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Galactic habitable zone

January 01, 1970

Not to be confused with Habitable zone.

In astrobiology and planetary astrophysics, the galactic habitable zone is the region of a galaxy in which life might most likely develop. The concept of a galactic habitable zone analyzes various factors, such as metallicity (the presence of elements heavier than hydrogen and helium) and the rate and density of major catastrophes such as supernovae, and uses these to calculate which regions of a galaxy are more likely to form terrestrial planets, initially develop simple life, and provide a suitable environment for this life to evolve and advance.[1] According to research published in August 2015, very large galaxies may favor the birth and development of habitable planets more than smaller galaxies such as the Milky Way.[2] In the case of the Milky Way, its galactic habitable zone is commonly believed to be an annulus with an outer radius of about 10 kiloparsecs (33,000 ly) and an inner radius close to the Galactic Center (with both radii lacking hard boundaries).[1][3]

Galactic habitable-zone theory has been criticized due to an inability to accurately quantify the factors making a region of a galaxy favorable for the emergence of life.[3] In addition, computer simulations suggest that stars may change their orbits around the galactic center significantly, therefore challenging at least part of the view that some galactic areas are necessarily more life-supporting than others.[4][5][6]

History edit

Background edit

The idea of the circumstellar habitable zone was introduced in 1953 by Hubertus Strughold and Harlow Shapley[7][8] and in 1959 by Su-Shu Huang[9] as the region around a star in which an orbiting planet could retain water at its surface. From the 1970s, planetary scientists and astrobiologists began to consider various other factors required for the creation and sustenance of life, including the impact that a nearby supernova may have on life's development.[10] In 1981, computer scientist Jim Clarke proposed that the apparent lack of extraterrestrial civilizations in the Milky Way could be explained by Seyfert-type outbursts from an active galactic nucleus, with Earth alone being spared from this radiation by virtue of its location in the galaxy.[11] In the same year, Wallace Hampton Tucker analyzed galactic habitability in a more general context, but later work superseded his proposals.[12]

Modern galactic habitable-zone theory was introduced in 1986 by L.S. Marochnik and L.M. Mukhin of the Russian Space Research Institute, who defined the zone as the region in which intelligent life could flourish.[13] Donald Brownlee and palaeontologist Peter Ward expanded upon the concept of a galactic habitable zone, as well as the other factors required for the emergence of complex life, in their 2000 book Rare Earth: Why Complex Life is Uncommon in the Universe.[14] In that book, the authors used the galactic habitable zone, among other factors, to argue that intelligent life is not a common occurrence in the Universe.

The idea of a galactic habitable zone was further developed in 2001 in a paper by Ward and Brownlee, in collaboration with Guillermo Gonzalez of the University of Washington.[15][16] In that paper, Gonzalez, Brownlee, and Ward stated that regions near the galactic halo would lack the heavier elements required to produce habitable terrestrial planets, thus creating an outward limit to the size of the galactic habitable zone.[10] Being too close to the galactic center, however, would expose an otherwise habitable planet to numerous supernovae and other energetic cosmic events, as well as excessive cometary impacts caused by perturbations of the host star's Oort cloud. Therefore, the authors established an inner boundary for the galactic habitable zone, located just outside the galactic bulge.[10]

Considerations edit

In order to identify a location in the galaxy as being a part of the galactic habitable zone, a variety of factors must be accounted for. These include the distribution of stars and spiral arms, the presence or absence of an active galactic nucleus, the frequency of nearby supernovae that can threaten the existence of life, the metallicity of that location, and other factors.[10] Without fulfilling these factors, a region of the galaxy cannot create or sustain life with efficiency.

Chemical evolution edit

 
The metallicity of the thin galactic disk is far greater than that of the outlying galactic halo.

One of the most basic requirements for the existence of life around a star is the ability of that star to produce a terrestrial planet of sufficient mass to sustain it. Various elements, such as iron, magnesium, titanium, carbon, oxygen, silicon, and others, are required to produce habitable planets, and the concentration and ratios of these vary throughout the galaxy.[10]

The most common benchmark elemental ratio is that of [Fe/H], one of the factors determining the propensity of a region of the galaxy to produce terrestrial planets. The galactic bulge, the region of the galaxy closest to the Galactic Center, has an [Fe/H] distribution peaking at −0.2 decimal exponent units (dex) relative to the Sun's ratio (where −1 would be 110 such metallicity); the thin disk, in which local sectors of the local Arm are, has an average metallicity of −0.02 dex at the orbital distance of the Sun around the galactic center, reducing by 0.07 dex for every additional kiloparsec of orbital distance. The extended thick disk has an average [Fe/H] of −0.6 dex, while the halo, the region farthest from the galactic center, has the lowest [Fe/H] distribution peak, at around −1.5 dex.[10] In addition, ratios such as [C/O], [Mg/Fe], [Si/Fe], and [S/Fe] may be relevant to the ability of a region of a galaxy to form habitable terrestrial planets, and of these [Mg/Fe] and [Si/Fe] are slowly reducing over time, meaning that future terrestrial planets are more likely to possess larger iron cores.[10]

In addition to specific amounts of the various stable elements that comprise a terrestrial planet's mass, an abundance of radionuclides such as 40K, 235U, 238U, and 232Th is required in order to heat the planet's interior and power life-sustaining processes such as plate tectonics, volcanism, and a geomagnetic dynamo.[10] The [U/H] and [Th/H] ratios are dependent on the [Fe/H] ratio; however, a general function for the abundance of 40K cannot be created with existing data.[10]

Even on a habitable planet with enough radioisotopes to heat its interior, various prebiotic molecules are required in order to produce life; therefore, the distribution of these molecules in the galaxy is important in determining the galactic habitable zone.[13] A 2008 study by Samantha Blair and colleagues attempted to determine the outer edge of the galactic habitable zone by means of analyzing formaldehyde and carbon monoxide emissions from various giant molecular clouds scattered throughout the Milky Way; however, the data is neither conclusive nor complete.

While high metallicity is beneficial for the creation of terrestrial extrasolar planets, an excess amount can be harmful for life. Excess metallicity may lead to the formation of a large number of gas giants in a given system, which may subsequently migrate from beyond the system's frost line and become hot Jupiters, disturbing planets that would otherwise have been located in the system's circumstellar habitable zone.[17] Thus, it was found that the Goldilocks principle applies to metallicity as well; low-metallicity systems have low probabilities of forming terrestrial-mass planets at all, while excessive metallicities cause a large number of gas giants to develop, disrupting the orbital dynamics of the system and altering the habitability of terrestrial planets in the system.

Catastrophic events edit

 
The impact of supernovae on the extent of the galactic habitable zone has been extensively studied.

As well as being in a region of the galaxy that is chemically advantageous for the development of life, a star must also avoid an excessive number of catastrophic cosmic events with the potential to damage life on its otherwise habitable planets.[17] Nearby supernovae, for example, have the potential to severely harm life on a planet; with excessive frequency, such catastrophic outbursts have the potential to sterilize an entire region of a galaxy for billions of years. The galactic bulge, for example, experienced an initial wave of extremely rapid star formation,[10] triggering a cascade of supernovae that for five billion years left that area almost completely unable to develop life.

In addition to supernovae, gamma-ray bursts,[18] excessive amounts of radiation, gravitational perturbations[17] and various other events have been proposed to affect the distribution of life within the galaxy. These include, controversially, such proposals as "galactic tides" with the potential to induce cometary impacts or even cold bodies of dark matter[18] that pass through organisms and induce genetic mutations.[19] However, the impact of many of these events may be difficult to quantify.[17]

Galactic morphology edit

Various morphological features of galaxies can affect their potential for habitability. Spiral arms, for example, are the location of star formation, but they contain numerous giant molecular clouds and a high density of stars that can perturb a star's Oort cloud, sending avalanches of comets and asteroids toward any planets further in.[20] In addition, the high density of stars and rate of massive star formation can expose any stars orbiting within the spiral arms for too long to supernova explosions, reducing their prospects for the survival and development of life.[20] Considering these factors, the Sun is advantageously placed within the galaxy because, in addition to being outside a spiral arm, it orbits near the corotation circle, maximizing the interval between spiral-arm crossings.[20][21]

Spiral arms also have the ability to cause climatic changes on a planet. Passing through the dense molecular clouds of galactic spiral arms, stellar winds may be pushed back to the point that a reflective hydrogen layer accumulates in an orbiting planet's atmosphere, perhaps leading to a snowball Earth scenario.[6][22]

A galactic bar also has the potential to affect the size of the galactic habitable zone. Galactic bars are thought to grow over time, eventually reaching the corotation radius of the galaxy and perturbing the orbits of the stars already there.[21] High-metallicity stars like the Sun, for example, at an intermediate location between the low-metallicity galactic halo and the high-radiation galactic center, may be scattered throughout the galaxy, affecting the definition of the galactic habitable zone. It has been suggested that for this reason, it may be impossible to properly define a galactic habitable zone.[21]

Boundaries edit

 
The galactic habitable zone is often viewed as an annulus 7-9 kpc from the galactic center, shown in green here, though recent research has called this into question.

Early research on the galactic habitable zone, including the 2001 paper by Gonzalez, Brownlee, and Ward, did not demarcate any specific boundaries, merely stating that the zone was an annulus encompassing a region of the galaxy that was both enriched with metals and spared from excessive radiation, and that habitability would be more likely in the galaxy's thin disk.[10] However, later research conducted in 2004 by Lineweaver and colleagues did create boundaries for this annulus, in the case of the Milky Way ranging from 7 kpc to 9 kpc from the galactic center.

The Lineweaver team also analyzed the evolution of the galactic habitable zone with respect to time, finding, for example, that stars close to the galactic bulge had to form within a time window of about two billion years in order to have habitable planets.[17] Before that window, galactic-bulge stars would be prevented from having life-sustaining planets from frequent supernova events. After the supernova threat had subsided, though, the increasing metallicity of the galactic core would eventually mean that stars there would have a high number of giant planets, with the potential to destabilize star systems and radically alter the orbit of any planet located in a star's circumstellar habitable zone.[17] Simulations conducted in 2005 at the University of Washington, however, show that even in the presence of hot Jupiters, terrestrial planets may remain stable over long timescales.[23]

A 2006 study by Milan Ćirković and colleagues extended the notion of a time-dependent galactic habitable zone, analyzing various catastrophic events as well as the underlying secular evolution of galactic dynamics.[18] The paper considers that the number of habitable planets may fluctuate wildly with time due to the unpredictable timing of catastrophic events, thereby creating a punctuated equilibrium in which habitable planets are more likely at some times than at others.[18] Based on the results of Monte Carlo simulations on a toy model of the Milky Way, the team found that the number of habitable planets is likely to increase with time, though not in a perfectly linear pattern.[18]

Subsequent studies saw more fundamental revision of the old concept of the galactic habitable zone as an annulus. In 2008, a study by Nikos Prantzos revealed that, while the probability of a planet escaping sterilization by supernova was highest at a distance of about 10 kpc from the galactic center, the sheer density of stars in the inner galaxy meant that the highest number of habitable planets could be found there.[3] The research was corroborated in a 2011 paper by Michael Gowanlock, who calculated the frequency of supernova-surviving planets as a function of their distance from the galactic center, their height above the galactic plane, and their age, ultimately discovering that about 0.3% of stars in the galaxy could today support complex life, or 1.2% if one does not consider the tidal locking of red dwarf planets as precluding the development of complex life.[1]

Criticism edit

The idea of the galactic habitable zone has been criticized by Nikos Prantzos, on the grounds that the parameters to create it are impossible to define even approximately, and that thus the galactic habitable zone may merely be a useful conceptual tool to enable a better understanding of the distribution of life, rather than an end to itself.[3] For these reasons, Prantzos has suggested that the entire galaxy may be habitable, rather than habitability being restricted to a specific region in space and time.[3] In addition, stars "riding" the galaxy's spiral arms may move tens of thousands of light years from their original orbits, thus supporting the notion that there may not be one specific galactic habitable zone.[4][5][6] A Monte Carlo simulation, improving on the mechanisms used by Ćirković in 2006, was conducted in 2010 by Duncan Forgan of Royal Observatory Edinburgh. The data collected from the experiments support Prantzos's notion that there is no solidly defined galactic habitable zone, indicating the possibility of hundreds of extraterrestrial civilizations in the Milky Way, though further data will be required in order for a definitive determination to be made.[24]

See also edit

References edit

  1. ^ a b c Gowanlock, M. G.; Patton, D. R.; McConnell, S. M. (2011). "A Model of Habitability Within the Milky Way Galaxy". Astrobiology. 11 (9): 855–73. arXiv:1107.1286. Bibcode:2011AsBio..11..855G. doi:10.1089/ast.2010.0555. PMID 22059554. S2CID 851972.
  2. ^ Choi, Charles Q. (21 August 2015). "Giant Galaxies May Be Better Cradles for Habitable Planets". Space.com. Retrieved 24 August 2015.
  3. ^ a b c d e Prantzos, Nikos (2006). "On the "Galactic Habitable Zone"". Space Science Reviews. 135 (1–4): 313–22. arXiv:astro-ph/0612316. Bibcode:2008SSRv..135..313P. doi:10.1007/s11214-007-9236-9. S2CID 119441813.
  4. ^ a b Rok Roškar; Debattista; Quinn; Stinson; James Wadsley (2008). "Riding the Spiral Waves: Implications of Stellar Migration for the Properties of Galactic Disks". The Astrophysical Journal. 684 (2): L79. arXiv:0808.0206. Bibcode:2008ApJ...684L..79R. doi:10.1086/592231. S2CID 15219277.
  5. ^ a b University of Washington (15 September 2008). "Immigrant Sun: Our Star Could Be Far from Where It Started in Milky Way". Newswise. Retrieved September 15, 2008.
  6. ^ a b c Battersby, Stephen (November 30, 2011). "Earth's wild ride: Our voyage through the Milky Way". New Scientist (2841).
  7. ^ Strughold, Hubertus (1953). The Green and Red Planet: A Physiological Study of the Possibility of Life on Mars. University of New Mexico Press.
  8. ^ James Kasting (2010). How to Find a Habitable Planet. Princeton University Press. p. 127. ISBN 978-0-691-13805-3. Retrieved 4 May 2013.
  9. ^ Huang, Su-Shu (April 1960). "Life-Supporting Regions in the Vicinity of Binary Systems". Publications of the Astronomical Society of the Pacific. 72 (425): 106–114. Bibcode:1960PASP...72..106H. doi:10.1086/127489.
  10. ^ a b c d e f g h i j k Gonzalez, Guillermo; Brownlee, Donald; Peter, Ward (2001). "The Galactic Habitable Zone: Galactic Chemical Evolution". Icarus. 152 (1): 185. arXiv:astro-ph/0103165. Bibcode:2001Icar..152..185G. doi:10.1006/icar.2001.6617. S2CID 18179704.
  11. ^ Clarke, J. N. (1981). "Extraterrestrial intelligence and galactic nuclear activity". Icarus. 46 (1): 94–96. Bibcode:1981Icar...46...94C. doi:10.1016/0019-1035(81)90078-6.
  12. ^ Tucker, Wallace H. (1981). "Astrophysical crisis in the evolution of life in the Galaxy". In Billingham, John (ed.). Life in the Universe. Cambridge: The MIT Press. pp. 287–296. ISBN 9780262520621.
  13. ^ a b Blair, S. K.; Magnani, L.; Brand, J.; Wouterloot, J. G. A. (2008). "Formaldehyde in the Far Outer Galaxy: Constraining the Outer Boundary of the Galactic Habitable Zone". Astrobiology. 8 (1): 59–73. Bibcode:2008AsBio...8...59B. doi:10.1089/ast.2007.0171. PMID 18266563.
  14. ^ Ward, Peter; Brownlee, Donald (2003-12-10). Rare Earth: Why Complex Life is Uncommon in the Universe. Springer. pp. 191–220. ISBN 9780387952895.
  15. ^ Gonzalez, G (2001). "The Galactic Habitable Zone: Galactic Chemical Evolution". Icarus. 152 (1): 185–200. arXiv:astro-ph/0103165. Bibcode:2001Icar..152..185G. doi:10.1006/icar.2001.6617. S2CID 18179704.
  16. ^ Charles H. Lineweaver, Yeshe Fenner and Brad K. Gibson (January 2004). "The Galactic Habitable Zone and the Age Distribution of Complex Life in the Milky Way". Science. 303 (5654): 59–62. arXiv:astro-ph/0401024. Bibcode:2004Sci...303...59L. doi:10.1126/science.1092322. PMID 14704421. S2CID 18140737.
  17. ^ a b c d e f Lineweaver, C. H.; Fenner, Y.; Gibson, B. K. (2004). "The Galactic Habitable Zone and the Age Distribution of Complex Life in the Milky Way". Science. 303 (5654): 59–62. arXiv:astro-ph/0401024. Bibcode:2004Sci...303...59L. doi:10.1126/science.1092322. PMID 14704421. S2CID 18140737.
  18. ^ a b c d e Vukotic, B.; Cirkovic, M. M. (2007). "On the timescale forcing in astrobiology". Serbian Astronomical Journal. 175 (175): 45. arXiv:0712.1508. Bibcode:2007SerAJ.175...45V. doi:10.2298/SAJ0775045V. S2CID 56156159.
  19. ^ Collar, J. I. (1996). "Clumpy Cold Dark Matter and biological extinctions". Physics Letters B. 368 (4): 266–269. arXiv:astro-ph/9512054. Bibcode:1996PhLB..368..266C. doi:10.1016/0370-2693(95)01469-1. S2CID 119377346.
  20. ^ a b c Mullen, Leslie (May 18, 2001). . NAI Features Archive. Nasa Astrobiology Institute. Archived from the original on April 9, 2013. Retrieved May 9, 2013.
  21. ^ a b c Sundin, M. (2006). "The galactic habitable zone in barred galaxies". International Journal of Astrobiology. 5 (4): 325–326. Bibcode:2006IJAsB...5..325S. doi:10.1017/S1473550406003065. S2CID 122018103.
  22. ^ Pavlov, Alexander A. (2005). "Passing through a giant molecular cloud: "Snowball" glaciations produced by interstellar dust". Geophysical Research Letters. 32 (3): L03705. Bibcode:2005GeoRL..32.3705P. doi:10.1029/2004GL021890.
  23. ^ Raymond, Sean N.; Quinn, Thomas; Lunine, Jonathan I. (2005). "The formation and habitability of terrestrial planets in the presence of close-in giant planets". Icarus. 177 (1): 256–263. arXiv:astro-ph/0407620. Bibcode:2005Icar..177..256R. doi:10.1016/j.icarus.2005.03.008. S2CID 15547409.
  24. ^ Forgan, D. H. (2009). "A numerical testbed for hypotheses of extraterrestrial life and intelligence". International Journal of Astrobiology. 8 (2): 121–131. arXiv:0810.2222. Bibcode:2009IJAsB...8..121F. doi:10.1017/S1473550408004321. S2CID 17469638.

External links edit

  Media related to Habitable zone at Wikimedia Commons

January 01, 1970
galactic, habitable, zone, confused, with, habitable, zone, astrobiology, planetary, astrophysics, galactic, habitable, zone, region, galaxy, which, life, might, most, likely, develop, concept, galactic, habitable, zone, analyzes, various, factors, such, metal. Not to be confused with Habitable zone In astrobiology and planetary astrophysics the galactic habitable zone is the region of a galaxy in which life might most likely develop The concept of a galactic habitable zone analyzes various factors such as metallicity the presence of elements heavier than hydrogen and helium and the rate and density of major catastrophes such as supernovae and uses these to calculate which regions of a galaxy are more likely to form terrestrial planets initially develop simple life and provide a suitable environment for this life to evolve and advance 1 According to research published in August 2015 very large galaxies may favor the birth and development of habitable planets more than smaller galaxies such as the Milky Way 2 In the case of the Milky Way its galactic habitable zone is commonly believed to be an annulus with an outer radius of about 10 kiloparsecs 33 000 ly and an inner radius close to the Galactic Center with both radii lacking hard boundaries 1 3 Galactic habitable zone theory has been criticized due to an inability to accurately quantify the factors making a region of a galaxy favorable for the emergence of life 3 In addition computer simulations suggest that stars may change their orbits around the galactic center significantly therefore challenging at least part of the view that some galactic areas are necessarily more life supporting than others 4 5 6 Contents 1 History 1 1 Background 2 Considerations 2 1 Chemical evolution 2 2 Catastrophic events 2 3 Galactic morphology 3 Boundaries 4 Criticism 5 See also 6 References 7 External linksHistory editBackground edit The idea of the circumstellar habitable zone was introduced in 1953 by Hubertus Strughold and Harlow Shapley 7 8 and in 1959 by Su Shu Huang 9 as the region around a star in which an orbiting planet could retain water at its surface From the 1970s planetary scientists and astrobiologists began to consider various other factors required for the creation and sustenance of life including the impact that a nearby supernova may have on life s development 10 In 1981 computer scientist Jim Clarke proposed that the apparent lack of extraterrestrial civilizations in the Milky Way could be explained by Seyfert type outbursts from an active galactic nucleus with Earth alone being spared from this radiation by virtue of its location in the galaxy 11 In the same year Wallace Hampton Tucker analyzed galactic habitability in a more general context but later work superseded his proposals 12 Modern galactic habitable zone theory was introduced in 1986 by L S Marochnik and L M Mukhin of the Russian Space Research Institute who defined the zone as the region in which intelligent life could flourish 13 Donald Brownlee and palaeontologist Peter Ward expanded upon the concept of a galactic habitable zone as well as the other factors required for the emergence of complex life in their 2000 book Rare Earth Why Complex Life is Uncommon in the Universe 14 In that book the authors used the galactic habitable zone among other factors to argue that intelligent life is not a common occurrence in the Universe The idea of a galactic habitable zone was further developed in 2001 in a paper by Ward and Brownlee in collaboration with Guillermo Gonzalez of the University of Washington 15 16 In that paper Gonzalez Brownlee and Ward stated that regions near the galactic halo would lack the heavier elements required to produce habitable terrestrial planets thus creating an outward limit to the size of the galactic habitable zone 10 Being too close to the galactic center however would expose an otherwise habitable planet to numerous supernovae and other energetic cosmic events as well as excessive cometary impacts caused by perturbations of the host star s Oort cloud Therefore the authors established an inner boundary for the galactic habitable zone located just outside the galactic bulge 10 Considerations editIn order to identify a location in the galaxy as being a part of the galactic habitable zone a variety of factors must be accounted for These include the distribution of stars and spiral arms the presence or absence of an active galactic nucleus the frequency of nearby supernovae that can threaten the existence of life the metallicity of that location and other factors 10 Without fulfilling these factors a region of the galaxy cannot create or sustain life with efficiency Chemical evolution edit nbsp The metallicity of the thin galactic disk is far greater than that of the outlying galactic halo One of the most basic requirements for the existence of life around a star is the ability of that star to produce a terrestrial planet of sufficient mass to sustain it Various elements such as iron magnesium titanium carbon oxygen silicon and others are required to produce habitable planets and the concentration and ratios of these vary throughout the galaxy 10 The most common benchmark elemental ratio is that of Fe H one of the factors determining the propensity of a region of the galaxy to produce terrestrial planets The galactic bulge the region of the galaxy closest to the Galactic Center has an Fe H distribution peaking at 0 2 decimal exponent units dex relative to the Sun s ratio where 1 would be 1 10 such metallicity the thin disk in which local sectors of the local Arm are has an average metallicity of 0 02 dex at the orbital distance of the Sun around the galactic center reducing by 0 07 dex for every additional kiloparsec of orbital distance The extended thick disk has an average Fe H of 0 6 dex while the halo the region farthest from the galactic center has the lowest Fe H distribution peak at around 1 5 dex 10 In addition ratios such as C O Mg Fe Si Fe and S Fe may be relevant to the ability of a region of a galaxy to form habitable terrestrial planets and of these Mg Fe and Si Fe are slowly reducing over time meaning that future terrestrial planets are more likely to possess larger iron cores 10 In addition to specific amounts of the various stable elements that comprise a terrestrial planet s mass an abundance of radionuclides such as 40K 235U 238U and 232Th is required in order to heat the planet s interior and power life sustaining processes such as plate tectonics volcanism and a geomagnetic dynamo 10 The U H and Th H ratios are dependent on the Fe H ratio however a general function for the abundance of 40K cannot be created with existing data 10 Even on a habitable planet with enough radioisotopes to heat its interior various prebiotic molecules are required in order to produce life therefore the distribution of these molecules in the galaxy is important in determining the galactic habitable zone 13 A 2008 study by Samantha Blair and colleagues attempted to determine the outer edge of the galactic habitable zone by means of analyzing formaldehyde and carbon monoxide emissions from various giant molecular clouds scattered throughout the Milky Way however the data is neither conclusive nor complete While high metallicity is beneficial for the creation of terrestrial extrasolar planets an excess amount can be harmful for life Excess metallicity may lead to the formation of a large number of gas giants in a given system which may subsequently migrate from beyond the system s frost line and become hot Jupiters disturbing planets that would otherwise have been located in the system s circumstellar habitable zone 17 Thus it was found that the Goldilocks principle applies to metallicity as well low metallicity systems have low probabilities of forming terrestrial mass planets at all while excessive metallicities cause a large number of gas giants to develop disrupting the orbital dynamics of the system and altering the habitability of terrestrial planets in the system Catastrophic events edit nbsp The impact of supernovae on the extent of the galactic habitable zone has been extensively studied As well as being in a region of the galaxy that is chemically advantageous for the development of life a star must also avoid an excessive number of catastrophic cosmic events with the potential to damage life on its otherwise habitable planets 17 Nearby supernovae for example have the potential to severely harm life on a planet with excessive frequency such catastrophic outbursts have the potential to sterilize an entire region of a galaxy for billions of years The galactic bulge for example experienced an initial wave of extremely rapid star formation 10 triggering a cascade of supernovae that for five billion years left that area almost completely unable to develop life In addition to supernovae gamma ray bursts 18 excessive amounts of radiation gravitational perturbations 17 and various other events have been proposed to affect the distribution of life within the galaxy These include controversially such proposals as galactic tides with the potential to induce cometary impacts or even cold bodies of dark matter 18 that pass through organisms and induce genetic mutations 19 However the impact of many of these events may be difficult to quantify 17 Galactic morphology edit Various morphological features of galaxies can affect their potential for habitability Spiral arms for example are the location of star formation but they contain numerous giant molecular clouds and a high density of stars that can perturb a star s Oort cloud sending avalanches of comets and asteroids toward any planets further in 20 In addition the high density of stars and rate of massive star formation can expose any stars orbiting within the spiral arms for too long to supernova explosions reducing their prospects for the survival and development of life 20 Considering these factors the Sun is advantageously placed within the galaxy because in addition to being outside a spiral arm it orbits near the corotation circle maximizing the interval between spiral arm crossings 20 21 Spiral arms also have the ability to cause climatic changes on a planet Passing through the dense molecular clouds of galactic spiral arms stellar winds may be pushed back to the point that a reflective hydrogen layer accumulates in an orbiting planet s atmosphere perhaps leading to a snowball Earth scenario 6 22 A galactic bar also has the potential to affect the size of the galactic habitable zone Galactic bars are thought to grow over time eventually reaching the corotation radius of the galaxy and perturbing the orbits of the stars already there 21 High metallicity stars like the Sun for example at an intermediate location between the low metallicity galactic halo and the high radiation galactic center may be scattered throughout the galaxy affecting the definition of the galactic habitable zone It has been suggested that for this reason it may be impossible to properly define a galactic habitable zone 21 Boundaries edit nbsp The galactic habitable zone is often viewed as an annulus 7 9 kpc from the galactic center shown in green here though recent research has called this into question Early research on the galactic habitable zone including the 2001 paper by Gonzalez Brownlee and Ward did not demarcate any specific boundaries merely stating that the zone was an annulus encompassing a region of the galaxy that was both enriched with metals and spared from excessive radiation and that habitability would be more likely in the galaxy s thin disk 10 However later research conducted in 2004 by Lineweaver and colleagues did create boundaries for this annulus in the case of the Milky Way ranging from 7 kpc to 9 kpc from the galactic center The Lineweaver team also analyzed the evolution of the galactic habitable zone with respect to time finding for example that stars close to the galactic bulge had to form within a time window of about two billion years in order to have habitable planets 17 Before that window galactic bulge stars would be prevented from having life sustaining planets from frequent supernova events After the supernova threat had subsided though the increasing metallicity of the galactic core would eventually mean that stars there would have a high number of giant planets with the potential to destabilize star systems and radically alter the orbit of any planet located in a star s circumstellar habitable zone 17 Simulations conducted in 2005 at the University of Washington however show that even in the presence of hot Jupiters terrestrial planets may remain stable over long timescales 23 A 2006 study by Milan Cirkovic and colleagues extended the notion of a time dependent galactic habitable zone analyzing various catastrophic events as well as the underlying secular evolution of galactic dynamics 18 The paper considers that the number of habitable planets may fluctuate wildly with time due to the unpredictable timing of catastrophic events thereby creating a punctuated equilibrium in which habitable planets are more likely at some times than at others 18 Based on the results of Monte Carlo simulations on a toy model of the Milky Way the team found that the number of habitable planets is likely to increase with time though not in a perfectly linear pattern 18 Subsequent studies saw more fundamental revision of the old concept of the galactic habitable zone as an annulus In 2008 a study by Nikos Prantzos revealed that while the probability of a planet escaping sterilization by supernova was highest at a distance of about 10 kpc from the galactic center the sheer density of stars in the inner galaxy meant that the highest number of habitable planets could be found there 3 The research was corroborated in a 2011 paper by Michael Gowanlock who calculated the frequency of supernova surviving planets as a function of their distance from the galactic center their height above the galactic plane and their age ultimately discovering that about 0 3 of stars in the galaxy could today support complex life or 1 2 if one does not consider the tidal locking of red dwarf planets as precluding the development of complex life 1 Criticism editThe idea of the galactic habitable zone has been criticized by Nikos Prantzos on the grounds that the parameters to create it are impossible to define even approximately and that thus the galactic habitable zone may merely be a useful conceptual tool to enable a better understanding of the distribution of life rather than an end to itself 3 For these reasons Prantzos has suggested that the entire galaxy may be habitable rather than habitability being restricted to a specific region in space and time 3 In addition stars riding the galaxy s spiral arms may move tens of thousands of light years from their original orbits thus supporting the notion that there may not be one specific galactic habitable zone 4 5 6 A Monte Carlo simulation improving on the mechanisms used by Cirkovic in 2006 was conducted in 2010 by Duncan Forgan of Royal Observatory Edinburgh The data collected from the experiments support Prantzos s notion that there is no solidly defined galactic habitable zone indicating the possibility of hundreds of extraterrestrial civilizations in the Milky Way though further data will be required in order for a definitive determination to be made 24 See also editElliptical galaxy Extraterrestrial liquid water Fermi paradox Metallicity distribution function Planetary habitability Rare Earth hypothesis Search for extraterrestrial intelligence Spiral galaxy Terraforming Life habitable zonesReferences edit a b c Gowanlock M G Patton D R McConnell S M 2011 A Model of Habitability Within the Milky Way Galaxy Astrobiology 11 9 855 73 arXiv 1107 1286 Bibcode 2011AsBio 11 855G doi 10 1089 ast 2010 0555 PMID 22059554 S2CID 851972 Choi Charles Q 21 August 2015 Giant Galaxies May Be Better Cradles for Habitable Planets Space com Retrieved 24 August 2015 a b c d e Prantzos Nikos 2006 On the Galactic Habitable Zone Space Science Reviews 135 1 4 313 22 arXiv astro ph 0612316 Bibcode 2008SSRv 135 313P doi 10 1007 s11214 007 9236 9 S2CID 119441813 a b Rok Roskar Debattista Quinn Stinson James Wadsley 2008 Riding the Spiral Waves Implications of Stellar Migration for the Properties of Galactic Disks The Astrophysical Journal 684 2 L79 arXiv 0808 0206 Bibcode 2008ApJ 684L 79R doi 10 1086 592231 S2CID 15219277 a b University of Washington 15 September 2008 Immigrant Sun Our Star Could Be Far from Where It Started in Milky Way Newswise Retrieved September 15 2008 a b c Battersby Stephen November 30 2011 Earth s wild ride Our voyage through the Milky Way New Scientist 2841 Strughold Hubertus 1953 The Green and Red Planet A Physiological Study of the Possibility of Life on Mars University of New Mexico Press James Kasting 2010 How to Find a Habitable Planet Princeton University Press p 127 ISBN 978 0 691 13805 3 Retrieved 4 May 2013 Huang Su Shu April 1960 Life Supporting Regions in the Vicinity of Binary Systems Publications of the Astronomical Society of the Pacific 72 425 106 114 Bibcode 1960PASP 72 106H doi 10 1086 127489 a b c d e f g h i j k Gonzalez Guillermo Brownlee Donald Peter Ward 2001 The Galactic Habitable Zone Galactic Chemical Evolution Icarus 152 1 185 arXiv astro ph 0103165 Bibcode 2001Icar 152 185G doi 10 1006 icar 2001 6617 S2CID 18179704 Clarke J N 1981 Extraterrestrial intelligence and galactic nuclear activity Icarus 46 1 94 96 Bibcode 1981Icar 46 94C doi 10 1016 0019 1035 81 90078 6 Tucker Wallace H 1981 Astrophysical crisis in the evolution of life in the Galaxy In Billingham John ed Life in the Universe Cambridge The MIT Press pp 287 296 ISBN 9780262520621 a b Blair S K Magnani L Brand J Wouterloot J G A 2008 Formaldehyde in the Far Outer Galaxy Constraining the Outer Boundary of the Galactic Habitable Zone Astrobiology 8 1 59 73 Bibcode 2008AsBio 8 59B doi 10 1089 ast 2007 0171 PMID 18266563 Ward Peter Brownlee Donald 2003 12 10 Rare Earth Why Complex Life is Uncommon in the Universe Springer pp 191 220 ISBN 9780387952895 Gonzalez G 2001 The Galactic Habitable Zone Galactic Chemical Evolution Icarus 152 1 185 200 arXiv astro ph 0103165 Bibcode 2001Icar 152 185G doi 10 1006 icar 2001 6617 S2CID 18179704 Charles H Lineweaver Yeshe Fenner and Brad K Gibson January 2004 The Galactic Habitable Zone and the Age Distribution of Complex Life in the Milky Way Science 303 5654 59 62 arXiv astro ph 0401024 Bibcode 2004Sci 303 59L doi 10 1126 science 1092322 PMID 14704421 S2CID 18140737 a b c d e f Lineweaver C H Fenner Y Gibson B K 2004 The Galactic Habitable Zone and the Age Distribution of Complex Life in the Milky Way Science 303 5654 59 62 arXiv astro ph 0401024 Bibcode 2004Sci 303 59L doi 10 1126 science 1092322 PMID 14704421 S2CID 18140737 a b c d e Vukotic B Cirkovic M M 2007 On the timescale forcing in astrobiology Serbian Astronomical Journal 175 175 45 arXiv 0712 1508 Bibcode 2007SerAJ 175 45V doi 10 2298 SAJ0775045V S2CID 56156159 Collar J I 1996 Clumpy Cold Dark Matter and biological extinctions Physics Letters B 368 4 266 269 arXiv astro ph 9512054 Bibcode 1996PhLB 368 266C doi 10 1016 0370 2693 95 01469 1 S2CID 119377346 a b c Mullen Leslie May 18 2001 Galactic Habitable Zones NAI Features Archive Nasa Astrobiology Institute Archived from the original on April 9 2013 Retrieved May 9 2013 a b c Sundin M 2006 The galactic habitable zone in barred galaxies International Journal of Astrobiology 5 4 325 326 Bibcode 2006IJAsB 5 325S doi 10 1017 S1473550406003065 S2CID 122018103 Pavlov Alexander A 2005 Passing through a giant molecular cloud Snowball glaciations produced by interstellar dust Geophysical Research Letters 32 3 L03705 Bibcode 2005GeoRL 32 3705P doi 10 1029 2004GL021890 Raymond Sean N Quinn Thomas Lunine Jonathan I 2005 The formation and habitability of terrestrial planets in the presence of close in giant planets Icarus 177 1 256 263 arXiv astro ph 0407620 Bibcode 2005Icar 177 256R doi 10 1016 j icarus 2005 03 008 S2CID 15547409 Forgan D H 2009 A numerical testbed for hypotheses of extraterrestrial life and intelligence International Journal of Astrobiology 8 2 121 131 arXiv 0810 2222 Bibcode 2009IJAsB 8 121F doi 10 1017 S1473550408004321 S2CID 17469638 External links edit nbsp Media related to Habitable zone at Wikimedia Commons Retrieved from https en wikipedia org w index php title Galactic habitable zone amp oldid 1205168694, wikipedia, wiki, book, books, library,

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