1. Celestial Distances A Galaxy 150 Million Light Years From Earth
February 14, 2006
Astronomy 2010

2. Distance and Motion of Stars
To infer luminosity, mass, and size from observations we need to know the distance to a star.
Distance units for stars:
light year (LY): distance light travels in one year
1 LY = 9.46 x 1012 km
Rigel 775 LY, Betelgeuse 1,400 LY
Proxima Centauri 4.2 LY nearest
parsec: 1 pc = 3.26 LY
Motion of the star relative to the Sun (Ch. 16):
radial motion: star moves along line of sight
proper motion: star moves across celestial sphere
February 14, 2006
Astronomy 2010

3. Stellar Distances How can we measure such great distances?
We use several techniques, useful at different scales, with each scale connecting to the next, like the steps of a ladder.
Precise determination of the metre.
Radar measurements of distances to planets to determine the astronomical unit (AU).
Parallax measurements of nearby stars
Variable stars
H-R diagram
Red shift and supernovae (later chapters)
February 14, 2006
Astronomy 2010

4. Parallax Effect wavy motion: parallax effect period of 1 year
distance to star is 6.0 LY
type M
straight line is the star's proper motion
February 14, 2006
Astronomy 2010

5. What is Parallax?
nearby star appears to move back and forth compared to more distant stars
Barnard's star: 6.0 LY
parallax depends on distance  use it to measure distance
February 14, 2006
Astronomy 2010

6. Parallax on the Earth View object from 2 vantage points
Determine distance using trigonometry
Object appears to shift positions compared to the far off background
Angular shift, called the parallax: angle of a triangle and the distance between the two vantage points is one side of the triangle
how far away is the tree?
measure baseline distance B with a meter stick
measure parallax angle p
use trigonometry to derive distance
February 14, 2006
Astronomy 2010

7. Parallax for Stars Need Earth-Sun distance View Sun and Venus
why we need A.U.
View Sun and Venus
measure Venus-Earth distance using radar
measure angular distance between Sun and Venus in 1st quarter phase
use trigonometry to derive Earth-Sun distance
Now you know how far Earth travels in year – baseline distance
February 14, 2006
Astronomy 2010

8. Parallax  Distance measure angular shift p
know baseline distance (1 AU)
trigonometry  star distance d
February 14, 2006
Astronomy 2010

9. Parsecs
Distances to the stars in units of astronomical units are huge, a more convenient unit of distance called a parsec is used
abbreviated “pc”.
parsec = distance of a star that has a parallax of one arc second using a baseline of 1 astronomical unit.
1 parsec = 206,265 AU = 3.26LY.
Nearest star is ~1.3 parsecs from the Sun.
February 14, 2006
Astronomy 2010

10. Trigonometry Use basic trigonometric relations.
Used by modern surveyors to measure great distances (also called surveyor's method).
d : distance
b : baseline
p : angle b p d
February 14, 2006
Astronomy 2010

11. Parallax at Large Distances (but not too large)
For Earth-based measurements one can write:
d = (1AU) / tan(p),
Where angle p is the parallax measured in arc seconds
And d is the distance in parsecs.
The farther away the object is, the less it appears to shift.
Since the shifts of the stars are so small, arc seconds are used as the unit of the parallax angle.
3,600 arc seconds in just one degree.
The ball in the tip of a ballpoint pen viewed from across the length of a football field is about 1 arc second.
February 14, 2006
Astronomy 2010

12. More parsecs Conversion of parsecs to LY
1 parsec = 3.26 light years.
Which unit to use to specify distances: a light year or a parsec?
Both are fine and are used by astronomers.
Using a parsec for the distance unit and an arc second for the angle, we can express the relation between distance and parallax in the simple form:
p = 1/d and d=1/p
February 14, 2006
Astronomy 2010

13. What about more distant stars?
parallax fails for stars > 1000 LY away
baseline of 1 AU is too small
Variable Stars: Cepheids and RR Lyrae
The luminosity of these stars can be determined by measuring the time it takes them to vary in brightness.
Apparent brightness and luminosity tell us the distance.
Outline
What are Cepheid Variable Stars?
Why do they vary?
How is their variation related to luminosity.
February 14, 2006
Astronomy 2010

14. Cepheid Variables large yellow pulsating stars first: Delta Cephei
Discovered by John Goodricke in 1784
magnitude changes over 5.4 day cycle
hundreds known
periods range from 3 to 50 days
average luminosities are 1,000 to 10,000 LSun
February 14, 2006
Astronomy 2010

15. Cepheid Variable Stars
luminosity
time
Polaris, the North Star, is a Cepheid Variable
variation of 10% of magnitude (10% of luminosity)
period of 4 days
pulsation decreases over time
Cepheid variable stars are in a flickering phase of life
February 14, 2006
Astronomy 2010

16. Why Cepheid Variables Vary
pulsations:
changes in color and spectral class  temperature varies
doppler shift of spectra  size varies
luminosity changes when temperature and area change
cloud
pressure from hot gas
weight from gravity
normal stars: balance of pressure and gravity
variable stars: pressure and gravity out of synch
February 14, 2006
Astronomy 2010

17. Period – Luminosity Relationship
Henrietta Levitt (1908): systematic search found many Cepheid variables including hundreds in the Magellanic Clouds
The Magellanic Clouds are nearby “dwarf” galaxies
All stars in the Magellanic Clouds are roughly same distance away -- like observing the Moon from Earth
found: brighter Cepheids have longer periods
Calibrate distance scale: nearby Cepheid Variables within parallax distance
February 14, 2006
Astronomy 2010

18. 150 Million Light Years away
February 14, 2006
Astronomy 2010

19. February 14, 2006
Astronomy 2010

20. Distance from Spectral Types
close star (within our galaxy) – parallax
variable star – if you find one
alternative: spectral class + HR diagram
spectrum  temperature
spectral lines  broad classes
supergiants
bright giants
giants
subgiants
main sequence
HR diagram  luminosity
luminosity  distance
February 14, 2006
Astronomy 2010

21. Summary Determine the metre
Use the metre to determine the astronomical unit (AU)
Use the AU and stellar parallax to measure stars out to about 300 LY with satellite measurements, like Hipparcos
Use the period-luminosity relationship for variable stars to measure distances out to 100million LY. Calibrate with nearby variables. Often the distance measured is to a cluster of stars or another galaxy.
February 14, 2006
Astronomy 2010

22. Summary (cont’d)
For distant stars that are not variable and don’t have a nearby variable star, use the temperature - luminosity relation of the H-R diagram. Does require some work to determine if the star is main sequence, dwarf, or giant.
Later we will see the use of red shift and supernovae to measure the largest distances.
February 14, 2006
Astronomy 2010

23. Discussion Question
How would you explain how far away even the nearest star is to your Mother/Father/Sister/Brother?
February 14, 2006
Astronomy 2010