[image: Arnold_Houbraken_-_Jupiter,_Juno_and_Io.jpg]

*Io:  * Flight from Ghost and Gadfly
Io was the daughter of the oceanid Melia and Inachus, a river god and the
first king of Argos.  Like Callisto, Io decided to live a chaste life.
Her resolve was often tested as she was beautiful and had to fend off many
suitors.    She repelled them  all effortlessly.  Her troubles
began, however, with a series of disturbing dreams.    In these night
visions, Io saw images of haunting green-haired girls who lurked in forest
groves and disordered the wits of travelers.  Along with these girls was
Zeus who whispered pleas of love to the frightened Io.   He begged her to
lie with him in the verdant meadows of Lerna.  One morning, Io spoke of
these dreams to her father, Inachus.  Inachus consulted the delphic Oracle
which commanded him to banish Io forever, lest the enraged Zeus strike down
every mortal in his kingdom with his notorious thunder bolts.  So, poor Io
was banished.  Soon thereafter, when the rivers joined to lament the
transformation of Daphne to a tree following Apollo's relentless pursuit,
Inachus alone remained apart from the others, for he was lost in a swell of
tears over the daughter he would never see again.  Although her father
couldn't see her, Zeus certainly did.   Io was walking along the outermost
tributaries of her father's tear rich stream, so as to remain, though
unseen, close to the father she was forced to forsake.  Sensing Io's
distress, Zeus invited her to recline in a grove of trees where the fair Io
would find cool shade against the noon time sun.   Remembering her dream,
Io fled across the fields of Lerna and into the concealing canopies of
Lycrea, where she then beheld a gathering storm cloud: Zeus in his proper
form.   Before the designing god could make defeat of her virginity, Hera
transformed Io into a bull.    Suspecting that this transformation wouldn't
deter her lustful husband, Hera summoned a gadfly to constantly sting Io,
causing her to constantly move in a vain effort to escape the cruel,
bothersome insect.   As if that were not sufficient torment, Io was also
watched by Argus, the giant monster with a hundred eyes.   He proved an
effective watchman, for his eyes slept at different times and he could
always watch the poor tormented Io with the eyes that remained awake.
At Zeus' command, Hermes, in the guise of a shepherd,approached and
befriended Argus.  Once he has gained the other's trust, Hermes played such
soft music for him on the lyre that it caused all the eyes to drift off to
sleep.    Zeus then struck off the monster's head.  Despite the success of
this plan, Io was still impossible to retain, as she kept moving due to the
gadfly's constant pursuits.   Also, she was now pursued by Argus' enraged
ghost. As ghosts needed no sleep, Argus couldn't be lulled into slumber
again.   Io fled across the world; to Dodona, the prophetic oak who
pronounced her as Zeus' bride.   She also encountered Prometheus, chained
to a rock as a punishment for bringing fire to the mortals.    Though he
suffered the pains of having eagles gnawing on his liver, Prometheus also
told Io a prophecy of her eventual worship in Egypt and encouraged her to
find refuge there.     Io fled to the Egyptian desert, where the gadfly
perished and Argus' ghost was repelled by deities sympathetic to Io.   It
was there that Zeus finally encountered her. Wearied by the dogged pursuits
of the ghost and gadfly, Io allowed Zeus to approach her. With a touch of
his hand, Zeus restored her back to the form of a woman and at the same
time also made her pregnant with Epaphus, whose name means "he of the
touch."   Io remained in Egypt, where she was worshiped as the goddess
Isis.  Her son Ephaphus would also experience an apotheosis, eventually
becoming identified as the bull-god Apis.


THE SOUTHWORTH PLANETARIUM
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Julian Date: 2459026.16
2019-2020:  CLXIX


THE DAILY ASTRONOMER
Thursday, July 2, 2020
Remote Planetarium 57:  Intrinsic Variable Stars I - Cepheids

Yesterday we discussed the two main types of extrinsic variable stars:
eclipsing binaries and rotating stars.  Today, we begin our discussion
about intrinsic variable stars, those stars whose variability results from
processes occurring within the star, itself.     As we shall see, the
different types of intrinsic variable far outnumber the extrinsic, hence
the necessity of dividing the intrinsic variable lesson into more than one
part.

The chart below shows a variable star "tuning fork" diagram.   While the
extrinsic variables subdivide only into two categories, the
intrinsic variables subdivide into two categories that each contain
multiple subdivisions.       Today's RP focuses on Cepheids, one of
astronomy's most important types of variable stars.  Astronomers were able
to use these stars to determine the distances of extremely remote objects,
such as globular clusters and galaxies.

[image: classification-660x381.jpg]
We begin with a quick review about stellar *luminosity*, defined as a
star's energy output over the period of one second.       A star's
luminosity depends on its size and effective temperature.    Recall the
following equation introduced in RP # 37:

[image: unnamed.gif]


The luminosity increases with the square of the radius and the fourth power
of the temperature.    If a star expands, its size increases, but its
effective temperature will also increase.  As its name implies, "pulsating
variables" expand and contract.  Consequently, a pulsating star's size and
temperature -and therefore, luminosity- vary throughout each pulsation
cycle.  Cepheids, one of the best known types of pulsating variables,
operate on this same principle.      The mechanism responsible for Cepheid
pulsation involves ionized and doubly ionized helium.      Helium is
ionized when it loses one electron and when it loses both electrons is
doubly ionized.

[image: download.png]
As the helium layer contracts due to the Cepheid's gravitational
attraction, it absorbs heat and in the process becomes more ionized.
Doubly ionized helium is more opaque than singly ionized helium or neutral
helium. As it is more opaque, it collects more heat.  (As an analogy, think
of how darker colors absorb more heat than lighter ones.)    As the doubly
ionized helium layer heats up, it begins to expand.  The expansion causes
the layer to cool.  The cooled helium then regains an electron to become
singly ionized.    The singly ionized helium, being less opaque,  allows
more heat to escape.  The expansion ceases and the gravitational
contraction resumes.  The compressed layer then heats, the helium becomes
doubly ionized and the layer becomes more opaque.    The heating induces
the next expansion and the cycle continues again.

Cepheid variables have proven to be immensely useful for distance
determination purposes.    A cepheid's variability period is directly
related to its luminosity, hence the term *period-luminosity relation*.
 The more luminous the cepheid, the longer the period.     Astronomers
recognize two types of Cepheids, I and II.


   - *Type I Cepheids:* a.k.a. "Classical Cepheids."   High
metallicity, *Population
   I* stars that are between 4- 20 more massive than the Sun.   They can
   also be as much as 100,000 times more luminous.
   - *Type II Cepheids: *  Low metallicity, Population II stars of low mass
   (less than the Sun.)

   Each type has its own period luminosity relation curve, as seen below.
[image: Period-Luminosity_Relation_for_Cepheids.png]

The  horizontal line indicates the pulsation length period in days) and the
vertical shows the star's corresponding absolute magnitude, which is
related directly to its luminosity.   By observing the Cepheid's period, an
astronomer will automatically know its absolute magnitude.  By comparing
the absolute magnitude with the apparent magnitude that was directly
observable, the distance to the cepheid variable, and by extension to the
galaxy containing it, could be ascertained.

__________________________________________
*How did they work out the Period-Luminosity Relation?*
Henrietta Swan Leavitt discovered the Period-Luminosity Relation by
observing Cepheid variable stars with the Small Magellanic Cloud. This
"Cloud"  is a satellite galaxy to the Milky Way at an estimated distance of
160,000 light years from Earth. Even though the SMC has a diameter of 7,000
light years, we can assume that all the stars are at more or less the same
distance from us. Similarly, we can assume that every citizen of Los
Angeles County is at the same distance from Portland, Maine.  Professor
Leavitt surveyed the Cepheid variables within the SMC and noticed that the
brightest Cepheids exhibited the longest variability periods. Through
careful observations, she determined a correlation between the Cepheid
variable's brightness and variability period. These observations served to
establish this relationship.  Direct distance determination of Delta
Cephei, the very first Cepheid discovered - hence, the name - provided
astronomers with that Cepheid's luminosity. This knowledge provided them
with the key to establishing the actual period luminosity relation.
[Note: by measuring Delta Cephei's distance through parallax, they could
compare its apparent brightness and distance to determine the star's actual
brightness, or luminosity. Distance, apparent brightness and absolute
brightness are the three factors involved in the "distance modulus"
equation. The determination of two yields the value of the third. Leavitt's
discovery enabled astronomers to use Cepheid variables as distance
indicators.
_________________________________________________________

[image:
andromeda-galaxy-Navaneeth-Unnikrishnan-11-9-2014-Kerala-India--e1570106613902.jpg]
Edwin Hubble is credited with having used Cepheid variables to ascertain
the distance to the Andromeda Galaxy.    He calculated its distance to be
around 800,000 light years, less than half the currently accepted value of
2.2 million light years.    He based his calculations using the light curve
now known to correspond to the second Cepheid variable type.   While this
initial distance value was woefully inadequate, it did firmly place the
"Andromeda Nebula" outside the Milky Way Galaxy's boundaries.

As we will discover,  there are other pulsating variables apart from the
Cepheids.  They, too, have often proven quite useful to astronomers in
their efforts to surmise the true extent of the cosmos.

More on variable stars next week.
Quiz tomorrow.

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