Date: 01-24-92  20:29
From: David Galea
Subj: Habitable Planets, from the January 1992 JBIS.

 * Originally dated 22 Jan 1992, 9:05

From: klaes@mtwain.enet.dec.com (Larry Klaes)
Organization: Digital Equipment Corporation


        The following posting is a summary written by my friend and
    co-worker, Drew LePage, of an article in the January 1992 issue of
    the JOURNAL OF THE BRITISH INTERPLANETARY SOCIETY (JBIS), Volume 45,
    Number 1.  Titled "An Estimate of the Prevalence of Biocompatible
    and Habitable Planets", it is authored by M. J. Fogg.

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        There is a very interesting article in the January 1992 edition
    of the JOURNAL OF THE BRITISH INTERPLANETARY SOCIETY (JBIS) on the
    likelihood of various types of stars having habitable or biocompatible
    planets.  A biocompatible planet is one where the long term presence
    of surface liquid water provides environmental conditions suitable for
    for the origin and evolution of life.  There are three subsets of
    biocompatible planets:

  * Juvenile Martian - As the name implies, it is a planet with condition
    similar to those found on Mars early in its life.  The planet would
    receive between 27% and 75% of the light we presently receive from the
    Sun and possess plate tectonics or some other geochemical carbon cycle.
    Mars was this type for its first one billion years.

  * Juvenile Terran - Again as the name implies, this is a planet with
    conditions similar to those found on the early Earth.  The planet
    would receive between 75% and 95% of the light we presently receive
    from the Sun and be geologically active.  Earth was this type of planet
    for its first four billion years (i.e. during the Precambrian period).

  * Habitable - This is a planet with Earthlike conditions.  The planet
    would receive between 95% and 110% of the light we receive and be
    geologically active.

        The author of the study collected the results of various studies
    to determine what conditions produce biocompatible and habitable
    planets, the evolution of stars and the effects on planetary environ-
    ments, the likely distribution of planets in other systems, as well
    as others.  The results of the author's simulations indicate the
    following:

  * Habitable planets can exist around stars with 0.8 to 1.8 times the
    mass of the Sun.

  * Biocompatible planets can exist around stars with 0.5 to 1.8 times the
    mass of the Sun.

  * Habitable planets may occur around >3% of the stars between 0.85 and
    1.45 times the mass of the Sun.

  * Biocompatible planets may occur around >30% of the stars between 0.8
    and 1.25 time the mass of the Sun.

        If only single stars possess planets:

  * There would be one habitable planet for every 413 stars.

  * The mean distance between systems with habitable planets would be
    31 light years.

  * There would be one biocompatible planet for every 39 stars.

  * The mean distance between systems with biocompatible planets would be
    14 light years.

  * There would be about 362 biocompatible (of which 34 would be habitable)
    planets within 100 light years of us.

        If planets could form in multiple star systems:

  * There would be one habitable planet for every 196 stars.

  * The mean distance between systems with habitable planets would be 24
    light years.

  * There would be one biocompatible planet for every 18 stars.

  * The mean distance between systems with biocompatible planets would be
    11 light years.

  * There would be about 763 biocompatible (of which 71 would be habitable)
    planets within 100 light years of us.

        The author goes further and calculates the probability of the
    nearer stars having biocompatible or habitable planets.  Assuming that
    planets can form in multiple star systems the following probabilities
    were calculated:

  Name          Distance (LY)   Type    Habitable   Biocompatible

  Alpha Centauri A     4.38     G2V    7.8%         44%
  Alpha Centauri B     4.38     K6V    4.4%         38%
  Epsilon Eridani     10.69     K2V    0.6%         34%
  61 Cygni A          11.17     K5V    0.0%          5.8%
  61 Cygni B          11.17     K7V    0.0%          0.3%
  Epsilon Indi        11.21     K5V    0.0%         18%
  Lacille 9352        11.69     M2     0.0%         <0.3%
  Tau Ceti        11.95     G8V    1.5%         35%
  Lacille 8760        12.54     M1V    0.0%          1.5%
  Groombridge 1618    15.03     K7     0.0%          2.5%
  70 Ophiuchi A       16.73     K1     4.4%         38%
  70 Ophiuchi B       16.73     K6     0.0%         16%
  36 Ophiuchi A       17.73     K0V    0.0%         28%
  36 Ophiuchi B       17.73     K1V    0.0%         27%
  36 Ophiuchi C       17.73     K5V    0.0%          9.0%
  HR 7703 A       18.43     K3V    0.0%         27%
  Sigma Draconis      18.53     K0V    1.5%         35%
  Delta Pavonis       18.64     G5     5.1%         39%
  Eta Cassiopeiae A   19.19     G0V    3.9%         38%
  Eta Cassiopeiae B   19.19     M0     0.0%          0.7%
  HD 36395        19.19     M1V    0.0%          0.5%
  Wolf 294        19.41     M4     0.0%         <0.3%
  +5301320 A          19.65     M0     0.0%          0.6%
  +5301320 B          19.65     M0     0.0%          0.5%
  -45013677       20.6      M0     0.0%         <0.3%
  82 Eridani          20.9      G5     4.4%         38%
  Beta Hydri          21.3      G1     7.5%         35%
  HR 8832         21.4      K3     0.0%         23%

        Assuming that the author's simulations and calculations are
    correct, there could be as many as 5.6 BILLION biocompatible planets
    in our galaxy of which about 500 MILLION are habitable.  And, as the
    above table shows, the nearest biocompatible planet could only be
    4.38 light years away.

        Drew LePage

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 * Origin: The AntiGravity Club - We won't let you down. (9:1030/10)