http://SaturnianCosmology.Org/ mirrored file
   For complete access to all the files of this collection
        see http://SaturnianCosmology.org/search.php
  ==========================================================


[another one without a clue on electricity]

Ball Lightning as a Self
Organized Complexity
Erzilia Lozneanu, Sebastian Popescu and Mircea Sanduloviciu
Department of Plasma Physics
"Al. I. Cuza" University
6600 Iasi, Romania
msandu@uaic.ro

The ball lightning phenomenon is explained in the frame of a
self-organization scenario suggested by experiments performed on the
spontaneously generated complex spherical space charge configuration in
plasma. Originated in a hot plasma, suddenly created in a point where a
lightning flash strikes the Earth surface, the ball lightning appearance
proves the ability of nature to generate, by self-organization, complex
structures able to ensure their own existence by exchange of matter and
energy with the surroundings. Their subsequent evolution depends on the
environment where they are born. Under contemporary Earth conditions the
lifetime of such complexities is relatively short. A similar
self-organization mechanism, produced by simple sparks in the earl Earth's
atmosphere (chemically reactive plasma) is suggested to explain the
genesis of complexities able to evolve into prebiotic structures.

1.  Introduction

The enigmatic ball lightning phenomenon has stimulated the people interest
for a very long time. Thus the ball lightning appearance was noted with
more than a hundred years ago in prestigious periodicals as for example
"Nature". The vast literature on ball lightning comprises books entirely
dedicated to this subject [1-3], review papers focussed on this topic
[4-7], as well as data banks. The data banks contain collections of
characteristics for lightning balls that where occasionally observed under
different circumstances. For example, in the United States, lightning
balls have been observed by about 5% of the adult population at some time
of their lives [8]. Among the prominent individuals who have observed
lightning balls are Niels Bohr and Victor Weisskopf [9]. Periodically, new
aspects concerning the ball lightning are discussed at international
symposiums, the last one taking place in 1999 at Antwerp, in Belgium. The
intriguing appearance and characteristics of the ball lightning have given
rise to a wide variety of models proposed for explaining the phenomenon.

At present the scientists that have focused their investigations on the
ball lightning could be divided in two parts. One part considers that the
plasma, created by an ordinary lightning stroke in the well-localized
region where it strikes the Earth surface, contains a sufficient amount of
matter and energy to explain the ball lightning appearance and lifetime.
This energy could eventually be stored as chemical one in a special kind
of accumulator [10], or is related to a more complex chemical phenomenon
involving, for example, water vapors [6]. Also other forms of energy, as
for example nuclear energy [11] and processes related to the behavior of
antimatter [12] were occasionally invoked to be at the origin of ball
lightning. 

The energy content and, consequently, the lifetime of ball lightning are
evidently related (in all of these models)  to the amount of energy
transferred from the ordinary linear lightning to the ball lightning.
After this energy transfer, the ball lightning appears, for a certain time
sequence, as an electrical gas discharge [10] or as a result of possible
other reactions (as for example chemical ones) accompanied by light
emission [6].

A new ball lightning model, published in Nature [13], considers at the
origin of ball lightning the chemical energy stored in nanoparticles of
silica-carbon mixtures which are ejected into the air as a filamentary
network when a normal lightning strikes the soil.

Another part of scientists relate the ball lightning appearance to the
presence of electromagnetic phenomena that usually accompany electrical
discharges, as for example ordinary linear lightning produced in the Earth
atmosphere during stormy weather, but occasionally also under fair weather
conditions. 

The prominent scientist that has proposed such a model was P.
L. Kapitsa [14]. He has proved the possibility to create in laboratory, at
atmospheric pressure, by interference, high frequency discharges, well
localized, showing some similarities with ball lightning.  Afterwards the
ball lightning model proposed by Kapitsa was justified by theoretical
considerations based on the presumption that electromagnetic radiation is
trapped in a plasma shell formed when a large amount of radiant energy
expels the plasma by ponderomotive force [15]. A similar theory relating
the ball lightning appearance to radiant energy produced during stormy
weather was proposed by Endean [16].

2.  On the implications of self-organization in the ball lightning
phenomenology

The possibility to explain the appearance of the ball lightning by
self-organization was firstly suggested by one of us at an international
symposium [17] in 1988, and then extensively described in other papers
[18-21]. Three years later Kadomtsev [22] suggested the considering of
ball lightning as a result of a self-organization mechanism presumably
possible in cold dusty plasma with electrochemical active particles. The
arguments for considering the self-organization as the genuine origin of
the ball lightning were inspired by experiments performed by us in
different plasma devices. As is well known, plasma is a medium where
self-confined space charge structures appear as flaming globes. 

These structures have been observed for long time ago. Thus, in 1920s the
American Nobel laureate Irving Langmuir, considered the "father" of Plasma
Physics, described an experiment in which he obtained luminous globes that
seem to have characteristics similar to those ascribed to ball lightning
[23]. Over the years, the spontaneous formation of spatial and
spatiotemporal patterns, frequently observed in plasma, have been
intensively studied both by experimental and theoretical physicists. These
studies have emphasized striking similarities of these patterns with those
formed in solid state physics, but also in chemical and biological media
[24,25]. Such similarities justify the opinion of considering the ball
lightning problem as one potentially solvable in the frame of
nonequilibrium physics. 

Arguments for this attempt are presented in a
recently published paper [21] that contains a test experiment able to
reveal the nature of physical processes whose successive appearance in a
plasma, subjected to an external constraint, determines the creation of a
well defined flaming globe. The succession of physical processes
experimentally identified in this test experiment reveals the presence of
a self-organization scenario potentially possible also in the Earth
atmosphere in the presence of electrical activity. 

The described experiment tries to join the hypotheses dominant today
concerning the ball lightning genesis.  First, there is the hypothesis
that the energy injected in the ball lightning by an ordinary linear
lightning is itself sufficient for explaining the ball lightning
appearance and lifetime. Second, there is the hypothesis that the
occasionally observed long lifetime of ball lightning is ensured by
trapping RF energy from external sources, i.e. lightning discharges
produced in the Earth atmosphere during stormy weather. 

This test
experiment has justified our attempt to consider it as a laboratory
simulation of ball lightning. With its help we have established a direct
relationship between the nonlinear behavior of plasma subjected to an
external constraint and the key processes generally accepted to be
relevant for the presence of self-organization. As is well known such key
processes are: i) symmetry breaking, ii) structural instability, iii)
bifurcation, and iv) long-range order [26]. The presence of the above
mentioned key processes was proved experimentally by gradually injecting
matter and energy in a plasma conductor placed between two electrodes.

Working as a plasma diode, the used experimental device makes possible to
reveal abrupt changes of the electrical conductivity of plasma by plotting
the current versus voltage static characteristic. Investigating the causes
that explain the observed abrupt changes of the plasma conductivity
(emphasized by the presence of critical points in the static
characteristic) we have obtained information concerning the genuine origin
of the above listed key processes. In this way we identified the stages of
the intermittent scenario of self organization, whose final product is a
flaming globe with behavior similar to that of a ball lightning. Although
not possible under natural conditions in the Earth atmosphere, the
identified scenario is essential for understanding the self-assemblage
process of the ball lightning considered as a self-organized complex space
charge configuration (CSCC). Based on such a self-organization scenario,
it becomes possible to explain the appearance of the ball lightning by
considering as initial condition the creation of a hot plasma in the point
where an ordinary lightning strikes the Earth surface. 

The subsequent
evolution of the plasma produced by local vaporization of soil can be
described in the frame of the so-called cascading self organization
process [27]. Such a cascading scenario of self-organization is
appropriate to the conditions under which ball lightning appears, because
the sudden injection of matter and energy in the form of ordinary
lightning is a process evidently present in nature. In comparison with the
experiment performed in a plasma diode, largely described in [21], where
the plasma was created before the matter and energy were gradually
injected, under stormy weather conditions the lightning stroke creates
itself a hot plasma in the point where it strikes Earth's surface.

The evolution of the hot plasma towards a free-floating flaming globe,
namely the ball lightning, becomes possible only if certain conditions are
satisfied. The first condition requires the spatial separation of
electrons and positive ions from the hot plasma. In the phase when the hot
plasma is in electrical contact with the positively charged Earth, such a
phenomenon becomes possible taking into account the high mobility of
electrons with respect to that of positive ions. As a consequence, the
Earth quickly collects electrons, so that a nucleus enriched in positive
ions appears.

Because of the high temperature of the plasma created by the lightning
stroke, the separation of opposite electrical space charges is enhanced by
thermal diffusion, so that the positive potential of the nucleus becomes
higher than that of the Earth [21]. The assemblage of the ball lightning
can be explained considering the following succession of sequential steps
related to the key processes of self-organization (specified in the
following by italics):

1. Creation of a well localized hot plasma at the impact point of an
electrical discharge, most frequently an ordinary linear lightning -
initial external constraint.

2. Separation of electrical opposite space charges because of the
differences in the diffusivity and mobility of electrons and positive
ions- nonequilibrium state. A nucleus enriched in positive ions,
surrounded by a partially ionized gas that fades off into the neutral
atmosphere, appears as a final product.

3. Acceleration towards the positive nucleus of the surrounding
thermalized electrons up to energies for which the neutral excitation and
ionization cross section functions suddenly increase in two adjacent
regions - symmetry breaking and spatial separation of the system's
functions relevant for self-organization.

4. Accumulation of those electrons that have lost their momentum after
neutrals' excitation in the region where the cross-section function of
this process suddenly increases. Development of electrostatic forces
acting as long-range correlations between the net negative space charge
formed after electrons' accumulation and the positive ions present in the
nucleus - initiation of long-range order.

5. Accumulation of opposite space charges in the form of a nearly
spherical electrical double layer that surrounds the positive nucleus. In
this phase the "fireball" is in electrical contact with the Earth. Sudden
transition into a state characterized by local minimum of the free energy
that spontaneously appears by the transition of the double layer into a
spherical one- structural instability. The enclosed spherical space charge
configuration simultaneously detaches from the Earth surface. So, a free
floating flaming globe, namely the ball lightning, appears as a relatively
stable self organized complexity.

6. Ensurance of the ball lightning existence for a certain time span by a
proper dynamics and for a certain time span, by a periodical exchange of
matter and energy with the surrounding plasma mantle. This behavior
explains the sound and electromagnetic phenomena reported as observational
characteristics of ball lightning.

The above-mentioned detachment of the ball lightning from the Earth
surface depends sensitively on the conductivity of the soil in the point
where the linear lightning produces the hot plasma. When the soil
conductivity is sufficiently low, a part of electrons collected by the
Earth, during the positive charging process of the nucleus, remains in the
vicinity of the contact point of the nearly spherical space charge
configuration with the Earth surface. When the space-charge transits into
a configuration characterized by a minimum of the free energy, the nearly
spherical double layer becomes closed. In this moment repulsive
electrostatic forces acting between the external side of the spherical
double layer and the negative space charge present for a short time span
at the Earth surface determine the detachment process.

The simultaneous fulfillment of the above both described processes
explains the very rare appearance of the ball lightning in the Earth
atmosphere. In the further evolution, the net negative charge well
localized on the Earth surface disperses so that the balance between the
attractive electrostatic forces and the buoyancy governs, for a relatively
long time, the ball lightning position and displacement with respect to
the Earth surface. Based on the described scenario, the ball lightning
could be considered as a giant "cell" created by self-organization in the
contemporary Earth atmosphere [21].

3.   Explanation of the ball lightning observational characteristics

In practice, all observational characteristics of the ball lightning
listed in [6] can be explained considering it as a self-organized CSCC
[21]. Thus, its association with stormy weather is the premise for
creation of the hot plasma by a lightning stroke. Its emission of light is
related to the de-excitations of the neutrals that were excited by
electrons accelerated towards the positive nucleus. The spherical shape
corresponds to a space charge configuration characterized by a minimum of
the free energy.

Therefore the ball lightning self-assemblage, started from an initially
hot plasma, does not require expenditure of additional external energy.
Only internal processes related to the described cascading
self-organization scenario govern the subsequent evolution of the hot
plasma into a lightning ball. The different colors of lightning balls and
the associated smell could be explained considering the nature of
materials evaporated in the point where the lightning stoke strikes the
Earth surface. 

The ball lightning's size depends on the amount of energy transferred by
the ordinary lightning that has created the hot plasma but also, after its
creation, on its ability to act as a cavity able to absorb at resonance
radiant energy. The considerable stability as an entity could be related
to the presence of a spherical double layer that ensures the
self-confinement mechanism emphasized by the spatial coherence of the ball
lightning. The apparent coldness of the ball lightning has a plausible
explanation knowing that the energy required for the self-assemblage of an
electrical double layer has the order of magnitude the neutrals'
ionization energy.

The lack of buoyancy of the ball lightning is related to its gaseous
nature self-confined by an electrical double layer. Its floating state,
realized after its detachment from the Earth surface, is explainable
considering the presence of attractive electrostatic forces acting between
the net negative space charge localized at the external side of the double
layer and the positive Earth. The buoyancy force equilibrates those
attractive forces to which the gravitational one must also be added.

A plausible explanation of the occasionally observed erratic motion of the
ball lightning, also against the wind, necessarily requires the
consideration of the transition from a stationary double layer into a
moving one. This transition takes place when a local self-enhancement of
the production of positive ions determines the overcompensation of the
adjacent net negative space charge accumulated after neutrals' excitation.
The two modes of demise, explosively or simple disappearing depend on the
energy transferred to the initial plasma that generates the ball
lightning, but also on the radiant energy absorption in the moment of its
de-aggregation.

Another important observational characteristic is the occasionally
observed penetration through dielectric walls without producing any damage
in the material [4, 28]. Such a phenomenon becomes possible considering
the ball lightning as a cavity that absorbs at resonance high frequency
radiant energy. Under such conditions the apparent penetration, for
example, through a window of an aircraft [4] is, very probable, a
re-generation of the ball lightning at the other side of the dielectric
wall.

4.  Cell-like characteristics of the ball lightning

From the point of view of nonequilibrium physics one of the most
interesting observational characteristics of the ball lightning is, beside
its genesis, its transition into a state in which it emits sound and
electromagnetic waves. This proves that the ball lightning naturally
evolves, immediately after its "birth", into a state in which a rhythmic
exchange of energy and matter with the surrounding plasma mantle ensures
its own existence for a relatively short time span. The magnitude of this
time span depends on the amount of slow electrons stored in the mantle. An
additional heating process, ensured by absorption of radiant energy from
eventually present RF sources, can extend the lifetime of the ball
lightning.

The matter and energy exchange process, sustained and controlled by the
double layer that protects the CSCC like a cell membrane, makes the ball
lightning phenomenology even more interesting for scientists whose goal is
to elucidate the mechanism by which the Nature has created the first
pre-biotic complex structure. Such structures might have appeared under
pre biotic Earth's conditions when usual electrical sparks had created, in
the above described way, a CSCC. In contrast to the present Earth
conditions, the CSCC had been self-assembled in an environment (reactive
plasma) in which a subsequent evolution into o more complex, perhaps
pre-biotic, structure became potentially possible. In this context it is
interesting to remind the content of already published papers that have
reported the appearance of "micro lightning balls" in plasma devices [29],
but also the self-assemblage, in reactive HF plasma, of membranous
vesicles [30-33]. These vesicles are considered as an essential step in
the evolution of the earliest cells.

Some remarkable behavior of the CSCC formed in laboratory, as for example
its self-replication by division, but also its ability to transmit
information by radiant energy (related to the double layer dynamics),
absorbed at resonance by similar other CSCC, put forward some qualities
usually attributed only to living systems [30].

Evidently, the attempt to explain the origin of life, starting from a
gaseous cell self-assembled in the chemical reactive early Earth
atmosphere by a scenario of self organization similar to that creating
lightning balls in the contemporary atmosphere must be approached with
great care. Additional laboratory experiments concerning the evolution of
a gaseous cell-like configuration, created by a usual electrical spark
produced in suitable selected reactive plasmas, into a vesicle, could
eventually elucidate this striking problem of broad interest for
scientists working in the most interdisciplinary science, namely the
Science of Complexity.

5.  Conclusions

Based on new knowledge concerning the scenario of self-organization that
explains the appearance of CSCC in plasmas we have described in this paper
a phenomenological model of the ball lightning. This model suggests that a
local injection of matter and energy by a lightning stroke can start, in
certain conditions, the self-assemblage of a well defined free floating
flaming globe, named ball lightning.

The same self-organization scenario initiated by simple sparks under
prebiotic Earth conditions is considered as a possible answer to the
problem concerning the manner by which the Nature has created initially
gaseous CSCCs having the ability to evolve into precursors of living
complex systems.

References

[1]  SINGER, Stanley, The Nature of Ball Lightning, Plenum (1971).
[2]  BARRY, James Dale, Ball lightning and Bead Lightning, Plenum (1980).
[3]  STENHOFF, Mark, Ball Lightning  ­ An Unsolved Problem in Atmospheric 
Physics,
Kluwer (1999).
[4]  CHARMAN, W. N., "Ball lightning" Phys. Rep. (Rev. Sect. Phys. Lett.) 54 
(1979), 261
306.
[5]  SMIRNOV, B. M., "The properties and the nature of ball lightning", Phys. 
Rep. (Rev Sect.
of Phys. Lett) 152 (1987), 177-226.
[6]  TURNER, D. J., "The structure and stability of ball lightning", Phil. 
Trans. R. Soc. Lond.
A 347 (1994), 83-111.
[7]  SINKEVICH, Oleg, "Long-lived plasma formations and problems associated 
with ball
lightning", High Temperature, 35 (1997), 639-652; 955-969.
[8]  ROTH, J. Reece, "Ball lightning: what nature is trying to tell the plasma 
research
community", Fusion Technology 27 (1995), 255-270.
[9]  ROTH, J. Reece, "Ball lightning as a route to fusion energy", 13th Symp. 
Fusion Energy,
Knoxville, Tennessee, October 2-6, vol. II, (1989), 1407-1414.
[10] KADOMTSEV, Boris, "On the ball lightning phenomenology", Comments Plasma
Phys.Control. Fusion 13 (1990), 277-285.
[11] ALTSSCHULER, M.D., L.L HOUSE, and E HILDNER, "Is ball lightning a nuclear
phenomenon?", Nature 228 (1970), 545-546.
[12] CRAWFORD, J. F., "Antimatter and ball lightning", Nature 239 (1972), 395.
[13] ABRAHAMSON, John, and James DINNISS, "Ball lightning caused by oxidation of
nanoparticle networks from normal lightning strikes on soil", Nature 403 
(2000), 519-521.
[14] KAPITSA, Pyotr, "The nature of ball lightning", Dokl. Akad. Nauk USSS,  
101 (1955),
245-248 (in Russian).
[15] ZHENG, Xue-Heng, "Quantitative analysis for ball lightning", Phys. Lett. A 
148 (1990),
463-469.
[16] ENDEAN, V.G. "Ball lightning as electromagnetic energy", Nature 263 
(1976), 753-755.
[17] SANDULOVICIU, Mircea, "Self-organization and disruption phenomena in 
current
carrying plasma", Int. Symp. Phys. Ionized Gases, Sarajevo, Yugoslavia, (1988), 
477-480.
[18] SANDULOVICIU, Mircea, "On The Ball Lightnig Phenomenology", Analele  
tiinifice
ale Universitii "Al.I.Cuza" Iai  (Scientific Annals of "Al.I.Cuza" University 
of Iasi),
XXXV (1989), 3-7, and in Current Research on Fusion, Laboratory and 
Astrophysical
Plasmas, edited by S.Kuhn, K. Schopf and R. Schrittwieser, World Scientific 
(1993), 235
240.
[19] SANDULOVICIU, Mircea, "On the Phenomenology of the Ball Lighting", XX-th 
Int.
Conf. Phen. Ionized Gases, Pisa, Italy (1991), 266-268.
[20] SANDULOVICIU, Mircea, "Quantum processes at the origin of 
self-organization and
chaos in current carrying gaseous conductors", XXIst Int. Conf. Phen. Ionized 
Gases,
Bochum, Germania, vol. III, Invited papers (1993), 279-286.
[21] SANDULOVICIU, Mircea, and Erzilia LOZNEANU, "The ball lightning as a self
organization phenomenon" J. Geophysical Res. Climate and Phys. of the 
Atmosphere 105
(2000), 4719-4727.
[22] KADOMTSEV, Boris, "Ball lightning as a phenomenon of self-organization", 
J. Moscow
Phys. Soc. 1 (1991), 335-340.
[23] BEATY, Bill, "Irving Langmuir's Ball Lightning Tube", (1995),
http://www.amasci.com/freenrg/balllg1.html.
[24] GORBATYUK, A. V., and F.J. NIEDERNOSTHEIDE, "Mechanisms of spatial current
density instabilities in p+-p--n-p+-n++", Phys. Rev. B 59 (1999), 13157-13169.
[25] KOCH, A. J., and Hans MEINHARDT, "Biological pattern formation: from basic
mechanisms to complex structures", Rev. Mod. Phys. 66 (1994), 1481-1507.
[26] NICOLIS, Gregoire and Ilya PRIGOGINE, Exploring Complexity- an 
Introduction,
Freeman & Co. (1989).
[27] SATO, Tetsuya, "Complexity in plasma: scenario of self-organization", J. 
Korean Phys.
Soc. 31 (1997), S109-S111.
[28] SINGER, Stanley, "Great balls of fire", Nature 350 (1991), 108-109.
[29] ECKER, Günter, "The unipolar arc- does it exist?", XIVth Int. Conf. Phen. 
Ionized Gases,
Dusseldorf, 29th August-2 September, Invited Papers, edited by W. Bötticher, H. 
Wenk, E.
Schulz-Gulde, (1983), 9-23.
[30] SANDULOVICIU, Mircea, "Cell structures in physical plasma resulting after 
a self
organization mechanism maintained by quantum processes", The Origin of Life
(abstracts), The Sixth ISSOL Meeting and the Ninth International Conference, 
Prague,
(1989), 94-95.
[31] SIMIONESCU I. Cristofor, Sorin MANOLACHE, Gheorghe COBILEAC, and Constantin
ROMANESCU, "Cold plasma synthesis and complexity of chemical evolution systems"
ACH - Models in Chemistry 132 (1995), 367-378.
[32] SANDULOVICIU, Mircea, "On the microscopic basis of self-organization", J. 
Tech.
Phys. (Warszawa) 38 (1997), 263-267.
[33] SANDULOVICIU, Mircea, Erzilia LOZNEANU, and Sebastian POPESCU, "Self
organization scenario relevant for the formation of prebiotic complex 
structures", J.
Plasma Fusion Res. SERIES, vol. 2 (1999), 486-489.