Lesson 9:
Other Worlds, Other Life
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9.5
Looking for Life in all the Right Places;
Revisiting the Drake Equation
The Search for Extraterrestrial Intelligence (SETI) project has as its basis the fact
that we could detect a beamed radio signal of the type we are able to generate now
from anywhere in the Milky Way Galaxy. Detecting simple life or a non-technical
civilization is expected to be considerably harder, but at least some of the factors
used in generating an estimate of the possible numbers of targets are the same.
The exobiologists' definition of life is this:
A self-replicating system subject to Darwinian evolution.
This is not the same as developing radio, TV and powerful over-the-horizon radar beacons.
Frank Drake attempted to rationalize the estimation of the possible number N of communicating
civilizations in our galaxy (forget other galaxies...) by dividing it up into a series
of possibly easier to handle estimates.
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N |
number of technical civilizations in the Milky Way Galaxy with whom we might expect to
communicate
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R* |
average rate of star formation in the Milky Way, in units of stars per year
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fp |
fraction of stars with planetary systems
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ne |
number of planets per system with suitable ecologies (liquid water...)
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fl |
fraction of such planets on which life actually occurs
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fi |
fraction on which intelligent life arises
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fc |
fraction where intelligent beings develop capability for interstellar communication
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Lc |
mean lifetime of such communicating civilizations
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The average star formation rate and the fraction of stars with planetary systems
can be estimated rather accurately from standard astronomical theory. The number
of planets per system suitable for life falls under a new field called "astrobiology".
While it is at present more difficult to quantify, in twenty years it should be
as well-defined as the first two factors.
The fraction of suitable planets on which life actually develops is a specialized
topic of organic chemistry and biochemistry, a field called exobiology, the search
for the origin of life.
The remaining terms in the Drake Equation are sociological in nature and do not concern
us in the simple search for any life. It has been noted that the reliability of
estimates of theses various factors declines rapidly going from
R* to
Lc. We may, however, need an
estimate for the expected lifetime, L
, for any life on a planet in order to calculate
the possible number of current locales of life in the Milky Way.
The estimated number of stars in the Milky Way,
N*, has not changed much in the
50 years since we realized the nature and extent of our Galaxy and other galaxies. The
Milky Way is a largish spiral galaxy, like its companion the Andromeda galaxy, with
about 100 billion (1011) stars.
(Sometimes you see the number as 200 billion, but 100 billion
is almost certainly good to within an order of magnitude.) This number is derived by
counting the stars within several small patches of sky in the galactic plane and
extrapolating to the whole galaxy. The age of the Milky Way,
T*, is still
accepted by most astronomers to be some 10 billion years, although the details of events
between the condensation of matter after the Big Bang some 14 billion years ago and the
formation of the first galaxies are still a little hazy. Recent Hubble images suggest
galaxy (or star) formation began earlier than was previously believed. You'll probably
get no arguments with a 12 billion year old Milky Way. In any case, it's the rate of
star formation,
R* = N*/ T* that we're
after:
R* = N*/ T*
= 100/12 to 200/10
= 8-20 stars / year.
Bear in mind that this estimate for R*
is by far the best estimate that we will encounter in this
discussion. Also bear in mind that this average rate may be grossly different from the
star formation rate 5 billion years ago when our Sun was forming. Further bear in mind
that stars age at different rates and will have different habitable zones at different
phases of their lifetime. None of these factors are included in our simplified
accounting.
Then, using the age of life on the Earth as an estimate,
R* x
L =
(8-20 stars/year) x (3.9 billion years)
= 30-77 billion stars
which might possibly host life forms in the Milky Way. But just how typical is our Sun
and its system of planets?
The factor fp is an
attempt to answer this last question: what fraction of stars have planetary systems?
Startling progress in this area has been made in just the last few years.
Realizing that then-current technology would not permit the direct observation of a
faint planet near a relatively dazzling (a billion times brighter!) star, astronomers
plotted the positions of nearby stars for decades, hoping to measure a "wiggle" which would
indicate one or more dark companions. In the best-known case, repeated observations of
Barnard's star from 1940 to 1970 appeared to capture a sinusoidal oscillation of about
0.05 arcseconds amplitude in the star's proper motion of 300 arcseconds across the sky.
(The moon is 1800 arcseconds wide). Five hundredths of an arcsecond was, at that time,
at least 10 times better than the best seeing that was available. This acccuracy was the
result of many repeated observations and statistical combination of results, some 3000
photographic plates analyzed by Van de Kamp.
This technique, like most others, is most sensitive to the case of one or two very
massive planets orbiting relatively close to their star. Consequently, the theories of the day
led to sets of simulated solar systems (S. Dole, 1970, Icarus, 13, 494-508) which,
not too surprisingly, all looked fairly similar to our solar system, dominated by
gas giants. The important point here is that the simplest interpretation of the sparse
results from these studies did not require Earth-like planets. And the sparseness of the
results led to fears of a low fp
.
As instrumentation has improved, and particularly with the availability of observations
from space, it has been possible to obtain direct images. If not yet of planets themselves,
at least of the swirling gas and dust clouds around young stars, the stellar nebulae
which are believed to be the precursors of planetary systems. Starting with Beta Pictoris
from infrared observations and then with the sudden confirmation of some 153 such
protoplanetary disks or "proplyds" in 1992 in the Orion Nebula by Hubble observations,
this has been a fruitful avenue of approach. These disks are 3-8 times the size of our solar
system and formed within the last million years. We still did not see any dense spots
in these clouds that might be condensing planets, but the number of disks seen has raised
new hopes for a large fp
.
Another modern search technique has relied on spectroscopy rather than position
measurements or direct imaging. Here we look at small shifts in the wavelengths of stellar
spectral features, as the star is alternately pulled towards us when a massive
planet is on the near side, or away from us when it is on the far side. These measurements
are a bit easier in that spectral observations are routinely made to one part in 10,000.
But there is the added complication of the Earth's orbital motion and the relative
motion of the Sun and the subject star. A potentially more serious complication is
to factor in the unknown "breathing" mode of the star, which causes the surface to pulse
in and out. Jupiter causes the Sun to shift velocity by 12.5 m/sec or 28 mph. Solar
breathing amounts to some 5 m/sec.
Spectrometers are subject to point-spread function (PSF) errors (the initial Hubble
smear was an extreme example) and a 1% error leads to a 25 m/sec inaccuracy. Optimizing computer
code to process out this error and spectrometer improvements over a period of 8 years
led the team of Geoff Marcy and Paul Butler to 3 m/s accuracy. They narrowly missed discovering
the first planet around a sun-like star, 51 Pegasi. This discovery, by Swiss astronomers Michel
Mayor and Didier Queloz, found a half-Jupiter-mass planet closer than Mercury is to the Sun,
so the orbital period was days, not years. This was not expected from the theoretical models of
solar nebula condensation of Dole and others, and was a real shocker. Marcy and Butler
quickly went back through their old observations and found six more cases of planets
orbiting Sun-like stars.
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Some Recently Discovered Extrasolar Planets |
|
Star |
Star Mass
(Solar masses) |
Planet Mass
(Jupiter masses) |
Avg. Distance
from star
(AU) |
Orbital
Period
(days) |
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51 Pegasi |
|
0.5 |
0.05 |
4.23 |
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Gliese 876 |
0.33 |
1.6 |
0.2 |
61 |
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Rho Coronae Borealis |
1 |
1.1 |
0.24 |
40 |
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Tau Bootis |
1.2
|
3.64 |
0.4 |
3.3 |
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Upsilon Andromedae |
|
0.63 |
0.5 |
4.6 |
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55 Rho Cancri |
0.8-1.2
|
0.85 |
0.12 |
14.7 |
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70 Virginis |
|
6.84 |
0.47 |
116.7 |
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16 Cygni B |
.99
|
1.74 |
1.70 |
803 |
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47 Ursae Majoris |
1.05
|
2.42 |
2.08 |
1095 |
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Sol |
1 |
1 |
5.2 |
4329 |
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Close-in, massive planets tug harder at their stars (51 Pegasi tugs at 53 m/sec,
Jupiter at 12.5 m/sec) and are thus easier to detect.
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