1826-- Olbers' Paradox and the
Necessity of a Beginning
A look at the night sky suggests a Changeless Universe,
apart from local (small-scale) phenomena, such as the Clouds drifting across
the Moon. Hence, suppose that on large-scale the Universe is static, infinite,
eternal and uniformly filled with stars. Then, one must reach the
conclusion that every point on the night sky should be as bright as the
surface of a star. The reason for this (seemingly crazy) conclusion is
that the number of stars at any given distance increases with the square
of the distance, while the intensity of light from a star decreases also
with the square of the distance. In this way we should live in the center
of a hollow blackbody whose temperature is (like that of the Sun) about
6000 degrees. This is Olbers' paradox, which can be traced as far back
as Kepler in 1610, rediscussed by Halley and Cheseaux in the eighteen century,
but was not popularized as a paradox until Olbers took up the issue in
1826. There are many possible explanations which have been considered.
Here are a few:
There's
too much interstellar dust to see the distant stars.
The
Universe has only a finite number of stars.
The
Universe is expanding; distant stars are red shifted into obscurity.
The
Universe is young; distant light has not reached us yet.
The first explanation - Olbers'
Solution - is just plain wrong. In a black body, the interstellar
dust will gradually heat up as the medium absorbs the radiation. Thus,
the clouds would glow as bright as the stars. The premise of the second
explanation may be technically correct. But the number of stars, finite
as it might be, is still large enough to light up the entire sky. The final
two possibilities are surely correct and partly responsible. There are
numerical arguments that suggest that the effect of the finite age of the
Universe - proposed originally by Edgar Allan Poe
(1948) - is the larger effect. We live inside a spherical shell
of "Observable Universe". Historically, after
Hubble discovered that the Universe was expanding, but before the Big Bang
was firmly established, Olbers' paradox was presented as proof of special
relativity; you needed the red-shift to get rid of the starlight. This
effect certainly contributes, but the finite age of the Universe is the
most important effect. Thus, if the age of the Universe
is finite, then: The Universe had to have
a Beginning, or a Genesis.
1916--Einstein published
a new theory of gravity, called general relativity.
His theory predicted a universe that would either expand or contract depending
on the density of matter and energy within it. But, in those days, however,
a dynamic universe was thought to be
such a crazy idea that even Einstein could not believe the prediction of
his own theory.
Therefore, Einstein, modified his theory to make it predict
a static universe, that is, a universe
that neither expanded nor contracted. Subsequently, Einstein would call
this fudging of his equations the biggest mistake of his life.
1919--The British astronomer Sir
Arthur Eddington led an expedition to West Africa to observe a solar
eclipse and test Einstein's prediction of the bending of light by the warping
of space and time near the Sun. The day after Eddington made public his
confirmation of Einstein's prediction, Einstein became the most famous
scientist in history.
1922--The Russian mathematician Aleksandr
Friedmann abandoned Einstein's static universe model and worked
out the mathematics and geometry of dynamic (that is, changing) universes.
To make progress with the mathematics he made the following simplifying
assumption:
the universe is isotropic
(looks the same in all directions) from every vantage point, at all times.
This implies a universe in which the matter and
energy are
uniformly distributed.
With this assumption (called by Einstein the Cosmological
Principle, which earlier Einstein had arrived at on philosophical
grounds) and using Einstein's equations of gravity Friedmann constructed
a class of mathematical models that described expanding
universes. The calculations were later repeated by the American
Howard Robertson in 1935.
1924--Edwin Hubble, using
work by Henrietta Levitt on Cepheid variables, measured the distance to
9 galaxies and proved that they are very distant.
1927--Abbe Georges Lemaitre
(a Belgian priest) took seriously the idea of an expanding universe. He
reasoned that if one went sufficiently far back in time all the matter
we see in the universe must have been squeezed into a very small volume,
a "Primeval Atom" which subsequently
fragmented to form the galaxies and stars we see today.
Lemaitre derived a relationship between (what later turned
out to be) Hubble's constant, H, and the age of the universe.
1929--Drawing on observations made by others as well
as his own, Edwin Hubble concluded that the further away a distant galaxy
is from us the greater its red shift, Z.
The red shift is defined by
Z = (lo - le)/le
where lo is the wavelength of the light that reaches Earth
and le is the wavelength of the light emitted at the source. The simplest
way to obtain a red shift from the light emitted by an object is to have
the object move away from the observer. A light source that moves away
from us looks redder, while one that moves towards us looks bluer. This
is an example of the Doppler effect.
Hubble proposed that the observed red shifts was evidence
that the galaxies are receding from
us, that is, evidence that the universe is expanding,
just as Einstein's original equations predicted.
Einstein's (self-confessed) blunder was his earlier failure
to accept this startling rediction. Had he been sufficiently bold he could
have made one of the most extraordinary predictions of 20th century science:
that the universe is expanding and came into being a finite time ago.
The velocity at which galaxies recede from us is called the
recession
velocity. Since the galaxies are receding from us, one might
be tempted to draw the conclusion that the Earth is at the center of the
expanding universe. However, according to the cosmological principle,
no place in the universe is privileged; in particular, we do not
occupy a privileged position; we are not at the center of the universe.
If we moved to another part of the universe we should expect to see more
or less the same thing: the galaxies would appear to recede from us.
1940s--George Gamow (a
Russian and ex-student of Friedmann) and later Ralph Alpher and Robert
Herman of Johns Hopkins University refined Lemaitre's idea of a primeval
atom. Alpher and Herman reasoned that far back in the past particles of
matter would be constantly colliding with each other. These collisions
would generate a tremendous amount of heat that would manifest itself as
photons of very short wavelengths. The temperature of these primordial
photons would be billions of degrees.
But as the universe expands all length scales are stretched
by the expansion including the wavelengths of the primordial photons. Recall,
that the longer the wavelength the lower a photon's energy. Therefore,
as the universe aged, and expanded, the photons would have progressively
lower energies and would therefore grow ever colder. Alpher and Herman
predicted that the universe should now be bathed in a feeble radiation
whose temperature would be just a few degrees above absolute zero. This
radiation would be literally the afterglow of the earlier extremely hot
dense phase of the universe. Alas, for Alpher and Herman, their ideas were
more or less forgotten.
1965--At Bell Labs in New Jersey, Arno
Penzias and Robert Wilson were preparing a radio telescope to observe
the Milky Way. They noted a persistent background noise wherever they pointed
their telescope. They tried very hard to get rid of it, but couldn't. It
finally dawned on them that this was not mere noise. In fact, they had
discovered, by accident, photon radiation coming from outer space, that
was not associated with any known astronomical objects. This radiation,
which is in the microwave part of the electromagnetic spectrum, is now
called the cosmic microwave background (CMB).
At the same time Bob Dicke and Jim
Peebles (at Princeton), working on a suggestion by George Gamow
that the universe might have been hot and dense in the past, were just
getting ready to look for the afterglow radiation from this dense hot phase
of the early universe when they were scooped by Penzias and Wilson. Sadly
for Dicke and Peebles it was Penzias and Wilson
who got the 1978 Nobel Prize for Physics
for their accidental discovery of the microwave background!
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