The Astonishing Redness of Kuiper-Belt Objects.
Abstract:The recently reported
extreme redness of a class of Kuiper-belt objects could be yet another indirect
indication of extraterrestrial microbiology in the outer solar system.
Look not thou upon the wine when it is red, when it giveth his colour in
the cup,…
At the last it biteth like a serpent, and stingeth like an adder. — Proverbs, xxiii. 31
At the last it biteth like a serpent, and stingeth like an adder. — Proverbs, xxiii. 31
The existence of an ancient
reservoir of cometary-type objects in stable circular orbits lying beyond the
orbit of Neptune is now beyond dispute. Tegler and Romanishen (1998)
have recently made the remarkable discovery that these so-called Kuiper-belt
objects include some that are exceedingly red. Accurate photometic studies
using CCD techniques have revealed two distinct classes of such objects. One
class is comprised of objects with surface colours that are only very slightly
redder than the sun, whilst the other contains objects that are said to be
"the reddest objects of the Solar System". The fact that the
distribution of colour amongst these objects does not correlate with
heliocentric distance indicates that the intensity of solar radiation
does not play an important role in the colouring process.
The
so-called reddest objects have a B-V colour excess relative to the Sun
typically of ~ 0.65 mag, and a V-R colour excess of ~ 0.4.
This implies that the ratio of reflectivity at the wavelengths 4500A and 6500A
is
f =
R(6500A)/R(4500A) » 2.5 (1)
Table 1
compares this value with reflectiviy ratios extracted from the data of
Tholen et al. (1986) for a representative set of comets and D-type
asteroids. From Table 1 we see that the surfaces of comets and asteroids fall
significantly short of meeting the condition implied by (1). Table 2 sets out
experimentally determined values of the same ratio f for several different
types of laboratory materials (CRC Handbook of Chemistry and
Physics, 54th ed., 1973; Larson and Fink, 1977). We note from
here that some mineral surfaces could come close to satisfying (1), but by far
the best candidates for producing redness are naturally occuring pigments as
typified by the data for 'ripe pear' and 'ripe peach'.
Table 2 also
includes data for irradiated hydrocarbon mixtures (Andronico et al.,
1987). The relevant values of f range from 3.3 to 1, decreasing with increasingradiation
dose beyond a certain point. Generally similar results are reported for
irradiation with high-energy photons rather than nucleons. In all cases colours
ranging from 'yellow' to 'brown' can be generated under carefully controlled
conditions, and with precisely chosen cut-off values of radiation doses. On the
basis of such laboratory data one could thus conclude that prolonged exposure
to high-energy radiation, as occurs in interplanetary space, would lead
eventually to the appearance of a grey or neutral colour. One might try to
retrieve the case for radiation colouring by invoking meteorite and
micrometeorite impacts. Such impacts, it could be said, arrests this greying
process by continually exposing a pristine cometary surface that will be
subject only to brief interludes of irradiation. But it is clear from Table 1
that the colours of real comets exposed to the interplanetary environment do
not bear testimony to such an effect. Indeed Halley's comet and other
long-period comets that spend most of their time in the outer regions of the
solar system have mostly neutral colours, whilst the shortest period comets
show reddening, albeit to a minor degree. From Table 2 it is clear that the
reflectivity ratio given by (1) is consistent with the presence of highly
absorptive organic chromophores (pigments) that have their absorption peaks
distributed over green to red wavelengths.
Table 1
Reflectivity
ratios for comets and asteroids
Object
|
Reflectivity
Ratio,
R(6500A)/R(4500A)
|
Comets,
period < 20 yr
|
1.26
|
Comets,
period > 35 yr
|
1.11
|
P/Halley
(Period 76yr)
|
1.00
|
D-type
Asteroids(Mean)
|
1.16
|
Kuiper-Belt
Red Class
|
2.50
|
Table 2
Reflectivity
ratio, f , for laboratory systems
Laboratory
system
|
Reflectivity
Ratio,
R(6500A)/R(4500A)
|
Pyroxene
|
1.58
|
Olivine
|
1.63
|
Ripe pear
|
3.67
|
Ripe peach
|
4.15
|
Irradiated
organics
|
3.30
decreasing with dose to 1.0
|
For many
years the present authors have maintained that red colorations of planetary
ices, for example the surface of Europa, could most plausibly be explained on
the basis of biological pigments (Hoyle and Wickramasinghe, 1983, 1997;
Hoover et al., 1986). Such pigments will be continually regenerated and
brought up to the surface as long a biological activity persists. Suitable
candidates for such pigmented microorganisms could be found among the Antarctic
snow-ice algae Chlamydomonas, and diatoms. These organisms, which produce
brownish and reddish colorations throughout the polar regions, might well serve
as an analogue for the colours of icy bodies in the Kuiper belt. It may be
relevant in the present context that diatoms are able to replicate and to carry
out photosynthesis beneath an ice crust, operating at light levels of less than
1% that at the surface (Hoover et al., 1986).
We have
argued elsewhere that radioactive heat sources present in primordial solar
material would inevitably produce melting of ices in the interiors of comets
(Hoyle and Wickramasinghe, 1983; Wallis and Wickramasinghe, 1992). The larger
objects amongst the comets, giant comets with radii greater than, say 50km, may
also be appropriate representations of Kuiper-belt objects. Such objects could
retain interior lakes beneath an ice crust for timescales that may even exceed
the age of the solar system. Anaerobic bacterial activity in subsurface lakes,
leading to the build-up of high-pressure gas pockets, could cause sporadic
cracking of an overlying ice layer. And this in turn leads to the transport of
biological pigments to the surface.
The classes
of red and grey Kuiper-belt objects discovered by Tegler and Romanishen could
thus mark out a simple distinction between objects that are biologically active
from those that are not. In objects where biological activity has ceased the
red pigments would rapidly degrade to become grey.
References
Andronico,
G., Baratta, G.A., Spinella, F. and Strazzulla, G.: 1987, Astonon.Astrophys 184, 49-51
CRC Handbook of Chemistry and Physics,
54th ed: CRC Press, 1973 Hoover, R. B., Hoyle, F., Wickramasinghe,
N. C., Hoover, M. J. & Al-Mufti, S.: 1986, Earth, Moon, and Planets, 35,
19-45 Hoyle, F. and Wickramasinghe, N. C.:
1983, Living Comets, Univ Coll. Cardiff Press Hoyle, F. and
Wickramasinghe, N. C.: 1997, Life on Mars? The case for a cosmic heritage Clinical
Press, Bristol Larson, H.P. and
Fink, U.: 1977, Applied Spectroscopy, 31, 386 Tegler, S. and
Romanishin, W.: 1998, Nature, 392, 49-51 Tholen, D. J, Cruikshank,
D. P, Hartman, W. K, Lark, N, Hammel, H. B. & Piscitelli, J. R.:
1986, Proc. 20th ESLAB Symposium on the Exploration of Halley's Comet,
Heidelberg 27-31 October 1986, ESA SP-250, Vol . III, 503-507 Wallis, M.K. and
Wickramasinghe, N.C.: The Observatory, 112, 228-234
Authors: N.C. Wickramasinghe and F. Hoyle
School of Mathematics, Cardiff University
PO Box 926, Senghennydd Road
Cardiff CF2 4YH, UK
School of Mathematics, Cardiff University
PO Box 926, Senghennydd Road
Cardiff CF2 4YH, UK
From: panspermia.org
https://www.panspermia.org/kuiper.htm
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