spring 2012 astronomy course mississippi valley night sky conservation the sky around us...
TRANSCRIPT
Spring 2012 Astronomy CourseMississippi Valley Night Sky ConservationThe Sky Around Us
Instructors:Pat BrowneStephen CollieRick ScholesCourse assistant
Amy Booth April 20 2012
Announcements:
Errata – M46, M47 in the constellation Puppis
Course Assistant Amy Booth
Course Group online: http://tech.groups.yahoo.com/group/MoK_NSC/
invitations pending…
Program developed byMississippi Valley Conservation
AuthorityRoyal Astronomical Society of
CanadaOttawa Astronomy FriendsEarth Centered Universe software for illustrations –
courtesy David Lane
WHERE Locating stars on the Celestial Sphere -
Constellations, Aligning our telescopes to track the
stars
WHEN Do they rise and set on our local
horizon
WHAT Stellar properties, stellar designation,classificationasterisms clusters of stars
WHOPioneers in stellar astronomy:Annie Jump CanonHelen Sawyer Hogg (Canadian)Ejnar Hertzprung- Henry Russell
II Stars in our Milky Way Galaxy
Our first NightSky…
Last week on our plansiphere
Objects on our Celestial Sphere = Stars in our Milky Way Galaxy
Celestial Sphere – April 20 2012Recall: What we see in the sky
depends
1. Date2. Time 3. What our latitude is which sets
our local horizon4. Demo first on the planisphere
then on the celestial sphere (local horizon)
5. Lets do this for April 20… The stars rise 4 minutes earlier each
day because the earth has also moved through its orbit as it has rotated around from night to day to night.
Star Time – Sidereal Time A year on earth in star time…Sidereal Time = our time measurement
with respect to the stars.. 1 Day = 1/365th of a circle ~ about one degree around the Sun. Earth rotates on its axis as well as rotates around the sun.
So, the time for a star to return to the same place in our sky the following evening is only 23 hours, 56 minutes and 4 seconds (not 24)This is called a sidereal day ( 1 revolution of the earth with respect to the stars)
Do the earth rotating dance around the sun then with respect to the stars infinitely far away…
Lets do this for Apr 20…
Say ‘goodbye” to winter constellations
Observations from Last week
Open ClustersNebula and Stars Globular ClustersGalaxies
As the Earth Turns –Tour of the Night SkyApril 13 2012, 9pm EDT
When planning your are observing session , start with the things that aregoing to set first – Westward HO!Here is the ECU view of the celestialsphere showing the western sky,You can see this on your planisphere. But your planisphere does not record the planets because they change from year to year. ECU can program the planets in… Jupiter, nearly set…Venus (the brightest object)We shall see a phase on VenusConstellation Object---------------- ---------Taurus M1 Crab Nebula – Supernova
remnant
Taurus M45 – the Pleaides – setting…
Gemini M35 – Open Cluster Auriga M37,M36,M38 OCsOrion M42 Orion Nebula Emission, M78
Reflection Nebula
Monoceros M46, M47 OCsCancer M44 Beehive Cluster , M67 We finish the Western tour with ruddy
Mars which is culminating on our meridian.
horizon (west)
line of the planets (ecliptic)
N/S line - Meridian
M1
M45
M37M36
M38
M42
M78
M46,M47
M35
Mars
M67
Jupiter
VenusVenus
M44
What We Observed
Recall:We went after the western Winter sky – objects that
would soon set.These objects were mostly in the Winter Milky Way
althouch you couldn’t tell that because the sun was still lighting up the horizon
We saw lots of Open Clusters . Their sizes/brightness differences were obvious in Puppis (not Monoceros) M47 vs M46
Cancer Beehive M44 vs M67
We saw Emission and Reflection Nebula like M42 and M43 which are in fact illuminating proto-stars
We saw a Supernova Remnant, the Crab Nebula in Taurus, … the Cosmic Dust Bunny!
Particular observations?
Constellation Celestial Object
Taurus M1 Crab Nebula
Taurus M45 Pleiades
Gemini M35
Auriga M37
Auriga M36
Auriga M38
Orion M42
M43
M78
Puppis (not Monoceros) M47
M46
Cancer M44 Beehive
Cancer M67 2700 6.1 30
Leo M65 - Leo Triplet
M66
Canes Venatici M3 - Globular Cluster 33900 6.2 18
M51 - Whirlpool Galaxy 37000000 8.4 11x7
Ursa Major M81 12000000 6.9
21x10
Ursa Major M82 - peculiar galaxy 12000000 8.4 9x4
Distance, Magnitude, Size
Constellation Celestial Object Distance (lys) Magnitude Size
Arc min
Taurus M1 Crab Nebula 6300 8.4 6x4
Taurus M45 Pleiades 440 1.6 110
Gemini M35 2800 5.3 28
Auriga M37 4400 6.2 24
M36 4100 6.3 12.0
M38 4200 7.4 21
Orion M42 1300 4 85x60
M43 1300 9 20x15
M78 1600 8.3 8x6
Puppis (not Monoceros) M47 1600 5.2 30
M46 5400 6 27
Cancer M44 Beehive 577 3.7 27
Cancer M67 2700 6.1 30
Leo M65 - Leo Triplet 60,000,000 9.3 8x1.5
M66 60,000,000 8.9 8x2.5
Canes Venatici M3 - Globular Cluster 33,900 6.2 18
M51 - Whirlpool Galaxy 20,000000 8.4 11x7
Ursa Major M81 10,000000 6.9 21x10
Ursa Major M82 - peculiar galaxy 10,000,000 8.4 9x4
Distance Graph and Brightness Graphs of what we saw
Galaxies
Globulars
Distance dimming
When we look at Open Clusters, we are looking into the disk of the Milky Way between 500 – 1000 light years distance.
It turns out we are looking at two different spiral arms – Auriga Open Clusters are in the Perseus Arm, whereas the Orion/Puppis clusters are in the Orion Arm
When we look at Globular Clusters we are looking 10x more deeply out of the disk of the galaxy in a halo around it – M3 is one example
Finally when we look at Galaxies, we are looking outside of our own galaxy > 10,000,000 light years
The brightest objects are the smaller magnitudes! !
Surface brightness depends on the concentration of the
material as well as the distance to the object.
M1, the Crab nebula is considered a difficult object in
the city because of its low surface brightness.
It is also on the higher end of the distance for these
asterisms.
Log
Practical Procedures – when thinking about Telescopes
What we practically need to know is how
to set up our scopes if we have an
equatorial mount. …
Setting up our equatorial mount is
just like setting our local horizon on the
celestial sphere…
To set the scope polar axis to the celestial polar axis, the wedge is rotated to match the altitude of polaris at your latitude.
This is the same thing as setting the altitude of the polestar equal to our latitude (45 deg)
Point the telescope North and
Look up the polar axis.
Se the altitude of the wedge to
• your Latitude. To line us up on the axis. We do this by
• pointing to the Pole star Polaris.
Polaris should be centered in the eyepiece
www.astro-baby.com/simplepolar/simple_polar_alignment.htm
Celestial Coordinate System = Equatorial Mount
Coordinates
Once we are aligned, we only have to nudge the Right Ascension axis (around the polar axis), in order to keep the object centered in the eyepiece.
Because when we are aligned with our polar axis we track the sky.
Celestial Equator
Meridian facing north
Polaris in not on the zenith but roughly 45 degrees up = our latitude above the equator
Lines of Right Ascension Parallels of
Declination
The equatorial mount has the same axes as
the celestial sphere. It is an alt-azimuth
mount that has been tilted up to the pole star
so that one axis can be turned with the earth
turning.
Back to what’s out there in …
the Night Sky …
Different scopes without equatorial mounts
Star hopping to find objects does not require fancy mounts
When we observe…
1. Always dress warmly as if it were still winter.
2. Standing around in the springtime can get chilly because you are not moving
3. Allow your eyes to adapt to what you are seeing
4. Learn not to stare into the eyepiece but let your eye relax and allow the peripheral vision to see things too
5. Use a red flashlight to consult charts if you are trying to hunt something down
6. Keep an observing Log! and record observations even if you’re tired
7. “If you don’t keep a logbook you’ll always be a beginner.”
Celestial Sphere Earth Centered Universe
Computed for our location
Given our geographical position and time on the earth: our latitude, our time zone and our Time of Day, ECU displays an accurate description of our celestial sphere for our position on the earth.
We can use a manual planisphere, set it for our time of year and day for our location to determine whether the object is above our horizon, what our L.S.T is, to place it on our meridian, etc
We are ready to plan our observing session and view not only stars, but star clusters, galaxies,etc.
But everything, stars, asterisms, constellations, galaxies have a time and a season… according to sidereal time.
M65, M65 Galaxies
Constellations: Area of sky identifiable by star pattern
Leo
BootesGemini
Virgo
Hydra
Cancer
Ursa Major
Corvus
Looking South then pan east or west of our meridian
Click to see the major constellations
Saturn
Mars
Exercise 1:
Go out and observe these constellations. How many bright stars can you see in them. Number them…
Optional – DVD Chapters 4,5,6,7,8,9,11,12
ecliptic
Constellations and asterisms are not necessarily close
to each other in space. Everything is at a nearly
‘infinite’ distance on our celestial sphere within our
Milky Way. This is to assign proper oordinates to them.
Historically, the brightest stars on were grouped
together into constellations and asterisms and the
brightest stars gained proper names. Extensive catalogues of stars have been
assembled by astronomers, which provide
standardized star designations.
Greek Letters (Bayer Catalogue) order by relative
brightness so that Alpha Leonis is brighter than
Gamma.
Their absolute positions in RA and DEC were recorded at special Meridional telescopes
fixed to watch stars culminating on the meridian.
The ancients grouped those constellations that traveled along the ecliptic (the path of the planets) into the Zodiac
There are 4 zodiacal constellations here…Gemini, Cancer, Leo, Virgo12 Zodiacal Constellations out of 88 modern ones (including Southern Hemisphere).
When we observe stars naked eye …Starlight and Spectra (some clues)
What visual clues tell us?
• Brightness• Colour
Brightness doesn’t really tell us the distance (parsecs or light years) because we need to know their intrinsic brightness
Colour – will tell us something about their temperature
Other Propertiesluminosity (intrinsic brightness) and spectra (relative abundance of spectral lines in the light from the star),Tell us about -the age (> millionsof years)- the distance to the object-chemical composition of the stellar object.
Without its spectral type a star is a meaningless dot.
Add a few letters and numbers like "G2V“ and the star suddenly gains personality and character
WHAT is a star… The Sun is a Star
A star is a massive, luminous sphere of plasma held together by gravityAt the end of its lifetime, a star can also contain a proportion of degenerate matter. The nearest star to Earth is the Sun, which is the source of most of the energy on Earth.
In a plasma gas, a certain portion of the particles are ionized. This is because the gas is heated to high temperatures at which point a gas may ionize its molecules or atoms (reduce or increase the number of electrons in them), thus turning it into a plasma, which contains charged particles: positive ions and negative electrons or ions.
Sun is below our horizon at 10 pm along the path of the plane of the ecliptic
This figure shows some of the more complex phenomena of a plasma. The colors are a result of relaxation of electrons in excited states to lower energy states after they have recombined with ions. These processes emit light in a spectrum characteristic of the gas being excited.
When a star is brought into the field of view and the spectroscope is properly focused and adjusted, you will see a beautiful spectrum with the colors of the rainbow spread out along its length. Depending on the spectral type and luminosity class of the star, and your particular setup, you may see hydrogen lines cutting perpendicular across the spectrum, or many fine lines of metals, or wide absorption bands of molecules. These lines and bands in stellar spectra have been called the "fingerprints of the stars" because their patterns identify the elements in a star's atmosphere and indicate a star's temperature. These spectral features are easy to see in some classes of stars and more difficult to see in others.
The image below was taken with the Visual / Photo / CCD Star Spectroscope:
http://www.starspectroscope.com/index.html How are spectral lines formed?By electrons jumping between different energy levels in the
atoms in the star's outer layers. Bound electrons can absorb and emit
energy only in certain discrete amounts. When an electron absorbs a photon of light with just the
right amount of energy, it jumps to a higher energy level. When the
electron spontaneously jumps back to a lower energy level, a photon is emitted.
Enough electrons jumping between any two given energy levels of a given
element will result in a spectral emission or absorption line at a characteristic
wavelength.For example, the strongest spectral line in a hot main-
sequence star like Vegalies in the blue-green part of the spectrum. It is a dark or absorption line resulting from electron jumps from the second to the fourth energy level of the neutral
hydrogen atom, and is known as hydrogen beta (in the Balmer series).
Visual Star Colour and Star Spectra using Spectroscope
Color Star Atlas or Color Stars in ECU
The main reason why stars are differently coloured is that some are hotter than others. Deep in their interior all stars are enormously hot (measured in millions of degrees), but their temperature lessens towards their outer layers, and the coolest star pours out most of their visible radiation in the red part of the spectrum. Hotter stars like the Sun appear yellow, still hotter stars appear white, and the hottest appear blue. The spectral type of a star is not the same thing as its intrinsic colour although the two are closely related. When starlight passes through a spectograph ( a prism or glass grating) it is split into the colors of the rainbow, a spectrum. Most importantly there are spectral absorption lines that give a clue to the temperature and the chemical composition of that star Almost all starlight spectra can be assigned to one of seven main types (OBAFGKM).
A great deal about the nature of the star can be inferred from its spectrum : how bright it really is, how massive it is, whether it is a compact main sequence star (see next slide) or a swollen giant. Broadly speaking, we can tell how old it is, and what is happening to it with respect to its hydrogen, helium or heavier element combustion process.
Coma Star Cloud – and star colours!
Hertsprung-Russell Diagram to classify Stars according to their Spectral Class
Stars and their Spectra
Most stars gather in certain narrow regions of the H-R diagram according to their masses and ages. Stars arrive on what's called the main sequencesoon after they are born, and this evolutionary track is where they spend most of their lives.
Massive stars blaze brightly on the hot, blue end of the main sequence. They burn up their nuclear fuel in only millions or tens of millions of years. Stars with lower masses comprise the yellow, orange, and red dwarfs on the lower-right part of the main sequence, where they remain for billions of years.
As a star begins to exhaust the hydrogen fuel in its core, it evolves away from the main sequence toward the upper right and becomes a red giant or supergiant. Stars that began with more than eight times the Sun's mass then evolve left and right through complicated loops on the H-R diagram as if in a frenzy to keep up their energy production. Then they finally explode assupernovae. Less massive giants evolve to the left and then down to becomewhite dwarfs; this is the track the Sun will trace through the H-R diagram
Class
Temperature[8]
(kelvins)Conventional
colorApparent color[9][10]
[11]
Mass[8]
(solar masses
)
Radius[8]
(solar radii)
Luminosity[8]
(bolometric)
Hydrogen
lines
Fraction of allmain sequence stars
[12]
O ≥ 33,000 K blue blue ≥ 16 M☉ ≥ 6.6 R☉ ≥ 30,000 L☉ Weak ~0.00003%
B10,000–33,000 K
blue to blue white blue white 2.1–16 M☉ 1.8–6.6R☉
25–30,000 L☉
Medium 0.13%
A7,500–10,000 K
white white to blue white 1.4–2.1M☉ 1.4–1.8R☉ 5–25 L☉ Strong 0.6%
F 6,000–7,500 K yellowish white white 1.04–1.4M☉ 1.15–1.4R☉ 1.5–5 L☉ Medium 3%
G 5,200–6,000 K yellow yellowish white 0.8–1.04M☉
0.96–1.15R☉
0.6–1.5 L☉ Weak 7.6%
K 3,700–5,200 K orange yellow orange 0.45–0.8M☉ 0.7–0.96R☉ 0.08–0.6 L☉Very weak
12.1%
M ≤ 3,700 K red orange red ≤ 0.45 M☉ ≤ 0.7 R☉ ≤ 0.08 L☉Very weak
76.45%
Stellar classification is a classification of stars based on their spectral characteristics. The spectral classof a star is a designated class of a star describing the ionization of its chromosphere, what atomic excitations are most prominent in the light, giving an objective measure of the temperature in this chromosphere. Light from the star is analyzed by splitting it up by a diffraction grating, subdividing the incoming photons into a spectrum exhibiting a rainbow of colors interspersed by absorption lines, each line indicating a certain ion of a certain chemical element. The presence of a certain chemical element in such an absorption spectrum primarily indicates that the temperature conditions are suitable for a certain excitation of this element. If the star temperature has been determined by a majority of absorption lines, unusual absences or strengths of lines for a certain element may indicate an unusual chemical composition of the chromosphere.Most stars are currently classified using the letters O, B, A, F, G, K, and M (usually memorized by astrophysicists as "Oh, be a fine girl, kiss me"), where O stars are the hottest and the letter sequence indicates successively cooler stars up to the coolest M class. According to informal tradition, O stars are called "blue", B "blue-white", A stars "white", F stars "yellow-white", G stars "yellow", K stars "orange", and M stars "red", even though the actual star colors perceived by an observer may deviate from these colors depending on visual conditions and individual stars observedhttp://en.wikipedia.org/wiki/Stellar_classification
Stellar Spectratells us surface temperature,
chemical compositionatmospheric pressure and surface gravity,
total luminousity (energy pouring out)
http://www.skyandtelescope.com/howto/basics/3305876.html?page=2&c=y
Whether in a star's atmosphere or in a laboratory, absorption lines are produced when a continuous rainbow of light from a hot, dense object (top left) passes through a cooler, more rarefied gas (top center).
Emission lines, by contrast, come from an energized, rarefied gas such as in a neon light or a glowing nebula. When I look at a star, why do I see dark absorption lines rather than
bright emission lines?Gas under high pressure produces a continuous spectrum, a rainbow of colors. Continuous radiation viewed through a low density gas results in an absorption-line spectrum.What's happening here is that radiation emitted by gas under high pressure deep within the star is being absorbed by low density gas in the star's outer layers.
We can show this in the lab:Using a slit and prism, physicists discovered that when a solid, liquid, or dense gas is heated to glow, it emits a smooth spectrum of light with no lines: a continuum. A rarefied hot gas, on the other hand, glows only in certain colors, or wavelengths: bright, narrow emission lines instead of a rainbow band. If a cooler sample of the same gas is placed in front of a glowing object emitting a continuum, dark absorption lines appear at the wavelengths where the emission lines would be if the gas were hot.What kinds of deep sky objects have emission-line spectra?A low density gas shows an emission-line spectrum, when not observed against a background of continuous radiation. Thus emission lines are found in the spectra of planetary and diffuse nebulae, and in some stars. In the latter case the lines often arise from gas clouds ejected from the star by strong stellar winds.
ClassTemperature[8]
(kelvins)Conventional color Apparent color[9][10][11] Mass[8]
(solar masses)Radius[8]
(solar radii)Luminosity[8]
(bolometric)Hydrogen
linesFraction of all
main sequence stars[12]
O ≥ 33,000 K blue blue ≥ 16 M☉ ≥ 6.6 R☉ ≥ 30,000 L☉ Weak ~0.00003%
B 10,000–33,000 K blue to blue white blue white 2.1–16 M☉ 1.8–6.6R☉ 25–30,000 L☉ Medium 0.13%
A 7,500–10,000 K white white to blue white 1.4–2.1M☉ 1.4–1.8R☉ 5–25 L☉ Strong 0.6%
F 6,000–7,500 K yellowish white white 1.04–1.4M☉ 1.15–1.4R☉ 1.5–5 L☉ Medium 3%
G 5,200–6,000 K yellow yellowish white 0.8–1.04M☉ 0.96–1.15R☉ 0.6–1.5 L☉ Weak 7.6%
K 3,700–5,200 K orange yellow orange 0.45–0.8M☉ 0.7–0.96R☉ 0.08–0.6 L☉ Very weak 12.1%
M ≤ 3,700 K red orange red ≤ 0.45 M☉ ≤ 0.7 R☉ ≤ 0.08 L☉ Very weak 76.45%
The sun is a G2 star representing 7.2% of the statistical population within 10 pcs.
Annie Cannon 1863 –1941 Harvard College Observatory Astronomer applied her own scheme which resulted in the famous OBAFGKM classification which is still used
today
The Sun's spectrum was marked by many narrow, black lines of various intensities.
These dark lines stayed at exactly the same places in the colorful band from day to day
and year to year. This solar spectrum — a 'rainbow' of sunlight with thin, dark absorption lines at numerous discrete wavelengths.
Each chemical element creates its own unique set of spectral lines.Similar spectral lines showed up in laboratory
Stellar Spectra Summary
Stellar Spectra
1. surface temperature2. chemical composition3. atmospheric pressure and surface gravity4. total luminousity (energy pouring out)
*The temperature sets the star's color and determines its surface brightness:how much light comes from each square meter of its surface.
The atmospheric pressure depends on the star's surface gravity and therefore, roughly, on its size — telling whether it is a giant, dwarf, or something in between.
The size and surface brightness in turn yield the star's luminosity (its total light output, or absolute magnitudeand often its evolutionary status (young, middle-aged, or nearing death).) The luminosity (when compared to the star's apparent brightness in our sky) also gives a good idea of the star's distance
Note also that the colour of the star is related to the
corresponding peak wavelength emitted
of the continuous radiation: λmax = b/ T
where λmax is the peak wavelength, T is the absolute temperature
of the black body, and b is a constant of proportionalitycalled Wien's displacement constant, value).http://en.wikipedia.org/wiki/Wien's_displacement_law Knowing the suns temperature, we infer a particular colour expressed as a wavelength in the visible …
T=5500
T = 5000
λ = λ max
Stellar Classification - Who
• http://astro.berkeley.edu/~gmarcy/women/cannon.html
Annie J. Cannon discovered that nearly all stars' spectra can be fit into one smooth, continuous sequence. The sequence matched the stars' color temperatures, from the hottest, blue-white stars at one end to relatively cool, orange-red ones at the cool end . The basic sequence ran O B A F G K M from hot to cool.
Planning your Observations
• Get a book from the library or a magazine that features a particular selection of objects visible from your location at the current date
• You can use ipod type devices but plan what you are doing beforehand so that you don’t just stare at the ipod
• Better to plan indoors first . Use a planetarium program like ECU. We can do a lab showing how to set the time, place, information detail, catalogues…
• Make sure you are comfortable at the eyepiece
• You can sit down when you get tired.
Plan your session. Choose an area to work on and pick from a list of different things: stars with colour/ colour contraststar clustersstar nebulae and nursuriesgalaxiessupernovae remnantsclusters of galaxies
ECU
Earth Centered Universe
Looking up – Spring Night Sky exploration
What binary stars can you see – pick some famous ones
What color contrasts can you observe? Blue and yellow??
1. How do you use stellar ‘landmarks’ to hop to non-stellar objects such as the Virgo Cluster of Galaxies(hint – Find Epsilon Virgo andBeta Leonis)
… or the cluster of galaxies in2. Leo, M65,M66?
3What does the M stand for… when we talk about Messier objects? 4.What kinds of M objects are there?
5.What kind of object is M44? (The Beehive cluster)
Star- Hopping to find Star Clusters and Clusters of Galaxies
Alpha Bootes
To find the Markarian Chain of
Galaxies in the Virgo cluster, locate
Epsilon Virginis and Beta Leo . They lie
half-way along the line
To find M65, M65 drop
down from Theta Leonis
To find M3 (Globular Cluster) locate
Arcturus (Alpha Bootes) and Alpha
Canes Venatici (not shown) . M3 is 1/3
of the way from Alpha Bootes
See ObservingGalaxies.ppt on the Millstone Website for more information