Misconceptions Regarding
SETI, Dyson Spheres and the Fermi Paradox

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In the July, 2000 issue of Scientific American, the article "Where are They?", by Ian Crawford [Cra00] contained a sidebar by Andrew J. LePage, "Where They Could Hide" [LeP00].  These articles pointed to a chart, "Results of SETI Programs" that indicating that radio searches for Kardashev Type II Civilizations^[FN1], leaking or effectively transmitting at > 10²⁵ W had been "Thoroughly Searched" for within the local group of galaxies (a distance of 5×10⁷ light years).  LePage also claims, "Before scientists began to look, they thought that type II or III civilizations might actually be quite common. That does not appear to be the case.".  Unfortunately, as I shall show, there are flaws in this analysis.
 

Radio SETI

The first question is: "What fraction of its available resources does a civilization devote to extraterrestrail communications?".  If you believe that there might exist significantly superior civilizations that might be distributing the "Encyclopedia Galactica", then you presumably would want to devote a significant amount of resources to transmitting beacons that indicate "Hey, here is a location of intelligence in the galaxy", as well as listening to any return signals that might be providing the blueprints for fusion reactors or interstellar spaceships.  As many scientists will point out it is a waste of time and energy to attempt to convert non-believers in a rational approach into believers in a rational approach.  So it is only of interest to transmit signals to locations, if there is evidence there, that support for the concept of the existence of superior alien species is present.  Since we do not transmit significant "locator beacon" signals, it is unlikely that extraterrestrials would be transmitting signals to us.  While nearby aliens might realize that we have made the transition to a radio communicating civilization, our signals that have reached them thus far would bear no indication that we realise that "they" might exist or are waiting for communications from them.

A Type II civilization with 10²⁶ W certainly doesn't devote 100% of its power to radio communication with inferior civilizations!  For example, we can take Arecibo that has a 2500 kW (~10⁶ W)transmitter, that can be focused into a beam of ~10¹⁵ W. The ratio of that transmitter power to the power production of our sub-Type-I civilizations is about 10^-14 (assuming we were continuously transmitting from Arecibo, which we aren't).  If Type II civilizations transmitted at the same ratio, the signal power would be around a terawatt.  That limits the detection of these civilizations to within 10-100 ly on the distance scale.  For a civilization to radiate at a Type II level (assuming the 10^-14 ratio), it would have to be beyond a Type III level (> 100 trillion stars) for it to be able to waste communication energy at that level.  As there are only several hundred billion stars in our galaxy, this seems very unlikely.  When discussing the effective power transmitted by ETI civilizations, it is important to state clearly what the assumptions are for the return-on-investment.  We (humans) don't waste a lot of energy communicating with entities significantly below our level.  We are still several orders of magnitude away from being even a Type I civilization.  The idea that any civilization above that level would waste its energy communicating with us requires a very big leap of faith.

Optical and Infrared SETI

A careful investigation of the criteria used for these studies will reveal they can be used to justify only very limited(!) conclusions regarding Type II Civilizations.  The methods used Jugaku and Nishimura are to identify stars that have a very slight slight excess of IR radiation relative to visible radiation.  This strategy is based on a conclusion by Michael D. Papagiannis, one of the founders of IAU Commission 51, in [Pap85] which stated:

"From the above (calculations) it follows that the construction of a spherical shell around a star from the material present in its planetary system is an impossible task. What is possible, however is to have a large number of independent space structures in orbit around the star, but these would intercept only a relative fraction (~1%) of the star's radiation.  Consequently such stars, would display a normal spectrum with only a small excess in the infrared."

"One should expect that, within a few thousand years of its entering the stage of industrial development, any intelligent species should be found occupying an artificial biosphere which completely surrounds its parent star."

"The most likely habitat for such beings would be a dark object, having a size comparable with the Earth's orbit, and a surface temperature of 200 deg. to 300 deg. K. Such a dark object would be radiating as copiously as the star which is hidden inside it, but the radiation would be in the far infrared, around 10 microns wavelength."

"Since radiation at any temperature above 3^oK is wasteful and a squandering of natural resources, the higher the civilization, the lower the infrared radiation.  We should look for extended sources of 4^oK radiation.  There should be very few natural such sources."

"A solid shell or ring surrounding a star is mechanically impossible.  The form of "biosphere" which I envisaged consists of a loose collection or swarm of objects traveling on independent orbits around the star.  The size and shape of the individual objects would be chosen to suit the inhabitants.  I did not indulge in speculations concerning the constructional details of the biosphere, since the expected emission of infrared radiation is independent of such details."^[FN2]

Perhaps unknown to Papagiannis, was a very detailed earlier work by Dr. K. G. Suffern of the Department of Applied Mathematics at the University of Sydney  analyzing various characteristics for Dyson shells [Suf77].  While the general tone of the anaylsis is to draw conclusions similar to those of Papagiannis, Suffern concluded:

"Of course this is not an objection in principle to optically thick Dyson spheres because in principle the radiation from any black body with a temperature T > 2.7 K is thermodynamically useful. It just points out a practical difficulty that thermodynamics imposes upon optically thick biospheres."

It is safe to say that Dyson's use of the term "dark object" and the subsequent popularization of "hallow balls" by Science News Letters [Dys60b], rather than his intended "shells" [Dys60c], continues to generate confusion, because even in 1999, talented engineers such as Robert Zubrin make such statements as "Dyson Spheres are impractical" and "the implausibility of the Dyson Sphere is so extreme that it has even been criticized by science fiction writers." [Zub99, p. 241].  Dyson Shells are implausible or impractical only if you envision them as true spheres or primitive human habitats.  And some science fiction writers, by stretching their imagination to include engineering methods such as force transfer using high speed circulating fluid streams, have described plausible Dyson spheres [Poh75]!

O'Neill Habitats

The Papagiannis and Suffern calculations are based on the assumption that we are limited to the available "construction material" present in our solar system. Papagiannis uses a figure of 10 Earth masses, while Suffern uses a figure of 30 Earth masses [from Bra76].  The author estimates that the solar system contains minimum of 3-10 times the amount of construction material considered by Suffern and Papagiannis (~100 Earth masses; 5.9×10²⁶ kg).  Why is this?

During the last 25 years, it has become clear that the view of traditional construction materials (iron, aluminium, glass) is somewhat limited, and that structures will ultimately be constructed out of materials with more robust physical properties.  These include diamond and saphire as well as ceramics including carbides, oxides and nitrides.  So substances such as methane, ammonia, carbon dioxide and carbon monoxide, which are abundant in the bodies with orbits beyond Saturn are more useful for construction purposes than was previously thought.  Water ice is also present in significant quantities in these bodies and may be considered a structural material if it is kept significantly below its freezing point.  In our solar system, the excess of hydrogen and oxygen over carbon (and other metals) dictates that the most efficient materials usage must use water in lieu of other materials as much as possible.  In addition, the most abundant elements, hydrogen and helium may be used as radiation shields, as highly pressurized gases or possibly in liquid or solid form, leaving other materials available for more important uses.

The classic O'Neill habitat contains 4% aluminium, 2% glass, 10% water, and 82% soil, rock and construction materials [ONe74].   How can we substitute advanced materials into these habitats?  The greatest mass utilization would result from constructing all structural elements out of carbon (as diamond or buckytubes), saphire (Al₂O₃), silicon carbide (SiC) and hematite (Fe₂O₃).  Metals would only be used in situtations requiring great ductility or electrical conductivity.  Diamond has an elasticity 5× that of high carbon steel and 13× that of aluminum alloys.  Replacing the aluminum and steel in the original designs with diamond and saphire (which are also more abundant) reduces the structural material mass requirements by 10 times or more.

For example, advanced colonies could contain diamond walls of sufficient strength to hold an atmosphere, surrouded by silica aerogel insulation to keep heat in and cold out, surrounded by ice containing bubbles filled with high pressure hydrogen gas as a radiation and meteor shield, coated with ultrathin high efficiency solar cells that efficiently harvest incoming visible and infrared photons and covert them into electricty.

The traditional agriculture methods envisioned by O'Neill are not those that would be used by an advanced civilization.  The soil requirements are presumably those required for growing food.  Yet we know that traditional foods may be grown quite effectively hydroponically [Hyd00].  That would eliminate the soil requirement completely and replace it with a water requirement.  Water as previously noted is one of the most abundant materials in the solar system.  If the population adapts to non-traditional foods, or food processing can manipulate basic ingredients into traditional forms, one may envision very thin orbiting pancakes (agrosats) with glass surfaces facing the sun and ceramic radiators facing away from the sun filled with water containing algae like organisms that are bioengineered to manufacture and store a completely balanced set of nutrients.  These would be very thin structures, perhaps only a few cm thick.  These agrosats could periodically dock with habitat colonies where the nutrients would be harvested and the agrosats refertilized with carbon dioxide, ammonia and trace elements.

Traditional agriculture is very inefficient from an energy standpoint.  The biochemical predictions of photosynthetic energy harvesting efficiency are quite good, theoretically 35% [Mat90, pg 664].  But if U.S. agricultural land is ~9.5 million acres [TWA99] (3.8×10¹⁰ m²), and is receiving an average of 400 W/m² for 8 hours a day (4.4×10¹⁷ J/day) and is used to feed perhaps 500 million people (allowing for food exports), 2400 calories (1×10⁷ J/day), this gives an overall agricultural efficiency of 1.1%.  This could be increased by perhaps 5 times by eliminating fish, poultry and meat that waste extensive amounts of energy in the production of their food substance.  This increase would be offset by calculations that included the current energy contribution of petroleum based inputs (fertilizer and fuel)  into the farming and harvesting of food resources.  No advanced civilization will subsist on traditional agriculture for many years.

Advanced societies would attempt to make the most efficient use of the available energy as possible.  Intially, this could be based on multi-layer solar cells (~30-40% efficiencies).  Ultimately it may use solar concentrators with high temperature heat engines  that radiate at the background radiation temperature.  The temperature differential (2900°K - 3°K), potentially allows ~99% efficiencies.  Harvested power could be used to produce hydrogen ions (H⁺) that are utilized by mitochondria- or bacteria-like bioreactors to synthesize ATP and subsquently carbohydrates and proteins. Ultimately the losses involved in these chemical processes might drive civilizations to engineer individuals to be able to utilize sunlight or electricity directly.  There are only mental barriers that would prevent extraterrestrial bioengineers from producing cloroplast-like energy conversion units in their own skin.  Humans unfortunately have too little skin area to power their ~100W metabolisms.  They would require the addition of wings with increased surface area, or lower operating temperatures to pursue this approach.

Thus if we divide the multi-purpose O'Neill style habitats into powersats and agrosats that harvest most of the available sunlight and habitats that house populations at New York or Tokyo density levels then the resources of a solar system may be utilized much more efficiently.

So, only primitive civilizations such as ours (circa 1974) would limit themselves to collecting less than 1% of the solar output of their star.  Using advanced materials and technologies, advanced Type-II civilizations would harvest all of the power produced by their stars as Dyson has suggested.  As they evolve their civilization, making it increasingly efficient, they would radiate heat at ever lower temperatures, potentially approaching the background temperature as Minsky and Suffern have pointed out.

Life and its Forms

As NASA scientists are beginning to engineer artificial life [Poh99], and life supporting chemistries that do not require liquid water have been postulated [Fre79, Lew98], we can envision either engineering or discovering life forms that can exist outside temperature ranges predicted by Dyson.  Ultimately if nanotechnology is feasible, we may envision civilizations that operate over temperatures ranging from 3^oK to 2900^oK or higher.

The time spans for civilizations of intelligent beings to evolve from very primitive states (e.g. Homo erectus) to the limits imposed by classical laws of physics are very short (~10⁵-10⁶ years) compared with the galactic time scales (~10¹⁰ years).  Work by the author [Bra99] has shown, that a Type II civilization could rapidly form an highly integrated meta-mind with a computational capacity ~10³⁴ times that of a human brain.  This meta-mind would occupy the computers of star-enveloping solar power satellites that do effectively hide the star.  So exploration for and conclusions regarding extraterrestrial intelligence, Dyson Shells, and the Fermi Paradox are unlikely to be valid if one assumes an anthropocentric starting point as most individuals unconsciously do.

Conclusions should only be made if one assumes capabilities and capacities at the limits of known (experimentally validated) laws of physics.  Unfortunately, astronomers and SETI researchers continue to look for signs of life assuming  human perspectives (i.e. visible stars) rather than perspectives dictated by the limits of the laws of physics.  Only whole sky surveys, with long exposure times in the mid-far IR ranges are likely to detect low temperature Dyson Shells. Unfortunately, even expensive telescopes, like SIRTF, that will not be available until 2002, the detectors for these wavelengths, typically, Si:As, Ge:Ga and stressed Ge:Ga are still very primitive^[FN3].  It is doubtful that even very advanced telescopes, still in the planning stages, would have the capabilities required to provide definitive evidence for or against these objects.

As the LePage & Crawford articles fail to examine these points in detail they should be viewed as editorial commentary on SETI rather than definitive statements.

The editors of Scientific American claim "ZIP, ZILCH, NADA has come out of any aliens with whom we share the galaxy. Searches for extraterrestrial intelligence have at least partially scanned for Earth-level radio transmitters out to 4,000 light-years away from our planet (yellow circle) and for so-called type I advanced civilizations out to 40,000 light-years (red circle). The lack of signals is starting to worry many scientists".  The lack of radio transmissions is unsurprising if you comprehend the capabilities of civilizations that could afford to expend large quantities of energy communicating with distant civilizations at a much lower level.  This isn't comparable to adult humans communicating with babies or dogs or dolphins or birds (that have roughly the same order-of-magnitude intellectual capacities).  Advanced civilizations that have the energy to throw away in communicating with us, would be comparable to humans communicating with mice or insects or even bacteria. In short, they are unlikely to be interested in constructing the transmitters or providing power to them.  Current SETI search strategies almost all implicitly assume that civilizations remain around our level of development for a very long time (hundreds of years)^[FN4].  If instead technological civilizations make a rapid transition from pre-Type I to Type II as appears likely to be the case [Vin93], then these efforts are highly misguided. So if "worry" is required, it should be about why scientists are so shortsighted.

LePage has devised a system [LeP96] for rating stars as potential SETI targets which ignores the basic problem that almost all advanced technological civilizations should not have a "visible stars"!  Brown dwarfs [Bas00], are estimated to be twice as abundant as stars [Kir00].  Because they are smaller and cooler than stars, they are more easily disassembled.  If we had the technology to conduct extensive surveys of brown dwarfs^[FN5] we might find that many of them are being disassembled to supply fuel and construction materials for meta-minds.  The unresolved problems of the missing baryonic dark matter and the gravitational microlensing observations, suggesting 200 billion "masses" orbiting our galaxy [Alc00], hint at the possibility that such entities may exist.  Thus we may conclude, there is still plenty of room for progress in SETI.

Footnotes

• In 1964, Nikoli Kardashev proposed there were 3 levels of technological civilizations, Level I: using the entire power available on a planet, Level II: using all the power available from a star and Level III: using all the power available in a galaxy.  For further Information, see the original reference [Kar64].
• The infrared emission is largely independent of the shape and architecture of the individual objects but not their operating temperature!
• The SIRTF arrays are 32×32 and 2×20 for example.  Such small arrays either provide limited resolution or make whole sky surveys extremely time consuming.  See: http://sirtf.jpl.nasa.gov/SciUser/MIPS/mips_intro.html
• This is the "L" parameter from the classic Drake Equation.  Unfortunately, all radio searches assume "L" must be leakage time (for pre-Type II) or intentional broadcast time (for Type-II).  The observational capabilities of Type-II would allow them to communicate using highly efficient directional lasers, presumably to other Type-II civilizations.  Lasers are prefered for energy reasons and higher information capacity.  The only use a Type-II civilization would have for radio communications is to communicate with another Type-II civilization through a dust cloud that would attenuate a laser beam.  Type-II civilizations do not broadcast to pre-Type-I civilizations because it is a waste of energy and matter due to the intelligence scale differences.  There may be rare cases of leakage from pre-Type I civilizations, but these are likely to be brief as civilizations develop the technologies (coaxial cable, fiber optics, low-power spread spectrum radio) that eliminate most forms of leakage.  If we wanted to look for leakage signals, the best choice might be radar signals occasionally used for astronomy observations.  If our civilization is an example, our "leakage" longevity is likely to be less than 100 years.  So for radio SETI to have failed, it must have failed to detect a civilization at approximately our level of development within a few hundred light years of us (the limit of current detectability).  The probabilities of that occuring seem to be quite small.
• Current technologies only allow us to view brown dwarfs out to distances of several hundred light years.

References

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See online document @ ADS 1977PASAu...3..177S.
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