Abstract
A new method is here used to obtain experimental data
on the nature and composition of the Tunguska Cosmic Body. The leading
hypothesis of the method is that in the forest conifers which have survived
the Tunguska catastrophe, the fluid resin present at the moment of the event
could have acted as a trap for airborne particles, as happens in amber. The
growth rings of trees can give information on the age of the resin and therefore
on the time when the particulate was trapped in them. With a scanning
electron microscope, a total of 7163 particles were found in resin-samples
from Tunguska branches and from two control trees. The time distributions of
the particles in the years 1885-1930 show clear abundance peaks centred on
1908. This makes it possible to conclude that the presence of Fe, Ca, Al, Si,
Au, Cu, S, Zn, Cr, Ba, Ti, Ni, C and O in the particles observed is related
to the Tunguska event and that these elements are probable constituents of
the Tunguska Cosmic Body. This result is compatible with recent calculations
showing that the Tunguska body can be a normal density stony asteroid.
Introduction
On 30 June 1908 the explosion in the atmosphere of a cosmic body over the basin
of the Podkamennaja Tunguska river (Central Siberia) resulted in 2,150 km2
of forest fall and a great number of trees and branches burnt in a large part
of the explosion area.
Since 1927 a great number of scientific expeditions has worked in Tunguska to
collect data on the effects of the explosion and search for fragments or
traces of the material from the disrupted Tunguska Cosmic Body (TCB). Some
reviews summarize the results acquired by these intensive investigations in
successive periods, i. e., 1927-1958 (Krinov 1966), 1958-1969 (Vasiljev
1984), 1970-1980 (Vasiljev 1986), 1980-1985 (Vasiljev 1988). Data on forest
devastation and records of the atmospheric and seismic waves have made it
possible to deduce the main characteristics of the Tunguska explosion, i. e.
its exact time, 00h 14m 28s UT, (Ben-Menahem
1975), the coordinates of the point usually called "epicentre", 60
53' 09"; N, 101 53' 40"; E, (Fast 1967), the energy release and
height of the explosion, though the values for the last two parameters are
estimated with great uncertainty. However, no impact craters or meteorite
fragments have ever been found in an area of 15,000 km2 (Vasiljev et
al. 1990), so that the nature and composition of the TCB are still
controversial.
Apart from less conventional hypotheses involving near critical fissionable
material (Zigel' 1959, Hunt et al. 1960), antimatter meteors (Cowan et
al. 1965), tiny black holes (Jackson and Ryan 1973) or alien spacecrafts
(Kazantsev 1946, Baxter and Atkins 1976), the two most plausible explanations
consider the explosion in the atmosphere at an altitude of 5-10 km of a comet
(see, e. g., Whipple 1930, Kresak 1978) or an asteroid-like meteorite (see,
e. g., Kulik 1939, Sekanina 1983).
In the recent past the cometary hypothesis has been favoured on the basis
that a low density object was needed to explain the Tunguska catastrophe
(Petrov and Stulov 1975, Turco et al. 1982). Subsequently, to account for the
concentration of energy release of the explosion, two sub-versions of this hypothesis
have been developed, one introducing chemical reactions (Tsymbal and Shnitke
1986), the other nuclear-fusion reactions (D'Alessio and Harms 1989).
On the other hand, it has been shown (Grigoryan 1976, Grigoryan 1979, Passey
and Melosh 1980, Levin and Bronshten 1986) that the fragmentation of a normal
density object can greatly increase the rate of energy deposition in a small
region near the end of the trajectory, thus appearing as an atmospheric
explosion. Detailed calculations which include the effect of aerodynamic
forces that can fracture the object, and the heating of the bolide due to
friction with the atmosphere, have recently been performed, showing that the
Tunguska event is fully compatible with the catastrophic disruption of a
60-100 m diameter asteroid of the common stony class (Chyba et al.
1993, Hills and Goda 1993). However, due to the uncertainty of such input
parameters as the energy and height of the explosion or the inclination angle
and the encounter velocity of the impactor, the same calculations do not
exclude the possibility that the TCB was a high velocity iron object, nor
rule out a carbonaceous asteroid as an explanation of the event.
The only way to achieve certainty about the nature and composition of the TCB
remains the search for some of its remnants. Many radiocarbon analyses of
Tunguska wood samples (Nesvetajlo and Kovaliukh 1983), chemical analyses of
soil or plants, bed-by-bed chemical analyses of the peat formed by Sphagnum
fuscum in 1850-1950 (Vasiljev et al. 1973, Golenetskij et al.
1977a, Golenetskij et al. 1977b, Kolesnikov et al. 1977),
isotopic analyses of many different soil, peat and wood samples (Kolesnikov et
al. 1979), as well as analyses of the spherules from Tunguska soil
samples collected in a radius of several tens of kilometres from the
epicentre (Jhanno et al. 1989, Nazarov et al. 1990), have been
carried out. Nevertheless, many conclusions of this intensive work are still
uncertain, so that further investigations are needed.
In the present work a new method is used to obtain experimental data on the
nature and composition of the TCB. Preliminary attempts (Cecchini et al.
1992, Valdr and Korlevic' 1993) to use this method have shown its validity,
although the necessary corrections (Galli et al. 1993) had to be
introduced in order to deduce a reliable dating for the particles.
Method
The leading hypothesis of the method is that in the forest conifers which
have survived the Tunguska catastrophe, the fluid resin freshly emitted due
to some physiological effect, could have acted as a trap as happens in amber,
for airborne particles present at the moment of the event. The most
interesting case is when the resin is emitted and deposited around small dead
branches, naturally decorticated long before the event and subsequently
merged in the growing stem. The resin produced inside the sapwood is
partially emitted year by year to the exterior, in a fluid state, during the
most active vegetation period. The part of it immediately surrounding the
branch on the outer bark of the tree, solidifies and becomes gradually
included from outside, by the growing wood. So, the fresh resin can act like
a trap for airborne microparticles and part of them, embedded in the
tree-resin, can eventually be found in the resin layer along the limit
between the growth rings and the withered branch. Then, the elemental
composition of the particles can be determined by the analytical electron
microscopy technique.
The growth rings, being rather easily datable year by year, can give information
on the age of the resin and therefore on the time when the particulate was
trapped in it. To date the resin, the width of the outside bark and the width
of the resin layer on the bark must be taken into account because they are
responsible for a certain shift between the date of the particle capture and
that of the adjacent tree rings, as can be seen in Fig. 1.
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Fig. 1. Sketch of the inclusion mechanism of airborne
particles in the resin emitted around a dead branch of a living conifer.
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The sketch in Fig. 1 shows a vertical section of a stem slice containing a
withered branch. In the upper part of the figure, the slice is represented in
the 1908 state with its last growth ring adjacent to the bark. In the
vegetative period of that year, the fresh resin surrounding the dead branch
on the outer part of the bark could trap airborne particles. In the lower
part of the figure the same section is shown some years later. The solidified
1908-resin with the trapped particles has been included inside the growing
tree and now has become adjacent to the growth ring of 1914 (or to a couple
of rings depending on the relative thicknesses of rings and resin layers).
The shift between the age of the resin and that of the tree-rings varies for
different trees and should be experimentally determined.
The correction for the bark and resin widths was overlooked in the
preliminary attempts to search for microremnants of the TCB in the tree resin
(Cecchini et al. 1992, Valdr and Korlevic 1993) therefore the
particles listed in these preliminary works, having been trapped in the resin
some years before 1908, cannot be related to the Tunguska event. The
refinements of the method, suggested by M. Galli (Galli et al. 1993),
have permitted the present systematic analysis and the correct dating of the
particles embedded in the tree-resin before, during and after the Tunguska
event.
Previous chemical analyses of materials from Tunguska have generally been
carried out by searching for traces of elements from the TCB in soil, plants
and rocks (Kovalevskij et al. 1963, Iljina et al. 1971,
Golenetskij et al. 1977a), in beds of peat (Golenetskij et al.
1977a, Golenetskij et al. 1977b), in growth rings of trees, etc...
These analyses - in which infinitesimal mass concentrations of some
elements, possibly originated from the products of the explosion of the TCB,
were sought in the whole mass of the materials considered - have given
uncertain results. Attempts to consider spheroidal particles found in the
soil as relic candidates for the TCB came up against the difficulty of reliably
dating the spherules. A careful comparison of their composition with that
of spherules of known origin has led to the conclusion that about 95 % of the
spherules examined have a terrestrial or micrometeoritic origin, and the
difficulty of dating the remaining part left uncertain their provenance from
the TCB (Jhanno et al. 1989, Nazarov et al. 1990). The great
advantages of the new method here used are that it gives the possibility to
bring out and analyse particles which could be pure microremnants of
the TCB, and to reliably date them. The same advantages should reveal
themselves also when the method is applied to investigate the isotopic
composition of the elements found.
The refined method can in principle be applied to get information on
environmental conditions in the past, especially in connection with events of
microsized particulate production (aerosols from human, volcanic and seismic
activity, forest fires, etc...). The accumulation in the resin can be thought
to be similar to the deposition and accumulation of volcanic aerosols and
particulate in polar ice sheets. So, for example, in the case of volcanic
eruptions, large quantities of aerosols and ashes are injected into the
atmosphere and are generally deposited within 1 or 2 years so that any
"clean-air" location, even at a great distance from the site of the
event, must be expected to receive significant amounts of fall-out, which can
be subtracted from the background and analysed in a way similar to the
present one.
Samples
To collect the necessary wood samples from living trees that have survived
the catastrophe, the authors of the present work participated, in the summer
of 1991, in a scientific expedition (Cecchini et al. 1992, Galli et
al. 1993) led by N. V. Vasiljev, deputy chairman of the Commission on
Meteorites and Cosmic Dust of the Siberian Section of the Russian Academy of
Sciences, and by G. V. Andreev from the Astronomical Observatory of Tomsk.
Among the few conifers per hectare that have survived the Tunguska
catastrophe in the vicinity of the epicentre, the most frequent are Siberian
larches (Larix sibirica) and common pine (Pinus sylvestris)
followed by Siberian spruce (Picea obovata) and Siberian pine (Pinus
cembra). The most suitable tree for our purpose turned out to be the
Siberian spruce, with abundant resin and very regular yearly lignification
cycles (i. e. without double or missing annual rings), so that the latewood
tree ring limits could easily be dated. Therefore, the samples have been
taken from trees of this species plus, for comparison, some samples from a
Siberian pine.
The samples collected have the form of thin transversal stem slices, sawn at
different heights, or of cylindrical cores extracted from living trees and
containing the embedded withered branches surrounded by resin.
The samples of interest contained withered branches, dead at least some years
before the catastrophe of 1908. On such branches the living tissues
have deposited resin both from years before and after the catastrophe. The
traces of the withered branches could be discovered by looking in the bark of
the stem for spots of shiny fresh resin, the oldest dead branches being more
abundant in the lower part of the stem because of the natural pruning of the
trees in a normally thick forest. The greater part of the samples was
extracted directly from living trees with a 22 mm diameter corer. In order to
verify the adequate age of the trees, preliminary cores were extracted with a
5 mm Pressler probe. The wounds due to the perforations were immediately
treated with an appropriate cream.
The wood samples collected in Tunguska were subsequently examined in Bologna.
In order to bring out the branches, the branch-stem interstices, containing
the resin layers, were opened. It was then possible to proceed to electron
microscopy inspection of the samples in two different ways: a) through
scanning of the surface of the resin that was adjacent to the dead branches;
b) by direct observation of the particles extracted after dissolving the
resin inside filtering capsules placed in a Soxhlet extractor.
The overall size, morphology and chemical composition of the particles have
been determined using a scanning electron microscope equipped with an energy
dispersive X-ray spectrometer (in the present work a Philips SEM 515, with
EDAX PV9100). A computerised electron detector has been used to determine the
concentration of components with atomic numbers greater than 10. The samples
extracted from the surface of the resin have been placed on standard SEM
stubs and coated with thin films of carbon by evaporation in vacuum.
The resin deposited in the years 1885-1930 on 14 branches of 7 trees
situated in different directions within a radius of 8 km from the epicentre
of the Tunguska catastrophe, has been examined (see Table 1). The exact
location of the trees listed in Table 1 is given elsewhere (Serra et al.
1994). For comparison, 6 other branches of a control tree growing at about
1,100 km W-SW from the Tunguska site and the resin deposited on the roots of
a control tree uprooted by the explosion of 1908 have also been examined.
Results
In the 71 resin samples from 20 branches and 3 roots of the 9 trees listed
in Table 1, 7163 particles were found up to 1 June 1993. From this total, 171
pure gold particles, mainly found in the resin of the nineteenth century,
clearly having nothing to do with the Tunguska event, will be discussed
elsewhere. Here the other 5854 particles found in the resin-samples from
Tunguska branches are discussed and compared with the 1138 particles from the
two control trees.
The shift between the age of the resin and that of the tree rings has been
determined by measuring the bark-width and the width of the tree-rings in all
the wood-samples considered, taking into consideration the bark-width and the
thickness of resin layers on living younger trees. This shift has been found
equal to 6 3 years. The dating given hereafter is referred to the resin
age, calculated with a 6-year shift with respect to the adjacent
tree-rings. Taking into account the uncertainty in the resin dating, three
periods are here considered: 1902-1914, which corresponds to particles that
could be related to the Tunguska event; 1885-1901 and 1915-1930, which
correspond to "background particles" trapped before and after the
Tunguska event.
As mentioned above, a chemical semiquantitative analysis of the composition
of the particles has been performed by using a windowed energy dispersive
X-ray spectrometer. Great care has been devoted to avoid contamination of the
samples during their preparation and analysis. The series from the same
branch of the resin samples corresponding to the three periods considered
were carbon-coated contemporarily. To exclude artifacts, for six branches,
two or three different series of resin-samples for each branch have been
prepared at different times after a general check of the experimental set-up.
The analysis has revealed the presence of 28 elements in the particles from
the Tunguska tree-resin. In Table 2, the elements present with more than 1 %
in at least 1 particle are listed, taking into account that the equipment
used cannot reliably detect quantities < 1 % or elements with atomic
number Z < 10. These elements are divided into two groups. A first group
of elements, which is present in all three periods considered is here
indicated as "low-Z" elements. It corresponds to elements with
atomic number Z < 20, plus iron. A second group of elements, mainly present
in the period 1902-1914, is here called "high-Z" and contains
elements with Z >= 22 with the exclusion of iron.
The 5854 particles found in the resin samples from Tunguska branches are
split in Table 3 into "low-Z" particles, i. e. particles containing
only low-Z elements, and "high-Z" particles, which contain
at least 1 % of 1 high-Z element (the high-Z particles usually contain a
certain percentage of low-Z elements). As can be seen from the data in Table
3, one third (about 130 particles/cm2) of the "low-Z"
particles could be related to the Tunguska event, but it is difficult to
distinguish them from the two thirds (about 250 particles/cm2) of
"background" particles. Therefore, the analysis is hereafter
focused on the high-Z particles, whose density is increased by more than a
factor 10 in the period 1902-1914.
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Fig. 2. Partition of the 5854 particles found in the
resin samples from Tunguska branches for the three periods considered.
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The bar graph in Fig. 2 summarises the total number of high-Z and low-Z
particles found in the three periods considered. Due to the fact that for
some branches the resin was available only for one or two of the three
periods of interest, the total number of particles observed is different in
the three periods. That is why in the following graphs the results are
presented in per mil calculated with respect to the 1181, 3356 and 1317 total
particles found in the corresponding period.
As can be seen from Fig. 3, a clear abundance peak is found in correspondence
with the period of the Tunguska event. Taking into account the 3 years
uncertainty in the dating, the particles under the whole peak can be
considered related to the Tunguska event, after subtraction of a very small
"background". Similar peaks have separately been obtained for the
different trees examined (Serra et al. 1994).
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Fig. 3. Time distribution (per mil) of the 518 high-Z
particles found in the resin samples from Tunguska branches.
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The graphs of Fig. 4 show the time distribution of particles containing a
single high-Z element, such as copper, chromium, barium and gold (the last
only when mixed with other elements). Similar peaks appear also for the other
high-Z elements for which sufficient statistics are available, i. e. zinc,
titanium and nickel.
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Fig. 4. Time distribution (per mil) of particles
containing Cu, Cr, Ba and mixed-Au.
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As mentioned, 471 out of the 518 high-Z particles contain a certain
percentage of low-Z elements. For these mixed particles, considered either in
their whole or separately for calcium, iron, silicon, alluminium, sulphur,
potassium and chlorine, mixed with high-Z elements, clear peaks centred at
1908 are obtained, as shown in Fig. 5 for the first 4 cases.
The high-Z particles found in the 1902-1914 resin from Tunguska branches,
appear to have experienced heating and melting. Many of them are spherules or
rounded particles like those shown in the micrographs of Fig. 6.
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Fig. 5. Time distribution (per mil) of particles
containing a mixture of low-Z and high-Z elements and of particles
containing Ca, Fe, Si mixed with high-Z elements.
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Fig. 6. Micrographs of four high-Z particles found in the
Tunguska branch-resin:
a) a spheroidal particle containing P (34%), Ca
(30%), K (18%), Fe (6%), Zn (4%), Ba (4%) and Si (3%) (tree n 7, year
1904),
b) a rounded particle containing Fe (77%), W (7%),
Al (4%), Cl (3%), K (2%), S (2%), Zn (2%), Cu (1%) and Mn (1%) (tree n 1,
year 1910),
c) a particle containing Ti (75%), Ca (14%), Si
(9%) and K (2%) (tree n 7, year 1904),
d) a particle containing Al (28%), Zn (23%), Ca
(17%), Si (13%), Fe (10%), S (3%), K (2%), Cl (2%) and Ti (1%) (tree n 6,
year 1907).
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Fig. 7. Micrographs of two low-Z particles found in the
Tunguska branch-resin:
upper) a particle containing Ca (65%) and Si (35%)
(tree n 1, year 1925),
lower) a particle containing Si (77%), Ca (9%), Fe
(7%), Al (4%) and K (2%) (tree n 6, year 1906).
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Among them sharp-edged or flocculent particles are generally absent,
unlike what happens for part of the low-Z particles trapped in the
resin of the three periods considered (see Fig. 7). The dimensions of the
particles can be estimated from the scale bars on the micrographs.
The spheroidal shape is a surely distinctive feature of particles which
underwent a thermal effect. Out of the 5854 particles from the Tunguska
branches, 88 are spheroidal (77 spheroids are high-Z particles and 11 are
pure low-Z particles). The time distribution for the 88 spheroidal particles
as well as that for 54 spheroids containing copper, show the usual peaks in
correspondence with the Tunguska event, as shown in Fig. 8. Similar graphs
are obtained also for the 31 and 30 spheroids containing aluminium and
calcium, respectively. It should be noted that the products of a high
temperature fusion followed by a rapid cooling are very different one from
another, as was experimentally checked by melting meteorite fragments in an
electric arc. For example, some spherules obtained in these conditions
contain a very high percentage of nickel, while this element is completely
absent in others (Florenskij et al. 1968).
On the basis of the chemical semiquantitative analysis performed, the
"average composition" ( % ) of the 463 high-Z particles of the
period 1902-1914 has been calculated and is shown by black bars in Fig. 9.
The quotes mean that the "average composition" should be considered
only as a qualitative indication. Indeed, as previously pointed out,
the equipment used cannot reliably detect elements with Z < 10 or
quantities < 1 %. Furthermore, the measured composition depends on the
place where the electron beam hits the particle and on the angle between the
electron beam and the surface of the particle. In averaging the composition,
the masses of the particles have not been taken into account. Finally, this
"average composition" refers to high-Z particles only. Taking into
account that probably about one third (see Table 3) of the "pure"
low-Z particles has the same origin as the high-Z particles, the percentage
of low-Z elements should be increased. It is worthwhile to note, however,
that this qualitative composition clearly differs from the composition of the
79 high-Z particles found in the root-resin of control tree n 2 and of the
29 high-Z particles found in 1902-1930 in control tree n 10 (see Fig. 9).
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Fig. 8.
Upper: time distribution (per mil) of all
spheroidal particles.
Lower: time distribution (per mil) of spheroidal
particles containing Cu.
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After completion of the present analysis, some measurements have been performed
with a new scanning electron microscope, a Philips PXL30 equipped with an
EDAX PV9900 spectrometer. With the equipment now available, it has been
possible to push the analysis down to elements with Z = 5. Two spectra of
newly examined particles and the corresponding micrographs, are given in Fig.
10. As can be seen, these spectra clearly reveal the lines of oxygen. To
search for the presence of carbon, some resin-samples have been coated with
gold instead of carbon. Thus, it has been possible to ascertain that many
elements listed in Table 2 are present not only in oxides, but also in
carbonates. This can strongly alter the measured ratio between the different
components of the particles. Thus, for example, due to the presence of
oxygen, the copper/aluminium ratio in the spherule of Fig. 10 is increased by
a factor of 1.5 when obtained by using the new equipment with respect to the
data obtained in the present work.
Fig. 10. The spectra and the corresponding micrographs
obtained with an EDAX PV9900 spectrometer for two particles found in the
1908 resin of tree n 5.
Left: a spheroidal high-Z particle containing
oxides of copper (86.6 %) and aluminium (13.4 %).
Right: a rounded low-Z particle containing oxides
of Si (67%), Al (24%), Na (5%), K (3%) and Fe (1%).
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Fig. 11. The measured radiocarbon abundance in percent of
the modern concentration (pMC) as a function of the tree-ring date for wood
samples from tree n. 1. The points connected with a solid line correspond
to the data from Stuiver and Becker 1993.
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Taking into account the results summarised in the present Section, one can
conclude that there are 14 elements, listed in Table 4, whose presence is
related to the Tunguska event. The list in Table 4 is given in decreasing
order of importance for the first 12 elements. The decreasing order takes
into account the number of particles, their average composition and the
probable relation to the Tunguska event of part of the "pure" low-Z
particles above the background. Oxygen and carbon, whose presence has been
ascertained, but for which no quantitative data are available, have been
added to the list. The elements Cl, K, Na, Pb and Mn, though listed in Table
2, are not included in Table 4, their relation to the Tunguska event being
dubious, due to the low overall percentage of the first three elements and to
peaks not so clear as those of Figs. 3-5 for Pb and Mn. The rather poor
statistics for Mg, P, Sn, Sr, Br, Ag, Bi, Co, Sb, Cd, W (from 11 to 1
particles, in decreasing order) has led to the exclusion of these elements
from Table 4.
As pointed out above, the present method should reveal its advantages also in
carrying out the isotopic analysis of the particles found. Up to now, only
the traditional radiocarbon method, which consists in searching for
infinitesimal concentrations of 14C in the full mass of the
tree-ring material, has been applied to study the Tunguska wood. The
radiocarbon analysis of a set of our wood samples from tree n. 1 has been
carried out by R. P. Beukens at the IsoTrace Radiocarbon Laboratory of the
Accelerator Mass Spectrometry Facility at the University of Toronto (Canada).
Figure 11 shows the measured values, with their error bars, of the
radiocarbon abundance in percent of the modern (year 1950 AD) concentration,
as a function of the ring date. These results are in general agreement with
those from Stuiver and Becker 1993. Radiocarbon due to neutron production in
a possible cometary impact producing a fusion reaction that might affect the
radiocarbon concentration at ground can be ruled out. The graph suggests an
increase of radiocarbon in the late 1909 and early 1910. A similar increase,
which has probably nothing to do with the Tunguska event, has been found in
1908-1910 tree-rings in previous radiocarbon analyses of Tunguska wood
samples (Nesvetajlo and Kovaliukh 1983). This increase may be related with
the expected solar cycle modulation of the cosmic radiation (Attolini et
al. 1989), though the large experimental error in the 1910 point leaves
doubts on such a conclusion.
Discussion
The sudden increase in the resin samples from Tunguska branches of
particles containing the elements listed in Table 4 cannot be related to
volcanic eruptions or tectonic activity. The dates and places of such events
do not correspond to the present data and the morphology of the particles
observed is different.
None of the known volcanic eruptions (Simkin et al. 1981) can explain
the peaks shown in Figs. 3-5 and 8. In the period of interest the eruptions
that have significantly affected light transmission in the northern
hemisphere with a certain observed dust veil are those of the volcanoes
Soufrire in West Indies (1902), Santa Maria in Guatemala (1902), Ksudach in
Kamchatka (1907) and Katmai in Alaska (1912). The last is apparently the only
one after 1908 able to cause a noticeable decrease in atmospheric light
transmission (Hoyt and Frlich 1983, Lamb 1988). On the other hand, the study
of the content of Antarctic snow (Boutron 1980) has shown that the strong
peaks observed in the concentration of Zn, Pb, Cu and Cd, appear to parallel
rather well the variations of global volcanic activity. In the present
work, no peaks of particles containing these elements have been observed in
the years 1902-1904 or 1912-1914, which might correspond to three of the four
volcanic eruptions mentioned. An increased concentration of the same
metals in snow and plants has been observed after earthquakes and it has been
shown that one of the most important sources of metals in the atmosphere are
aerosols which are emitted during degassing in active tectonic zones
(Alekseev and Alekseeva 1992). To our knowledge there is no record of a
particular seismic activity that can explain the peaks centred at 1908,
observed in the present work. Therefore, the volcanic and tectonic activity
can account for the presence in the branch-resin of some "background"
particles only.
Another source of particles in the atmosphere is the heavy metal release from
plants (Beauford et al. 1975, Beauford et al. 1977), which can
obviously be excluded as an explanation of the time-distribution data found
for the particles from Tunguska branch-resin.
Nor can the extraterrestrial dust particles (see, e. g., Sandford 1987,
Bradley et al. 1988) explain the time distribution of the particles
observed, though they are likely to be responsible for part of the
"background" of about 250 low-Z particles/cm2 and 5
high-Z particles/cm2 found in the Tunguska branch-resin in the
three periods considered (see Table 3). Anthropogenic sources of aerosols
cannot explain the Tunguska data, though they may be responsible for the hint
of an increase of high-Z particles observed in the control tree n 10 (40 km
from Tomsk) in the second and third decades of the present century. These
conclusions are confirmed by the results of the investigation of heavy metal
deposition in the peat of the basins of Podkamennaja and Nizhnjaja Tunguska
rivers (Bojarkina et al. 1986). A bed-by-bed neutron activation
analysis of the peat from different places located more than 80 km from the
smallest inhabited centres and more than 700 km from the nearest industrial
cities (Krasnojarsk, Irkutsk and Norilsk) was performed. The yearly
deposition per square meter of heavy metals was found more or less constant
for the period 1765-1972 and equal to 4000 1000 g for iron, 5 1 g for
scandium, 3 1 g for cobalt and 1.2 0.2 g for gold. These values,
therefore, correspond to the deposition in the Tunguska region from all
natural sources and can be considered as an upper limit for extraterrestrial
dust deposition. These measurements do not provide information about the
Tunguska event due to the fact that the yearly deposition was deduced from
the content of finite thickness bed peats, one of which corresponds to the
whole period from 1891 up to 1910. Control measurements performed by the same
authors near an industrial centre showed an increase in the deposition from
1903 to 1978 by factors of about 19 (Fe), 7 (Co and Sc) and 5 (Au).
The foregoing considerations lead to the conclusion that the increase in 1908
of particles containing the elements listed in Table 4 is directly correlated
to the Tunguska event. The data obtained from the Tomsk control tree n 10,
not showing such an increase, favour this interpretation. It is unlikely that
the particles observed correspond to the part of the material of the TCB that
was lifted into the higher atmosphere and precipitated worldwide in the
following months. This material was dispersed over a very large area and
there is no reason for a particular intensity of the precipitations in the
vicinity of the epicentre.
A second possible relation with the Tunguska event is that the particles
observed were transported from the ground to the tree-resin by the blast wave
from the explosion. A strong argument against this hypothesis is the
morphology of the particles observed in the peaks centred at 1908. As shown
in Fig. 6, the particles have no sharp edges and show evidence of drastic
heating, unlike what one would expect for particles coming from the ground.
Moreover, it is difficult to see a relation between the list of Table 4 and
the numerous chemical analyses of Tunguska soil, plant and rock samples
carried out by different groups (see, e. g., Kovalevskij et al. 1963,
Iljina et al. 1971, Golenetskij et al. 1977a). Finally, if the
particles were transported from the ground, a similar composition would have
been found for the particles trapped by the resin on the roots of control
tree n 2 and those on the branch-resin, but this does not happen, as Figure
9 shows. Though this graph should be considered with caution due to the fact
that the roots examined pertain to one tree only, it favours the hypothesis
of a different provenance for the particles embedded in the resin of the
roots and those from branch-resin. Indeed, at the moment of the explosion,
the resin on the branches was ready to receive the particles, while the roots
were under the ground. The roots emerged and began to emit resin only several
tens of seconds later. Due to this time delay the root-resin could not
receive particles directly from the exploded body but was able to trap
particles lifted from the ground.
Though a provenance from the ground of part of the trapped particles cannot
be excluded, it seems reasonable to assume that at least the main part of the
particles above the background came directly to the branch resin inside the blast
wave generated by the explosion of the TCB. This conclusion is
corroborated by the fact that the particles show evidence of heating and
melting as it should be, taking into account that the shocked gases,
concentrated in front of the impacting body, attained a temperature of
25,000-30,000 K (Chyba et al. 1993). Therefore, the elements
listed in Table 4 are probable constituents of the TCB and the present
results can be considered as experimental evidence in favour of the
hypothesis of the disruption of an ordinary stony meteorite.
An isotopic analysis of some elements present in the particles found (whose
masses are generally equal to fractions of a nanogram) would be of great
value in order to distinguish between a cosmic or terrestrial origin of the particles.
This isotopic analysis can also help to definitely answer the question of
nuclear processes invoked by some authors to explain the Tunguska explosion.
No trace of a nuclear process has been found by using the traditional
radiocarbon method applied to the full mass of the tree-ring material (see
previous Section) and no convincing evidence in favour of such a hypothesis
has ever been found (see, e. g., Kirichenko and Grechushkina 1963, Emeljanov
1963). It should be noted, however, that the methods used up to now cannot be
considered conclusive since they generally deal with radioactivity
measurements carried out more than half a century after the event or with the
search for infinitesimal isotopic anomalies in the whole mass of tree-rings,
sample of peat, etc..., resulting in measures at the limit of experimental
possibilities.
Conclusions
The branch-resin method here used has shown its validity in investigating
past events accompanied by aerosol production. Its application to the study
of the Tunguska event has made it possible to recognise a first list of 14
elements as probable constituents of the TCB. This list of elements is fully
compatible with recent calculations (Chyba et al. 1993, Hills and Goda
1993), showing that the TCB can be a normal density meteorite. Isotopic
analysis data together with an extension of the chemical analysis would be
useful to confirm the present conclusions.
Acknowledgements
The authors gratefully acknowledge G. V. Andreev, E. M. Kolesnikov, V.
D. Nesvetajlo and N. V. Vasiljev for their help in Tunguska and useful
discussions, K. Korlevic' for sending to M. Galli the first Tunguska wood
sample, whose structure examination excited the idea of the branch-resin
method here used, G. Valdr for having carried out a preliminary search of
particles trapped in the resin of the same sample and R. P. Beukens for the
radiocarbon analysis of a set of our Tunguska wood samples. The authors are
indebted, for their assistance in using different electron microscopy
facilities, to G. Tarroni and T. De Zaiacomo from the Bologna Centre of ENEA,
to F. Sandrolini and A. Saccani from the Department of Engineering of the
University of Bologna and to A. Garulli, F. Corticelli and D. Govoni from the
LAMEL laboratory of CNR in Bologna.
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Tables
Table 1. Trees and resin samples examined.
A) Resin samples
from tunguska branches
N
|
Tree
|
Years
|
branches
|
resin samples
|
1
|
Siberian spruce (Picea
obovata)
|
160
|
3
|
19
|
3
|
Siberian spruce (Picea
obovata)
|
130
|
2
|
5
|
4
|
Siberian spruce (Picea
obovata)
|
190
|
3
|
10
|
5
|
Siberian pine (Pinus
cembra)
|
110
|
1
|
7
|
6
|
Siberian spruce (Picea
obovata)
|
110
|
2
|
6
|
7
|
Siberian spruce (Picea
obovata)
|
110
|
2
|
7
|
8
|
Siberian spruce (Picea
obovata)
|
105
|
1
|
5
|
|
|
TOTAL
|
14
|
59
|
B) Resin
samples from control trees
N
|
Tree
|
branches
|
resin samples
|
10
|
Tomsk Siberian spruce (Picea obovata)
|
6
|
8
|
2
|
Roots from Siberian larch (Larix sibirica)
|
3
|
4
|
Table 2. The 28 elements present in the particles from Tunguska
tree-resin (more than 1 % in at least 1 particle). The equipment used cannot
reliably detect elements with Z < 10 or quantities < 1 %.
Low-Z elements Na Mg Al Si P S Cl
K Ca Fe
High-Z elements Ti Cr Mn Co Ni Cu
Zn Br Sr Ag Cd Sn Sb Ba W Au Pb Bi
Table 3. Particles in the resin samples from Tunguska branches.
Average dimensions of the particles: 4.5 m x 3.1 m (0.5 m x 0.5 m < 66
% <= 3 m x 3 m; 3 m x 3 m < 29 % <= 10 m x 10 m).
Period
(years)
|
Number
of samples
|
Resin surface
(cm2)
|
particles
|
density (particles/cm2)
|
High-Z
|
Low-Z
|
Total
|
High-Z
|
Low-Z
|
Total
|
1885-1901
|
17
|
4.46
|
20
|
1161
|
1181
|
4
|
260
|
265
|
1902-1914
|
25
|
7.60
|
463
|
2893
|
3356
|
61
|
381
|
442
|
1915-1930
|
17
|
5.40
|
35
|
1282
|
1317
|
6
|
237
|
244
|
TOTAL
|
59
|
17.46
|
518
|
5336
|
5854
|
30
|
306
|
335
|
Table 4. Elements related to the Tunguska event
Fe
|
Ca
|
Al
|
Si
|
Au
|
Cu
|
S
|
Zn
|
Cr
|
Ba
|
Ti
|
Ni
|
C
|
O
|
|
