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Cosmic Distance Ladder

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Title: Cosmic Distance Ladder


1
Cosmic Distance Ladder
  • Whats Up There in the Universe

2
Measuring the Distances
  • There is no one single method that works in all
    distance scales.
  • Measuring the distance is a hard problem in
    astronomy.
  • Infact there is succession of methods whose
    domain of validities overlap.
  • Each rung of the ladder provides information that
    can be used to determine the distances at the
    next higher rung.
  • We need to calibrate each method in the domain of
    overlap.

3
Distances of Planets
  • Keplers third law give only the ratios of the
    distances
  • Although by the 17th century astronomers could
    calculate each planet's relative distance from
    the Sun in terms of the distance of the Earth
    from the Sun, an accurate absolute value of this
    distance had not been calculated.

P2ka3
4
Astronomical Unit
  • Astronomical Unit (AU) Average distance between
    the Earth and the Sun.
  • Appropriate unit for giving distances in the
    Solar System.
  • No constant of proportionality if P is measured
    in years and a is measured in AU.

P2a3
5
Conjunction
Conjunction two celestial bodies appear near one
another in the sky. Mostly one of the objects is
the Sun and the other is one of the planets
6
2004 Transit of Venus
  • The duration of such transits is usually measured
    in hours (the transit of 2004 lasted six hours).
  • occur in a pattern that repeats every 243 years,
    with pairs of transits eight years apart
    separated by long gaps of 121.5 years and 105.5
    years.

7
Transit of Venus
  • It does not occur very often because the plane of
    the orbit of the Earth is tilted by 3.4.

8
Three consecutive days of close conjunction
between the Moon and Venus.
9
Solar Paralax by Venus Transit
  • The technique is to make precise observations of
    the slight difference in the time of either the
    start or the end of the transit from widely
    separated points on the Earth's surface.
  • The distance between the points on the Earth can
    then be used as to calculate the distance to
    Venus and the Sun.

Measuring Venus transit times to determine solar
parallax
10
AU
  • The astronomical unit is precisely determined
    with the transit method.
  • Also by radar ranging.
  • 1AU150 Million km1.5?1013 cm
  • The Earth is actually 147 104 753 km away from
    the Sun on the 29th of December and 152 091 803
    km away from the Sun on the 30th of June.
  • The currently accepted value of the AU is 149 597
    870 691 ? 30 metres.

11
Distances of planets
  • Once 1AU is determined, the distances of all
    planets can be found from Keplers third law.
  • Actually not a law, an emprical relation that has
    to be explained by the underlying physics.

12
Distances of Stars
  • How do we know the distances of stars?
  • Parallax!

13
Stellar Parallax
  • Different orbital positions of the Earth causes
    nearby stars to appear to move relative to the
    more distant stars.
  • The annual parallax is defined as the difference
    in position of a star as seen from the Earth and
    Sun, i.e. the angle subtended at a star by the
    mean radius of the Earth's orbit around the Sun.

14
Parallax and distance
  • Only direct measure of distance astronomers have
    for objects beyond solar system is parallax
  • Parallax apparent motion of nearby stars against
    background of very distant stars as Earth orbits
    the Sun
  • Requires images of the same star at two different
    times of year separated by 6 months

15
Parallax as a Measure of Distance
P
Background star
Image from A
Image from B 6 months later
  • P is the parallax
  • typically measured in arcseconds
  • Gives measure of distance from Earth to nearby
    star (distant stars assumed to be an infinite
    distance away)

16
Parsec
  • The parsec is the distance for which the annual
    parallax is 1 arcsecond.
  • A parsec equals 3.26 light years.
  • Distance (in parsecs) is simply the reciprocal of
    the parallax angle (in arcseconds) d1/p

17
Examples
  • Parallax angle 0.5 arcsecondgtd2 pc
  • Proxima Centauri has a parallax of 0.771
    arcsecond. This implies that its distance is d
    1.295 pc.

18
Example
  • The Sun has a parallax of 90 degrees.
  • Why?

19
Bessel (1838)
  • Successfully measured the parallax of the star 61
    Cygni.
  • This was considered as the conclusive evidence
    that the Earth is in motion.

20
Astronomical Angular Yardsticks
  • Easy yardstick your hand held at arms length
  • fist subtends angle of ? 5
  • spread between extended index finger and thumb ?
    15
  • Easy yardstick the Moon
  • diameter of disk of Moon AND of Sun ? 0.5 ½
  • ½ ? ½ 1/60 radian ? 1/100 radian ? 30 arcmin
    1800 arcsec

21
Distance Units
  • Light Year (ly) the distance light can travel in
    one year
  • 1 ly 9.46E17 cm6.324X104 AU
  • Parsec (pc) 3.26 ly 3.08X1018 cm
  • Astronomical Unit (AU) 149.6E13 cm

22
Limits of Parallax Method
  • Refraction caused by the atmosphere limits the
    accuracy to 0.01 arcseconds.
  • d1/p??d?p/p2
  • Reliable measurements, those with errors of 10
    or less, can only be achieved at stellar
    distances of no more than about 100 pc.
  • Space-based telescopes are not limited by this
    effect and can accurately measure distances to
    objects beyond the limit of ground-based
    observations.
  • E.g. Hipparcos 0.001 arcseconds

23
Size of the Milky Way
24
Question
  • 100 pc is a small fraction of the size of the
    Galaxy (diameter 100.000 light years.)
  • We can only measure the distances of a small
    fraction of stars in our galaxy with the paralax
    method.
  • How do we know the distances of galaxies,
    clusters of galaxies etc if the parallax method
    does not work?

25
Great Debate (1920)
  • Is the Galaxy the whole Universe?
  • Are the spiral nebulae other galaxies or are
    they just gas clouds in the Galaxy?
  • A universe of stars or a universe of galaxies?
  • Great Debate between Heber D. Curtis and Harlow
    Shapley.
  • Even Einsteins Universe (1916) was a universe of
    stars.

26
Standard Candles
  • A standard candle is an astronomical object that
    has a known luminosity.
  • Luminositypower (measured in Watts)
  • Or rather ergs/s (cgs system prefered in
    astronomy).
  • Flux Luminosity/4?d2
  • Measure the flux received on Earth and calculate
    the distance.

27
Woman Computers
A group of women computers a the Harvard
College Observatory circa 1890, directed by Mrs.
Williamina Fleming (standing). Photo credit The
Harvard College Observatory
28
Cepheid Variables A Standard Candle
  • A cepheid variable is a young star of several
    solar masses and roughly 104L? whose luminosity
    changes periodically.
  • The period of a Cepheid variable is related to
    its luminosity.
  • Measuring the period of light fluctuations (easy)
    allows the object's absolute luminosity to be
    determined.

29
Cepheids as Variable Stars
Modern calibration of the Cepheid P-L relation in
the Magellanic clouds, yields
here the period P is measured in days, and the
magnitude is measured in the I band.
30
Henrietta Leavitt
  • One of the woman computers at Harvard
    Observatory.
  • Established the period-luminosity relation for
    variable stars.
  • Along with Annie Jump Cannon and Cecilia
    Payne-Gaposchkin, Leavitt represents an early
    generation of female astronomers who, serving as
    astronomical computers doing meticulous and
    demanding work around the turn of the 20th
    Century, received little credit for their
    contributions until much later.

31
Through painstaking comparison of numerous
photographic plates of the Magellanic Clouds, she
identified thousands of variable stars.
Photo Caption Henrietta Leavitt at
her desk. Photo credit The Harvard
College Observatory.
32
Great Debate Solved (1924)
  • Edwin Hubble determined a Cepheid Variable in
    Andromeda Galaxy.
  • Used Leavitts method to find the distance.
  • Conclusion Andromeda is much distant than the
    estimated size of our galaxy!

33
Summary of Distance Ladder
Note that beyond the Virgo cluster, even very
bright stars like Cepheids become unresolved and
we see only the integrated light from galaxies.
Further away than this, we must determine
distances using the redshift of galaxies.
34
Some Elements of the Universe
35
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36
Open Clusters
  • Few thousand stars formed at the same time
  • Gravitationally loosely bound
  • Usually less than a few hundred million years old

Pleiades Open Cluster
37
The Solar Neighborhood
The 30 closest stars to the Sun
38
Globular Clusters
  • Spherical collection of stars
  • Strongly bound by gravity
  • Orbits the galactic core
  • 150 currently known globular clusters in the
    Milky Way, with perhaps 1020 more undiscovered
  • Concentrated in the halo of the galaxy
  • Old stars

39
Milky Way
Our galaxy
40
Our Position in the Milky Way
41
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42
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43
Andromeda GalaxyOur Neighbour
2.5 million light-years away
44
Local Group
Galaxies do not stand alone. They are in groups
A few million lightyears.
45
Abell
46
Super-Clusters
Part of the Virgo super-cluster. Some 60 million
lightyears.
  • Local group is a member of a supercluster called
    Virgo
  • So galaxy clusters form superclusters.

47
Large Scale Structure
  • Large scale structure is made up of
    superclusters.
  • Each dot represents a supercluster.
  • Superclusters form filaments and walls around
    voids.

Billions of lightyears.
48
Age of the Universe
The universe is about 13.7 Billion years old.
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