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Anatomy of a Galaxy in Evolution

Poincaré, at the conclusion of the preface to his book, `Hypthéses
Cosmogoniques', states "One fact that strikes everyone is the spiral
shape of some nebulae; it is encountered much too often for us to
believe that it is due to chance. It is easy to understand how
incomplete any theory of cosmogony which ignores this fact must be.
None of the theories accounts for it satisfactorily, and the
explanation I myself once gave, in a kind of toy theory, is no better
than the others. Consequently, we come up against a big question
mark."

Assundry collection of galaxies photographed in the optical.

The remainder of this section addresses how galaxies form and why
spirals are among a large percentage of all galaxies.

How Do Galaxies Evolve?

Galaxies consist of a variety of objects that have been categorized
into classes: normal, barred, peculiar, Seyfert, active core,
elliptical, radio, quasars, and so on. The answer to why these classes
occur in the universe requires a valid description of the universe.

According to the renowned plasma physicist David Bohm, "the universe
is an unending transformation in flux whose previous states we are not
privileged to know." The universe is taken to be a transformation in
flux, of infinite dimension and time, that, in the current plasma
state necessarily leads to electrical currents and magnetic fields.

According to the Nobel lauereate Hannes Alfvén, "Space is filled with
a network of currents which transfer energy and momentum over large or
very large distances. The currents often pinch to filamentary or
surface currents. The latter are likely to give space, as also
interstellar and intergalactic space, a cellular structure."

The structure above is a cut of the plasma universe showing the
filamentary currents produced by plasma in flux. Plasma tend to
separate into regions according to temperature, density, magnetic
field strength, chemical constituency, and other physical properties.
Wherever these regions are in relative motion, they are coupled by
electrical currents that they drive in each other. Like all electrical
currents, the circuit paths are closed, sometimes over very great
distances. Thus plasmas in relative motion in one part of the universe
can produce prodigious amounts of electrical energy. This energy may
be transferred over many billions of light years to burst suddenly
from a very small and localized region representing the circuit load.

Electrical currents produce two other very important physical effects.
Electrical currents produce magnetic fields and microwave radiation.
If the electrons in the current flow have relativistic velocities and
are in the presence of the magnetic fields, synchrotron radiation is
produced. Concomittant with the generation of magnetic fields are
electric fields.

Observed Large Scale Structure of the Universe

The Scientific Method

A scientific theory must be falsifiable. This means that it must be
capable of being shown that it is wrong. Science, since the time of
Francis Bacon is based on three crucial components: the hypothesis,
theory such as the mathematics used with the basics laws to derive an
observable solution, and experiment. The last experiment, is the key
component for falsifying the hypothesis and its theory.

In astrophysics, the tools for experiment are laboratory astrophysics
and observation. A new tool, developed in the last two decades
augments both laboratory and observatonal data: simulation by
supercomputer.

Basic Model for Galaxy Formation

"Doubleness"

The signature of electromagnetic forces at work is "doubleness".
Wherever there are multiple strands of electric currents, they prefer
to interact in pairs. The reason for this derives from Ampére's Law or
the Biot-Savart force law which states that currents in the same
direction attract while currents in the opposite direction repel. They
do so inversely as the distance betweeen them. This results in a far
larger ranging force of interaction than, say, the gravitational
forces between two masses. The latter give a force that is always
attractive and which varies inversely as the square of the distance
between them.

This doubleness phenomena is observed in the laboratory when very high
currents are passed through parallel arrays of wires, that explode
into plasma currents called "pinches". The pinches often interact in
pairs.

The simplest model that may be investigated experimentally or
simulationally is that of two adjacent currents (for technology
applications as many as several hundreds of pinches are used).

The simplest geometry for galaxy formation, two adjacent Birkeland
currents of width 35 kiloparsecs separated 80 kiloparsecs across. By
scaling the current flows in astronomical objects by size, it is
determined that the average flow in a galactic Birkeland current is
approximately 1019 amperes; IA, the Alfvén galactic current.

In contrast to the experiment above, where the plasma currents are 30
millimeters in length, the galactic currents may extend 400
megaparsecs or more.

Economy in simulation, gained from observing laboratory experiments,
suggests that the active region, where large electric fields build up,
is about 10 kiloparsecs in length. That is, the salient phenomena can
be modeled with two stubby pinches. The pinches are driven, of course,
by the energy carried in the long length currents.

Evolution Over Many Billions of Years

Major Observations

1. As the pinches interact in attraction, they take on a distorted
(jellybean) profile that then elongate into peculiar shapes,
untimately, with the parameters above, arriving at a barred spiral.

2. Very early in time, the pinches produce a burst of synchrotron
radiation. This phenomena is observed both in experiments and
simulations. For the parameters of this simulation, we may identify
three principle stages in the evolution of a barred spiral galaxy:

Quasar or Double Radio galaxy
Peculiar galaxy
Barred Spiral galaxy