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by
the residentially challenged science writer, Chongo
We can
see to the edge of all light. This is our light horizon, lying approximately
fourteen billion light years away, in every direction. A short distance beyond
it lies the Big Bang, which could be considered being the very edge of space,
as anything further is contained within the depths of the Big Bang itself. The
Big Bang was once right here, when it lay right here, long, long ago. Right
now, that edge is still present, but no longer present right here anymore.
Rather, although it still lies at the Big Bang, as always, that edge lies where
the Big Bang is located right now, far, far away, in every three-dimensional
direction, from here where it was once, then, long, long ago. (See “Riding a
Beam of Light”” Article, two articles back.)
In the meantime, between then here
long ago, and now there far away, approximately fourteen billion years have
elapsed. Being the same Big Bang here then, as there now, puts the Big Bang at
two very distant regions, and logically, at every point in between these two
regions as well, during the entire course of the Big Bang's displacement from
the one distance very near to us, here, then, to the other distance, very far
from us, there, where the Big Bang lies now. All the while, the Big Bang has
been happening, unceasingly, during the aforementioned approximately fourteen
billion years, just as it constantly happens always, with each and every moment
that passes, and, just as it will continue to happen, again, unceasingly, for
eons of moments to come. As it constantly happens, one individual moment
followed by another, the Big Bang constantly recedes from us in every direction
at once, at nearly the speed of light.
Giving it a little thought, one
realizes that our equally distant displacement in three spatial directions from
the Big Bang now, is somewhat analogous to being at the center of a sphere in
three dimensions, like, for example, at the center of the sphere of a soccer
ball, with the Big Bang forming the surface of that sphere like the inflated
skin of a soccer ball would - ignoring of course, temporarily, that the Big
Bang is very small, while the skin of a soccer ball is very big compared to its
tiny center. Taking this one step further by translating the Big Bang's approximately
fourteen billion light year spatial displacement into elapsed years across
time, we find ourselves here, now, at an equally distant displacement in a
fourth temporal direction, from time's edge also, being approximately fourteen
billion years removed from the Big Bang here then, and by implication,
equivalently distant by any equal combined space and time displacement thereof.
In other words, we seem to find ourselves, quite inescapably, in the center of
what might be interpreted being a sphere in four directions, like a soccer ball
with an additional dimension of depth. But, what does that mean? What would a
four-dimensional soccer ball physically be? How would it differ from a
three-dimensional one.
Most of us ordinarily spend our
lives imagining shapes purely in three dimensions, or less, exclusively. So,
how precisely does a round sphere manifest itself in the greater complexity
that four dimensions allow, given that we are normally confined to thinking of
a sphere in three dimensions alone and on the whole have no exposure at all to
hyper-dimensional shapes of any kind? How do we imagine conceptually, the
universe in the four dimensions that it really occupies, minimally, without
reverting to the far simpler image of celestial bodies afloat in a an vast
three-dimensional extent, nested within serially grander ones beyond our light
horizon, ad infinitum "unto mysterium?" To answer, we must ask yet
another question first, about exactness and precision. It is a very necessary
question to ask, as it will answer the original question of how round in four
dimensions manifests itself in our seemingly three-dimensional world.
The question we must ask is this:
When we use the word universe, what is it exactly that we mean with our use of
the term? We must ask this question of exact meaning, because the precise
association that applies to the term "universe" may vary, according
to just what we intend with our use of the word, and furthermore, may require
specification stringent enough to fit rigorous scientific standards. The simple
answer that the universe consists of space and time in every direction, along
with all that fills it, although well enough as a general reference, may not be
as precise a meaning as we might imagine it being, because it may not express
the strictness that the rigors of science predicate. Trivial as it may seem, an
accurate understanding of nature, as expressed in its physics, even in purely
conceptual descriptions exclusive of math, requires an exact understanding with
respect to an equally precise meaning for the term universe, or we are left
with little more than the vague illusion of understanding in place of its
actuality.
Now, in order to clarify in the
precise terms of science just what is meant by the term universe, it is wise to
start by considering the most recent evolution of the term, with respect to an
important discovery available to us, that Einstein did not have available to
him at the time he was using the word; although this important discovery seems
to have only barely escaped his notice. Remarkably, it was he himself who
identified the concept that ultimately led to this great discovery, as
expressed in a value that he introduced into his equations, called the
cosmological constant.
Apparently, Einstein added the
cosmological constant to his relativity equations, setting its value
appropriately so that these equations would yield a simple, static, 'flat'
universe, which they would not have, without incorporating it, and further,
fixing its value immutably. This was an image of the universe consistent with
the widespread, conventional notions of Einstein's era. Then, the conventional
picture of the universe was pretty simple. It included only our single galaxy
alone, suspended eternally, in a flat otherwise empty space extending
infinitely in every direction. Consistent with long-standing tradition,
conventional notions left any questions of either origin or destiny, altogether
beyond the realm of scientific inquiry. To the contrary, astronomical
observations and scientific scrutiny of them would eventually demonstrate that
long-standing tradition and common convention were not well founded at all in
nature's far-better-established realities.
To his ultimate regret, by embracing
the ease of the simplistic, convention of the day, to the extent of adjusting
his equations accordingly, Einstein mistakenly failed to recognize, that is,
failed to recognize before someone else did first, that a static universe was a
universe that could simply never be. Upon review of Einstein's adjustment to
his relativity equations, a man named Friedmann proposed that the then common
notion of a finite, static universe, lying eternally in an infinite and flat,
space, without any scientific consideration for finite temporal extent with respect
to either origin or destiny, just like Einstein's specification of a
cosmological constant that results in such a simple universe, required infinite
precision, and, because of this, was plainly impossible. This left solely
dynamic solutions as viable possibilities in nature, eliminating all hope of
any unending permanence for the cosmos. According to Friedmann, space and time
were no more flat and infinite than their measures were universally absolute
for all (a direct contradiction to relativity). In a word, our universe HAD to
be dynamic. And so it was, as subsequent scientific exploration would
demonstrate, conclusively.
Not long after Friedmann proposed a
dynamic universe as the only kind of universe possible, an astronomer named
Edwin Hubble validated Friedmann's conclusions through his observations of what
were then called nebulae. Using a star of known luminosity (brightness) as a
"standard candle," Hubble determined that these nebulae were actually
other galaxies, just like our own Milky Way is a galaxy. With this achievement,
Hubble secured his name as legend in science, with what was among the greatest
revelations ever made in astronomy. Hubble had discovered the existence of
other galaxies besides our own. In so doing, he revealed the dynamic character
of our universe, irrefutably.
What, exactly, it means
for the universe to be dynamic is the subject of the next science article, and
the two that follow it. It is not as simple a notion as it might, at first,
seem to be.
(From
THE HOMELESS INTERPRETATION OF QUANTUM MECHANICS, by Chongo in collaboration
with Jose. To see all the books and prior science articles that Chongo has
written, go to chongonation.com, and click on "Science Articles."
Chongonation.com is a web site dedicated to educating those who have least
opportunity for learning the scientific foundations that describe nature
(accurately). Chongonation.com provides, in addition to its science articles,
books that allow such opportunity, in lay terms, without any math. Simply go to
the www.chongonation.com home page and click on either 'Nature' or 'Products
& Prices' to see the different books are available.)
© 2009 Chongo
All rights reserved.
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© 2009 Chongo
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