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[image: Pegasus-Symbolism-and-Meaning1.jpg]
*Pegasus:* The Winged Horse
The beautiful young woman Medusa loved the sea god Poseidon. The sea god
Poseidon merely desired the beautiful young Medusa. Possessed of the
artlessness that is particular to the youthful and love-besotted, Medusa
naturally assumed that her passionate love was requited. Even though hers
was a mortal life while the sea god would remain forever ageless, Medusa
was steadfast in her devotion and obstinate in her belief that his
professions of love were likewise sincere. So, whenever the amorous
Poseidon summoned her, she went eagerly to him. Such was the case on
that night when Poseidon arranged for them to spend the evening in one of
Athena's temples. There they made love in sight of Athena's statue: the
ultimate calculated insult. Poseidon then departed, citing the need to
calm seas that had just grown turbulent. The truth is that he had tired
of Medusa and he left secure in the knowledge that the humorless Athena
would quickly avenge the temple's desecration on her. Her vengeance was
indeed as swift as it was cruel. Athena transformed Medusa from a comely
woman to a hideous gorgon. She was disfigured from head to toe: the auburn
hair transformed into hissing serpents, the alabaster skin to dark green
scales; the teeth to tusks and the legs to a fish's under body. Horrified
by her appearance, Medusa plunged hastily into the sea and fled to the
barren rock at the world's end where the only other two other gorgons
Stentho and Euryale resided. At this far flung atoll in the company of
sisters whom she found equally repellent Medusa lived miserably. Athena,
notorious for holding grudges, eventually sent Perseus to the island to
take off Medusa's head and deliver it to her. Although Medusa could
petrify anyone with a single glance, Perseus fulfilled the task by watching
the gorgon's reflection in his highly polished shield. When she ventured
too close, he took off her head and placed it in his satchel. While he
flew on Hermes' winged sandals away from the island, some of Medusa's blood
trickled out the satchel and into the ocean. Poseidon, suddenly contrite,
mixed these blood droplets with the sea foam to bring forth Chrysaor, a
full grown warrior wholly attired in golden raiment, and Pegasus the winged
horse. Medusa was pregnant with twins sired by Poseidon when she died.
About Chrysaor little is known. He fled his birth waters into obscurity.
Pegasus, the embodiment of Medusa's beautiful spirit liberated from its
bestial prison, flew away quickly and was said to have lived free and
untamed for many years. Pegasus refused to permit any human to approach
her, for she naturally feared all devices of human constraint. One
day a young man named Bellerophon spied the winged horse soaring high above
the clouds and he yearned to ride her. He consulted the seer Polybius to
learn how he could capture the elusive Pegasus. Polybius instructed him
to spend a night sleeping in Athena's temple. It was in this same temple
that Poseidon and Medusa were said to have conceived the twins Pegasus and
Chrysaor. As Bellerophon slept in the temple, he dreamt that Athena gave
him a golden bridle and said, "Sacrifice a bull to Poseidon and with this
bridle you shall become the master of the white winged horse." Soon
after Bellerophon awoke he found the golden bridle next to him. He
followed her instructions at once. Moments after Bellerophon sacrificed
the bull, Pegasus descended to the ground next to him. While holding the
golden bridle, Bellerophon gently approached the horse who, to his delight,
yielded. He saddled Pegasus and ascended high into the sky. The
horse and the young man soon developed a deep friendship and embarked on
many adventures. The most notable of these was Bellerophon's quest to
slay the Chimera, a fire breathing creature with a lion's head, a goat's
mid section and a snake's tail. This monster had been terrorizing the
kingdom of Lycia and devoured all those who attempted to defeat her.
Bellerophon efficiently killed the Chimera by firing a barrage of arrows
into it while he sat on Pegasus soaring high above. With Pegasus' aid, he
also defeated the Solymi, a race of cannibals who had also laid siege to
Lycia, and a battalion of Amazons, fierce female warriors. Like many
adventurers before him, Bellerophon grew dangerously over confident.
Believing that his successful ventures had made him equal to the gods,
Bellerophon tried to fly Pegasus up to Olympus, the gods' principal abode.
Enraged by this show of hubris, Zeus deployed a gadfly to sting Pegasus in
mid air. Once stung, Pegasus flipped over and Bellerophon fell to Earth.
While the descent didn't kill him, he was rendered lame. The rest of his
life was a misery as he was condemned to remain always hobbling along at
sea level. Condign punishment for one who aspired to heights far beyond
mortal attainment. Zeus summoned Pegasus up to Olympus to deliver his
thunderbolts and live in comfort within the gilded stables. The
constellation Pegasus shows the winged horse flying upside down: the
position she assumed when Bellerophon descended back to Earth and just
before she was to take her place among the Olympians.

THE SOUTHWORTH PLANETARIUM
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Julian Date: 2458982.16
2019-2020: CXLV

THE DAILY ASTRONOMER
Tuesday, May 12, 2020
Remote Planetarium 32: A Sun's Life II: Life and Luminosity

*LUMINOSITY*
Luminosity measures the amount of energy a star produces every second. The
Sun's luminosity is about 3,830,000,000,000,000,000,000,000 Watts. If we
could harness the Sun's energy output over one second, we could power human
society at its current level for 650,000 years! We must discuss
luminosity before we can speak about the Sun's life cycle. Our focus will
be on how a star's temperature and size affect luminosity. We will defer
the all important *mass-luminosity relation* until another day.

*Temperature.*
Let's imagine that I am standing in front of you with a garden hose, a fire
hose and a riot control water cannon. I will set one of them on you and
you must choose which one you would prefer. What do you say? Well,
unless this unseasonably cold weather that we've been experiencing well
into May, Mr. Gore, has depressed you beyond all consolation, you will
likely choose the garden hose. Why? You know that while the garden hose
will moisten and therefore annoy you, the fire hose and water cannon could
injure you severely. What's the difference? Water pressure. Pressure
determines the force of the expelled water.

What determines a star's radiant emission? Well, yes, all you need do is
look at the title of this section to answer that question.
Temperature is related directly to *radiant flux*, the amount of radiant
energy produced per unit over a given area of a star (also at a specific
wavelength, which we will also ignore, at least for today.) Radiant
flux is proportional to the fourth power of the temperature. If, for
instance, a star's temperature doubles, the radiant flux will increase 2 x
2 x 2 x 2 = 16 times. The radiant flux is very temperature sensitive.
The previous relation is just a proportionality. In order to know the
actual radiant flux for a given temperature, we need to introduce a
"constant of proportionality."
______________________________________________
*Explaining constants of proportionality.*
Now, instead of standing before you with hoses and water cannons, I've
decided instead to give you a bag of coins. Here we have established a
proportionality: the amount of money you receive will be proportional to
the number of coins I give you. The greater the coin number, the greater
your income. However, this information alone does not tell you how much
money you will actually receive. To know this value we have to
introduce a "constant of proportionality," in other words the coin's
value. You'll have more money if you receive a hundred quarters instead
of a hundred pennies. The constant of proportionality converts a
proportionality to an equality.
_______________________________________________

The Stefan Boltzmann constant
[image: infrared-thermal-imaging-image-6-medium-2x.png]
specifies the amount of radiant energy produced as a function of time and
temperature.

Now that we've established a relationship between radiant flux and
temperature, we need to next relate it to luminosity, the entire star's
energy output. Since radiant flux measures the energy emission from a
unit area, we can calculate the radiant emission along the entire star by
multiplying the flux by the star's surface area.

[image: TSA-Sphere-300x189.jpg]
The Sun is almost a perfect sphere. (As the Sun is only 0.0007% away from
perfect sphericity, we can safely consider it spherical.) A sphere's
surface area equals 4 times pi times the square of its radius. (Pi is
the ratio of a circle's circumference to its diameter and approximately
equals 3.14159) Combining the flux and area we derive the luminosity
equation:

[image: unnamed.gif]

The Sun's luminosity relates directly to the square of its radius and the
fourth power of its effective temperature. We will not use the term
"surface temperature" because a star lacks any solid surface.

*A SUN'S LIFE*

[image: Lifecycle-of-the-Sun20160922-23875-6o6ajj.png]

As we learned yesterday our Sun coalesced from a gaseous nebula
approximately five billion years ago. The Sun became an active star
once the hydrogen-burning commenced within its core. This "burning" is
actually a complex fusion process by which hydrogen nuclei fuse to produce
helium. Initially, the Sun was much less luminous that it is today.
The chart below relates the Sun's luminosity with time:

[image: 1200px-Solar_evolution_(English).svg.png]

About 1.5 billion years ago the Sun was about 80% as luminous as it is
today and has been gradually increasing. That the young and warm Earth
revolved around a cooler Sun puzzled astronomers greatly and led to the
"Faint Sun Paradox." Read more about this paradox and its possible
solution below. The main lesson resumes after this section's conclusion.
*_____________________________________________________________________________________*
*FAINT YOUNG SUN PARADOX*
Earth's geological record tells us that liquid water covered most of our
home planet billions of years ago much as it does now. It also indicates
that life began a few billion years ago within these very waters. This
record includes sedimentary rocks that still bear the imprint of fossilized
algae and other traces of primordial life. Stellar evolution indicates that
the Sun was much cooler during its youth than it is today. The Sun's
luminosity, or energy output, slowly increases with time as helium "ash"
generated by hydrogen fusion reactions accumulates in its core. This helium
intensifies core temperatures and impels the hydrogen-burning core to
expand. Consequently, the Sun will be much hotter in the future, just as it
was cooler 3-4 billion years ago. Specifically, when life was first gaining
a foothold in Earth's oceans, the Sun should have been about 25% less
luminous than it is today. The relationship between solar luminosity and
Earth's surface temperature is a tangled mess, so Earth's temperature would
have only been 7% lower than today's average value.
Therein lies the problem, because this temperature reduction should have
made Earth a global ice box, with glaciations extending from pole to pole.
Yet, geologically, we know that the young Earth, though not tropical, was
at least warm enough to keep most of the world's water liquefied.
Is there a solution to this paradox?
Well, there are certainly "solutions," the first of which was suggested by
the two astronomers, Sagan and Mullen, who introduced this paradox in 1972.
They proposed that the young Earth contained far higher levels of carbon
dioxide than it does today, perhaps even ten times higher. Such a heavy CO2
shroud would retain a great deal of heat, while allowing very little of it
to escape to outer space. Venus, the blast furnace planet, is so hot
because it is oppressed by a thick carbon dioxide atmosphere. The problem
with this theory is that the geological record, which is nothing but
trouble, shows that the ancient atmosphere could not have contained such
high levels of this "greenhouse gas."
Other astronomers proposed that Earth's ammonia levels might have been
higher. Like carbon dioxide, this ammonia could have acted like a thermal
blanket, keeping Earth warm despite a weaker Sun. However, stellar
evolution theory indicates that the infant Sun would have been much more
active, producing copious UV radiation that would have made short work of
this ammonia.
Mass-loss was yet another idea: that the Sun experiences gradual matter
loss through solar winds and constant particle emission. If the Sun had
been more massive in its infancy, its luminosity, which increases with
mass, would have been greater than models predicted. Astronomers supporting
this hypothesis suggested that the young Sun could have lost 10% of its
matter since its formation. The hotter infant Sun would have imparted
enough energy onto Earth to produce temperatures needed to keep the oceans
liquid. Unfortunately, solar evolution models developed through studies of
helioseismology (the analysis of solar surface wave motions as a means of
determining the Sun's interior structure) do not allow for such rapid mass
loss.
So, the paradox remained unresolved for a while.
It would have been helpful if astronomers had been able to observe the young
Sun and ascertain its properties from these observations. While making
such direct observations is not possible, astronomers can do the next best
thing: they can observe a young, sun-like star somewhere else in the
galaxy. Two astronomers, C. Karoff and H. Svensmark, have done exactly
that. They have observed a star named kappa Ceti, in the constellation
Cetus the Whale. Kappa Ceti is termed a "solar analogue," because its
properties such as effective temperature, metallicity (chemical
composition), and surface gravity are similar to the Sun's. Astronomers
believe this star to be about 700 million years old, the approximate age as
the Sun when life first developed on Earth. They base this estimation on
the star's rotation rate of 8.6 days. Scientists presume that the Sun's
rotation rate decreases with time. The Sun's current rotation rate is much
slower than 8.6 days. (Its equator completes a rotation every 25 days; its
poles every 36 days.) So, by interpolation, the researchers arrived at
kappa Ceti's age value, but admit that it is not precise. By studying kappa
Ceti, these researchers have provided support to the hypothesis that the
early Sun was far more active than it is presently. Not only would the Sun have
emitted copious amounts of UV radiation, but also X-ray and other forms of
energy, including Coronal Mass Ejections (explusions of charged solar
particles). This activity increase is important because such solar
emissions would have shielded Earth from the bombardment of Galactic Cosmic
Rays (GCRs). Surprisingly, the reduction in GCR penetration into Earth's
atmosphere might well provide the clue to solve this tricky paradox.
It works this way: a coronal mass ejection is followed by a reduced influx
of GCR's over a time span of hours or even days, known as Forbush
decreases. Astronomers Svensmark, Bondo, and Svensmark demonstrated in a
2009 research paper that such Forbush decreases cause reductions in aerosol
levels, cloud water content and low-altitude cloud formation rates. Such
low-altitude clouds and aerosols have a significant influence on the amount
of solar radiation that Earth absorbs because they both affect the planet's
albedo, the percentage of solar energy re-radiated out into space. The
greater the cloud cover, the greater the amount of sunlight reflected into
outer space and the cooler Earth becomes. While we believe that such
Forbush decreases have a negligible effect on present-day climates, it is
possible that the young Sun emitted so many CME's that Earth would have
been subjected to only a fraction of the GCR's that it receives now.
Astronomers Svensmark and Karoff determined that kappa Ceti is so active
with its CME's and other radiation that any planet within the life zone
(i.e. at the same distance as Earth is from the Sun), would receive only
ten percent of the cosmic rays that Earth does now. They showed that such a
low cosmic ray penetration rate would make that planet seven degrees warmer
than it would have been had kappa Ceti not been so active. This finding is
quite promising, because if Earth had been seven degrees warmer in its
youth than it "should" have been, the paradox vanishes, thereby preserving
both stellar evolution models and the geological record. Of course, in
science, such neat tie-ups are quite rare. Every theory must withstand
other observations, studies, and perceptions. So, the paradox is still a
paradox, but now astronomers have developed a solution that might actually
unravel it.
_______________________________________________________

The chart above shows us that the solar luminosity will continue to
increase throughout the remainder of its hydrogen burning phase which
should continue for another five billion years even when the temperature
decreases as a consequence of the Sun's expansion. As the Sun's
luminosity increases, the solar constant, the amount of solar energy Earth
receives per square meter will also increase. Now the solar constant
value is approximately 1.362 kilo Watts per square meter on average. About
1.1 billion years from now, the solar constant will be so high as to render
Earth uninhabitable. Nothing to concern us quite yet.

As helium accumulates in the Sun core, the core will expand and continue to
impart heat onto its surroundings. The luminosity will increase with
this expansion. In approximately five billion years from now, the Sun
will exhaust its core hydrogen reserves and the core fusion reactions will
cease. The energy pressure that had been counterbalancing the
gravitational compression will abate, allowing gravity to compress the
core. The core will also receive heat from the hydrogen burning shell
that will then form around the helium core. This shell will then migrate
outward, causing the Sun to expand into the *Red Giant* phase.

[image: Redgiantstar.jpg]

The Red Giant Sun will engulf Mercury, Venus and perhaps even Earth. Even
if Earth isn't consumed, it will become a super heated molten planet.
Eventually, the helium core will have heated so much from the
gravitational compression combined with the outer shell's thermal energy
that "helium-burning" will commence. The helium will fuse to form carbon.
The beginning of this phase is known as the "helium flash," a runaway
period of rapid helium fusion. The core temperature at this stage will
exceed one hundred million degrees!

[image: download.jpg]
The Sun is now much larger and far more luminous due to the ultra hot
helium burning core surrounded by the comparatively cooler hydrogen burning
shell. Within about a billion years, the Sun will exhaust its helium
reserves, leaving a predominantly carbon core. However, the Sun is not
massive enough to produce the pressures and temperatures necessary to
ignite carbon fusion reactions. The core contracts and the outer
layers are expelled into space to produce both a *white dwarf* surrounded
by a rapidly expanding *planetary nebula. *The death of solar mass stars
produce these nebulae, such as the Ring Nebula seen below. They were
called "planetary nebulae" simply because they resembled planets when
viewed telescopically.

[image: 640px-M57_The_Ring_Nebula.jpg]
Ring Nebula in Lyra the Harp.
The Sun will produce a planetary nebula when its life cycle ends.

A white dwarf is an ultra-dense, super hot stellar remnant that will
gradually wick away heat energy into space to become a black dwarf.
The Sun and most stars are sustained by a delicate balance between
antagonistic forces: the ceaseless gravitational attraction attempting to
compress the Sun to a lower volume and the energy pressure that wants to
expand the Sun to ever increasing volumes. The counterbalance of these
forces, deemed, "hydrostatic equilibrium," sustains the Sun. A white dwarf
doesn't generate energy to counterbalance the gravity, so one might wonder
why it doesn't collapse down to a singularity. The reason is
*electron degeneracy*. The electrons within the white dwarf repel each
other and prevent further compression. This mutual repulsion is a result
of a quantum effect known as the "Pauli Exclusion Principle," named for
Wolfgang Pauli (1900-1959) who introduced this principle in 1925. It
states that quantum laws prohibit electrons from exhibiting the same
quantum states, or, in this case, precisely the same locations in space.
(A dubious concept in the quantum world, of course.)

The white dwarf Sun, about the size of a terrestrial planet, will slowly
cool over billions of years. Its remaining planets will continue to revolve
around it, albeit much more slowly owing to the Sun's reduced mass. The
solar system will be a dark, cold region in space: harkening back to the
time just prior to the collapse that precipitated its birth.

Tomorrow, we'll learn about the Sun's structures.

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