists Margaret Turnbull and Jill Tarter developed the "HabCat" or Catalogue of Habitable Stellar Systems in 2002. The catalogue was formed by winnowing the nearly 120 000 stars of the larger Hipparcos Catalogue into a core group of 17 000 "HabStars", and the selection criteria employed provide a good starting point for understanding which astrophysical factors are necessary to habitable planets ^[2].

The spectral class of a star indicates its photospheric temperature, which (for main-sequence stars) correlates to overall mass. The appropriate spectral range for "HabStars" is presently considered to be "early-F," "G," to "mid-K." This corresponds to temperatures of a little more than 7 000 K down to a little more than 4 000 K; our Sun (not coincidentally) is directly in the middle of these bounds, classified as a G2 star. "Middle-class" stars of this sort have a number of characteristics considered important to planetary habitability:

• They live at least a few a billion years, allowing life a chance to evolve. More luminous main-sequence stars of the "O," "B" and "A" classes usually live less than a billion years and in exceptional cases less than 10 million ^{[3] [4]}.
• They emit enough high-frequency ultraviolet radiation to initiate important atmospheric dynamics such as ozone formation but do not emit so much that ionization destroys life as at it attempts to form ^[5].
• Surficial liquid water may exist on planets orbiting them at a distance that does not induce tidal lock (see next section and 3.1).

Crudely, these stars are neither "too hot" nor "too cold", and they live just long enough that life should have a chance to begin. This spectral range likely accounts for between 5% and 10% of stars in our galaxy. Whether fainter late K and M class ("red dwarf") stars are also suitable hosts for habitable planets is perhaps the most important open question in the entire field of planetary habitability given that the majority of stars fall within this range; this is discussed extensively below.

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The HZ is a theoretical shell surrounding a star throughout which any planets present would have surficial liquid water. After an energy source, liquid water is considered the most crucial component for life given how integral it is to all life-systems on Earth. This may reflect the bias of a water-dependent species, and if life is discovered in the absence of water (i.e., in a liquid-ammonia solution), the notion of an HZ may have to be greatly expanded or else discarded altogether as too restricting ^[6].

A "stable" HZ denotes two factors. First, the range of an HZ should not vary greatly over time. All stars increase in luminosity as they age and a given HZ naturally migrates outwards, but if this happens too quickly (i.e., with a super-massive star), planets may only have a brief window inside the HZ and a correspondingly weaker chance to develop life. Calculating an HZ range and its long-term movement is never straightforward, given that feedback loops such as the carbon cycle will tend to offset the increases in luminosity. Assumptions made about atmospheric conditions and geology thus have as great an impact on a putative HZ range as does Solar evolution; the proposed parameters of our own Sun's HZ, for example, have fluctuated greatly ^[7].

Secondly, no large-mass body such as a gas giant should be present in or relatively close to the HZ thus disrupting the formation of Earth-like bodies. If, for example, Jupiter had appeared between the orbits of Venus and Earth, the two smaller planets would almost certainly not have formed. It was once assumed that the inner-rock planets, outer-gas giants pattern observable in our solar system was likely to be the norm elsewhere, but recent discoveries of extra-solar planets have overturned this notion. Numerous Jupiter-sized bodies have been found in close orbit about their primary, disrupting potential HZs. Data for extra solar planets is, however, skewed towards large planets in close eccentric orbits because of them being far easier to spot, and it remains to be seen which type of solar system is the norm.

Changes in luminosity are common to all stars, but the severity of such fluctuations covers a broad range. Most stars are relatively stable, but a significant minority of variable stars often experience sudden and intense increases in luminosity and consequently the amount of energy radiated toward bodies in orbit. These are considered poor candidates for hosting life-bearing planets as their unpredictability and energy output changes would impact negatively on organisms. Most obviously, living things adapted to a particular temperature range would likely be unable to stand a too great deviation. Further, upswings in luminosity are generally accompanied by massive doses of gamma ray and x-ray radiation which might prove lethal. Atmospheres do mitigate such effects (i.e., an absolute increase of 100% in our Sun's luminosity would not necessarily translate into a 100% temperature increase on Earth), but atmosphere retention might not occur in the first place on planets orbiting variables, as being buffeted by high-frequency energy would continually strip such bodies of their protective covering.

Our Sun, as in much else, is benign in terms of this danger: the variation between solar max and minimum is roughly 0.1% over its eleven-year solar cycle. There is strong (though not undisputed) evidence that even minor changes in our Sun's luminosity have had significant effects on the Earth's climate well within the historical era; the Little Ice Age of the mid-second millennium, for instance, may have been caused by a relatively long-term decline in the sun's luminosity ^[8]. Thus, a star does not have to be a true variable for differences in luminosity to affect habitability.

The closest "solar twin" to our Sun is considered to be 18 Scorpii; interestingly (and perhaps unfortunately), the only significant difference between the two bodies is the amplitude of the solar cycle, which appears to be much greater on 18 Scorpii ^[9].

While the bulk of material in any star is hydrogen and helium, there is a great variation in the amount of heavier elements (metals) stars contain. A high proportion of metals in a star correlates to the amount of heavy material initially available in protoplanetary disks. A low amount of metal signifantly decreases the probability that planets will have formed around that star, under the solar nebula theory of planetary systems formation. Spectroscopic studies of systems where exoplanets have been found to date confirm the relationship between high metal content and planet formation: "stars with planets, or at least with planets similar to the ones we are finding today, are clearly more metal rich that stars without planetary companions ^[10]." High metallicity also places a youth requirement on hab-stars: stars formed early in the universe's history have low metal content and a correspondingly lesser likelihood of having planetary companions.

Current estimates suggest that at least half of all stars are in a binary system ^[11], which further complicates a delineation of habitability. The separation between stars in a binary may range from less than one astronomical unit (the Earth-Sun distance) to several hundred. In latter instances, the gravitational effects will be negligible on a planet orbiting an otherwise suitable star and habitability potential will not be disrupted. However, where the separation is significantly less, a stable orbit may be impossible. If a planet’s distance to its primary exceeds about one fifth of the closest approach of the other star orbital stability is not guaranteed ^[12].

The nearest star system to our own, Alpha Centauri, underscores the fact that binaries need not be discounted in the search for habitable planets. Centauri A and B have an 11 AU distance at closest approach (23 AU mean) and both should have stable habitable zones. A study of long-term orbital stability for simulated planets within the system shows that planets within approximately 3 AU of either star may remain stable (i.e. the semi-major axis deviating by less than 5%). The HZ for Centauri A is conservatively estimated at 1.2 to 1.3 AU and Centauri B at 0.73 to 0.74—well within the stable region in both cases ^[13].

The chief assumption about habitable planets is that they be terrestrial. Such planets, roughly within one order of magnitude of Earth mass, are primarily composed of silicate rocks and have not accreted the gaseous outer layers of hydrogen and helium found on gas giants. That life could evolve in the cloud tops of giant planets has not been decisively ruled out ^[14], though it is considered unlikely given that they have no surface and their gravity is enormous ^[15]. The natural satellites of giant planets, however, remain perfectly valid candidates for hosting life ^[16].

Whether a terrestrial planet or terrestrial-type satellite, certain criteria must be met before habitability is likely to be achieved.

Low-mass planets are poor candidates for life for two reasons. First, their lesser gravity makes atmosphere retention difficult. Constituent molecules are more likely to reach escape velocity and be lost to space when buffeted by solar wind or stirred by collision. Planets without a thick atmosphere lack the primal matter necessary for biochemistry, have little insulation and poor heat transfer across their surfaces (Mars with its thin atmosphere is colder than the Earth would be at similar distance) and lesser protection against high-frequency radiation and meteoroids. Secondly, smaller planets have smaller diameters and thus higher surface-to-volume ratios than their larger cousins. Such bodies tend to lose the energy left over from their formation quickly and end up geologically dead, lacking the volcanoes, earthquakes and tectonic activity which supply the surface with life-sustaining material and the atmosphere with temperature moderators like carbon dioxide.

"Low mass" is, of course, a partly relative label; the Earth is considered low mass when compared to our Solar System's gas giants, but it is the largest, by diameter and mass, and densest of all terrestrial bodies ^[17]. It is a large enough (along with Venus) to retain an atmosphere through gravity alone and large enough that its molten core remains a heat engine, driving the diverse geology of the surface. Mars, by contrast, is nearly (or perhaps totally) geologically dead and has lost much of its atmosphere ^[18]. Thus, it would be fair to infer that the lower mass limit for habitability lies somewhere between Mars and Earth-Venus. Exceptional circumstances do breed exceptional cases, however: Jupiter's moon Io (smaller than the terrestrial planets) is volcanically dynamic because of the gravitational stresses induced by its orbit; neighbouring Europa may have a liquid ocean underneath a frozen shell due also to energy created in its orbiting a gas giant; Saturn's Titan, meanwhile, has retained a thick atmosphere and has an outside chance of harbouring life. These satellites are exceptions, but they prove that mass as a habitability criterion cannot be considered in isolation.

Finally, a larger planet is likely to have a concomitantly large iron core. This allows for a magnetic field to protect the planet from the solar wind, which otherwise tends to strip away the planetary atmosphere and to bombard living things with ionized particles. Mass is not the only criterion for producing a magnetic field—as the planet must also rotate fast enough to produce a dynamo effect within its core ^[19]—but is a significant component of the process.

As with other criteria, stability is the critical consideration in determining the impact of orbital and rotational characteristics on planetary habitability.

Orbital eccentricity is the difference between a planet's closest and farthest approach to its primary. The greater the eccentricity the greater the temperature fluctuation on a planet's surface. While supremely adaptive, living organisms can only stand so much variation, particularly if the fluctuations overlap both the freezing point and boiling point of the planet's main biotic solvent (i.e., water). If, for example, Earth's oceans were alternately boiling off into space and freezing solid, it is difficult to imagine life as we know it having evolved. Fortunately, the Earth's orbit is almost wholly circular, with an eccentricity of less than 0.02; other planets in our solar system (with the exception of Pluto and to a lesser extent Mercury) have eccentricities that are similarly benign. Data collected on the orbital eccentricities of extra-solar planets has been surprising and perhaps discouraging in terms of extraterrestrial possibilities: 90% have an orbital eccentricity greater than that found within our solar system, and the average is fully 0.25 ^[20].

A planet's movement around its rotational axis must also meet certain criteria if we are to expect life to evolve.

• The day-night cycle should not be overlong. If a day takes years, the temperature differential between the day and night side will be pronounced, and problems similar to those noted with extreme orbital eccentricity will come to the fore.
• The planet should have moderate seasons. If the axial tilt (obliquity) is perpendicular to the ecliptic, seasons will not occur and a main stimulant to biospheric dynamism will disappear; such planets will generally be colder than they would be with a tilt. If a planet is radically tilted, meanwhile, seasons will be extreme and make it more difficult for a biosphere to achieve homeostasis. The exact effects of these changes can only be computer modelled at present, and studies have shown that even extreme tilts of up to 85 do not absolutely preclude life "provided (it) does not occupy continental surfaces plagued seasonally by the highest temperature ^[21]."
• The rotational "wobble" should not be pronounced. Precession on Earth occurs over a 23 000 year cycle; if this period were radically shorter or if the wobble were more extreme, drastic climatic changes would again impact on habitability.

The Earth's moon appears to play a crucial role in moderating our climate by stabilizing the axial tilt. It has been suggested that a chaotic tilt may be a "deal-breaker" in terms of habitability—i.e., a satellite the size of the moon is not only helpful but required to produce stability ^[22]. This position remains controversial.

For life as we know it to exist on any world, an abundance of four elements must be present: carbon, hydrogen, oxygen, and nitrogen. By weight, these four elements make up over 96% of Earth's collective biomass. Carbon has an unparalleled ability to bond with itself and to form a massive array of intricate and varied structures, making it an ideal material for the complex mechanisms that form living cells. Hydrogen and oxygen, in the form of water, comprise the solvent in which biological processes take place and in which the first reactions occurred that led to life's emergence. The energy contained in the powerful hydrogen bond, released from the breakdown of carbohydrates, is life's fuel. These four elements together make up amino acids, which in turn are the building blocks of protiens, the substance of living tissue.

There is reason to suspect that this habitability hurdle will be overcome elsewhere, as the four elements of life are also the commonest chemically reactive elements in the universe. Indeed, simple biogenic compounds, such as amino acids, have been found in meteorites and in interstellar space.

Relative abundance in space does not always mirror differentiated abundance within planets, however; of the four life elements, for instance, only oxygen is present in any abundance in the Earth's crust ^[23]. This can be partly explained by the fact that many of these elements, such as hydrogen and nitrogen, along with their most basic compounds, such as carbon dioxide, carbon monoxide, methane, ammonia, and water, are gaseous at warm temperatures. In the hot region close to the Sun, these volatile compounds could not have played a significant role in the planets' geological formation. Instead, they were trapped as gases underneath the newly formed crusts, which were largely made of rocky, involatile compounds such as silica (a compound of silicon and oxygen, accounting for oxygen's relative abundance). Outgassing of volatile compounds through the first volcanoes would have contributed to the formation of the planets' atmospheres. The Miller experiments have shown that, with the application of energy, amino acids can form from the synthesis of the simple compounds within the primordial atmosphere ^[24].

Even so, volcanic outgassing could not have accounted for the sheer amount of water in Earth's oceans ^[25]. The vast majority of the water, and arguably of the carbon, necessary for life must have come from the outer solar system, away from the Sun's heat, where it could remain solid. Comets impacting with the Earth in the Solar systems early years would have deposited vast amounts of water, along with the other volatile compounds life requires (including amino acids) onto the early Earth, providing a kick-start to the evolution of life.

Thus, while there is reason to be optimistic the life elements will be available elsewhere, this comes with a caveat: a habitable system likely requires a supply of long-term orbiting bodies to seed inner planets. Without comets there is reason to suspect life as we know it would not exist on Earth. The possibility also remains that other elements beyond those necessary on Earth will provide a biochemical basis for life elsewhere; see alternative biochemistry.

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Determining the habitability of red dwarf stars would help decide whether life in the universe is ubiquitous or vanishingly rare, since red dwarfs make up between 70% and 90% of all the stars in the galaxy (brown dwarfs are likely more numerous but could never support life as we understand it, since what little heat they emit quickly disappears).

Astronomers for many years ruled out red dwarfs as potential abodes for life, because their small size (from 0.1 to 0.6 solar masses) means that their nuclear reactions proceed exceptionally slowly, and thus they emit very little light, from 3% of that produced by the Sun to as little as 0.01%. Any planet in orbit around a red dwarf would have to huddle very close to its parent star to attain Earth-like surface temperatures; from 0.3 AU (just inside the orbit of Mercury) for a star like Lacaille 8760, to as little as 0.032 AU (such a world would have a year lasting just 6.3 days) for a star like Proxima Centauri ^[26]. At those distances, the star's gravity would cause tidal lock. The daylight side of the planet would eternally face the star, while the night-time side would eternally face away from it. The only way potential life could avoid either an inferno or an utter deep freeze would be if the planet had an atmosphere thick enough to transfer the star's heat from the day side to the night side. It was long assumed that such a thick atmosphere would prevent sunlight from reaching the surface in the first place, preventing photosynthesis.

However, studies by Robert Haberle and Manoj Joshi of NASA's Ames Research Center in California have shown that a planet's atmosphere need only be 15% thicker than Earth's for the star's heat to be effectively carried to the night side. This is well within the levels required for photosynthesis, though water would still remain frozen on the dark side in some of their models ^[27]. Martin Heath of Greenwich Community College, London has shown that seawater, too, could be effectively circulated without freezing solid if the ocean basins were deep enough to allow free flow beneath the night side's ice cap. So, a planet with deep enough sea basins and a thick enough atmosphere could, at least potentially, harbour life in a red dwarf system.

Mere size is not the only factor in making red dwarfs potentially unsuitable for life, however. On a red dwarf planet, photosynthesis on the night side would be impossible, since it would never see the sun. On the day side, because the sun does not rise or set, areas in the shadows of mountains would remain so forever, making photosynthesis difficult. Photosynthesis as we understand it would be further complicated by the fact that a red dwarf produces most of its radiation in the infrared, and on our planet the process depends on visible light.

Red dwarfs are far more variable and violent than their stabler, larger cousins. Often they are covered in starspots that can dim their emitted light by up to 40% for months at a time, while at other times they emit gigantic flares that can double their brightness in a matter of minutes. Such variation would be very damaging for life; however, it could also stimulate evolution by increasing mutation rates and rapidly shifting climatic conditions.

There is, however, one major advantage that red dwarfs have over other stars as abodes for life: they live a long time. It took 4.5 billion years for humanity to emerge on Earth, and life as we know it will see suitable conditions for perhaps 2 billion years more. Red dwarfs, by contrast, can live for trillions of years, because their nuclear reactions are far slower than those of larger stars, meaning that life both has longer to evolve and longer to survive.

Further, while the odds of finding a planet in the habitable zone around any specific red dwarf are slim, the total amount of habitable zone around all red dwarfs combined is equal to the total amount around sun-like stars given their ubiquity ^[28].

"Good jupiters" are gas giant planets like our own Jupiter that orbit their stars in circular orbits far enough away from the HZ to not disturb it but close enough to "protect" terrestrial planets in closer orbit in two critical ways. First, they help to stabilize the orbits of the inner planets and in turn their climates. Second, they keep the inner solar system relatively free of comets and asteroids that could cause devastating impacts ^[29]. Jupiter orbits our sun at about 5 times the Earth-sun distance, and this is the rough distance we should expect to find good Jupiters elsewhere. Jupiter's caretaker role was dramatically illustrated in 1994 when the Comet Shoemaker-Levy 9 comet impacted the giant; had Jovian gravity not captured the comet, it may well have entered the inner solar system.

Early in the Solar System's history, Jupiter played a somewhat contrary role: it increased the eccentricity of asteroid belt orbits and enabled many to cross Earth's orbit and supply the planet with important volatiles. Before the time that the Earth reached half its present mass, icy bodies from the Jupiter–Saturn region as well as small bodies from the primordial asteroid belt supplied water to the Earth because of the gravitational scattering of Jupiter and, to a lesser extent, Saturn ^[30]. Thus, while the gas giants are now helpful protectors, they were once suppliers of critical habitability material.

Scientists have also considered the possibility that particular areas of galaxies (Galactic habitable zones) are better suited to life than others; our own system, in the Orion Spur, on our galaxy's edge is considered to be in a life-favourable spot ^[31]. Well away from the galactic centre, it avoids various dangers:

• It is not in a globular cluster.
• It is not near an active gamma ray source.
• It is not near the black hole which is believed to lie at the galactic centre.
• The circular orbit of the Sun around the galactic centre keeps out of the way of the galaxy's dangerous spiral arms.

Relative loneliness is ultimately what a life-bearing system needs. If Sol were crowded amongst other systems, neighbours might disrupt the stability of various orbiting bodies (not least Oort cloud and Kuiper Belt objects, which can bring catastrophe if knocked into the inner solar system). Close neighbours also increase the likelihood of being fatally close to supernova explosions and pulsars.

• Astrobiology
• Astrophysics
• Origin of life
• Planetary science
• Solar twin

• David Darling
• General interest astrobiology
• James Kasting research papers
• Margaret Turnbull HabCat related files
• Sol Station