Sirius
Sun
Spectral Classification of Stars
Tuesday, February 21, 2012
Spectral Lines
NaHH
HCa
Fe
StellarClassification
Tuesday, February 21, 2012
Spectral Classification of Stars
Edward C. Pickering (1846-1919) and Williamina P. Fleming (1857-1911) label spectra alphabetically according to strength
of Hydrogen (Balmer) lines, beginning with “A” (strongest).
Timeline:
1890s
1890s Antonia Maury (1866-1952) developed a classification scheme based on the “width” of spectral lines. Would place “B” stars before “A” stars.
1901 Annie Cannon (1863-1941), brilliantly combined the above. Rearranged sequence, O before B before A, added decimal
divisions (A0...A9) and consolidated classes. Led to classification scheme still used by astronomers today!
OBAFGKM (Oh Be A Fine Guy/Girl, Kiss Me)
“Early Type” Stars
“Late Type” Stars
Tuesday, February 21, 2012
Spectral Classification of StarsTimeline:
1901 Annie Cannon (1863-1941), brilliantly combined the above. Rearranged sequence, O before B before A, added decimal
divisions (A0...A9) and consolidated classes. Led to classification scheme still used by astronomers today!
OBAFGKM (Oh Be A Fine Guy/Girl, Kiss Me)
“Early Type” Stars : Stars near the beginning of Sequence
“Late Type” Stars : Stars near the end of the Sequence.
One can mix the definitions: K0 star is an “early-type” K star. B9 is a “late-type” B star.
Annie Cannon classified 200,000 spectra, listed in the Henry Draper Catalog. Catalog ID’s are “HD 39801” (ID for Betelgeuse in the constellation Orion).1911-1914
During 1990s Two new letters added to Sequence for very cool, Brown-Dwarf stars. “L” spectral types (T=1300-2500 K) and “T” types (T < 1300 K).
OBAFGKMLT (Oh Be A Fine Guy/Girl, Kiss Me - Less Talk !)
Tuesday, February 21, 2012
Spectral Classification of Stars
Spectral Type Characteristics
O Hottest blue-white stars, few lines. Strong He II (He+) absorption lines. He I (neutral helium) stronger).
B Hot blue-white. He I (neutral Helium), strongest at B2. H I (neutral Hydrogen) stronger.
A White stars. Balmer absorption lines strongest at A0 (Vega), weaker in later-type A stars. Strong Ca II (Ca+) lines.
F Yellow-white stars. Ca II lines strengthen to later types. F-stars. Balmer lines strengthen to earlier type F-stars.
G Yellow stars (Sun is a G5 star). Ca II lines become stronger. Fe I (neutral iron) lines become strong.
K Cool orange stars. Ca II (H and K) lines strongest at K0, becoming weaker in later stars. Spectra dominated by metal absorption lines.
M Cool red stars. Spectra dominated by molecular absorption bands, e.g., TiO (titanium oxide). Neutral metal lines strong.
LVery cool, dark red (brown dwarfs). Brighter in Infrared than
visible. Strong molecular absorption bands, e.g., CrH, FeH, water, CO. TiO weakening.
T Coolest stars. Strong methane (CH4), weakening CO bands.
Hotter
Cooler
Tuesday, February 21, 2012
Spectral Classification of Stars
Tuesday, February 21, 2012
Spectral Classification of Stars
Tuesday, February 21, 2012
Spectral Classification of Stars
Tuesday, February 21, 2012
Spectral Classification of Stars
Tuesday, February 21, 2012
Spectral Classification of Stars
Tuesday, February 21, 2012
Spectral Lines
NaHH
HCa
Fe
StellarClassification
Tuesday, February 21, 2012
Spectral Classification of StarsPhysical Description
Hydrogen when T < 9900 KMajority of electrons in
ground state, n=1Hydrogen when T = 9900 K
Majority of electrons in first excited, n=2 state, and capable of producing Balmer lines
Hydrogen when T > 9900 KMajority of electrons unbound,
ionized hydrogen.
Tuesday, February 21, 2012
Most Abundant Elements in the Solar Photosphere.
Spectral Classification of StarsPhysical Description
Stars are not composed of pure hydrogen, but nearly all atoms (mostly H, He, and metals =
anything not H or He).
Typically 1 He atom for every 10 H atoms (and even fewer metals).
Helium (and metals) provide more electrons, which can recombine with ionized H.
So, it takes higher temperatures to achieve same degree of H ionization when He and
metals are present.
Element Atomic # Log Relative Abundance
H 1 12.00
He 2 10.93 ± 0.004
O 8 8.83 ± 0.06
C 6 8.52 ± 0.06
Ne 10 8.08 ± 0.06
N 7 7.92 ± 0.06
Mg 12 7.58 ± 0.05
Si 14 7.55 ± 0.05
Fe 26 7.50 ± 0.05
S 16 7.33 ± 0.11
Al 13 6.47 ± 0.07
Ar 18 6.40 ± 0.06
Ca 20 6.36 ± 0.02
Na 11 6.33 ± 0.03
Ni 28 6.25 ± 0.04
Abundance is = log10(Nelement/NH) + 12.I.e., Abudance of Oxygen = 8.83, which means:
8.83 = log10(NO/NH) + 12NO/NH = 108.83 - 12 = 0.000676 ≈1/1480
There is one Oxygen atom for every 1480 H atoms !
Tuesday, February 21, 2012
Spectral Classification of StarsPhysical Description
In 1925, Cecilia Payne (1900-1979) calculate the relative abundances of 18 elements in stellar atmospheres (one of the most brilliant PhD theses ever in astronomy).
Tuesday, February 21, 2012
Spectral Classification of Stars
How would you measure a star’s mass ?
Hertzsprung-Russell Diagram
Tuesday, February 21, 2012
Spectral Classification of Stars
How would you measure a star’s mass ?
+
Answer: Kepler’s Laws. Works well for binary stars.
=
r1
r2
m1
m2
m1r1 + m2r2R = m1 + m2= 0
m1
m2
r2
r1
a2
a1= =
Hertzsprung-Russell Diagram
Tuesday, February 21, 2012
Animations of binary Stars:
http://astro.ph.unimelb.edu.au/software/binary/binary.htm
http://abyss.uoregon.edu/~js/applets/eclipse/eclipse.htm
Tuesday, February 21, 2012
Binary Stars
Term binary was first used by Sir Williams Herschel in 1802.
"If, on the contrary, two stars should really be situated very near each other, and at the same time so far insulated as not to be materially affected by the attractions of neighbouring stars, they will then compose a separate system, and remain united by the bond of their own mutual gravitation towards each other. This should be called a real double star; and any two stars that are thus mutually connected, form the binary sidereal system which we are now to consider."
Tuesday, February 21, 2012
Binary Stars
Two Stars in Albireo system.
Tuesday, February 21, 2012
Binary Stars
Sirius Abrightest star in the sky
m = -1.46.
Sirius Bm = 8.30
In 1844, Friedrich Bessel deduced it was a binary.
In 1862 Alvan Graham Clark discovered the companion.
Tuesday, February 21, 2012
Spectral Classification of Stars
How would you measure a star’s mass ?
To Earth
Orbital Plane
Plane of Sky
m1
m2
v2
v1
=
For circular orbits, v1 = 2πa1/P
Determine radial component of velocities, vr, using doppler-shifted spectral lines.
v1r=v1 sin(i) & v2r=v2 sin(i)
m1
m2
m1
m2
v2r / sin(i)
v1r / sin(i)=
v2r
v1r
=
Therefore, we can determine the mass ratio without knowing the angle of inclination !
angle of inclination
Hertzsprung-Russell Diagram
Tuesday, February 21, 2012
Spectral Classification of Stars
How would you measure a star’s mass ?
Need one other equation to relate m1 and m2. Comes from Kepler’s 3rd law, replace a = a1 + a2
a = a1 + a2 = (P/2π) v1 + (P/2π)v2 = (P/2π) (v1+v2)
Kepler’s 3rd law, (P2 = 4π2 a3 / GM ), becomes
m1 + m2 = (P/2πG) (v1+v2)3
Substituting v1 = v1r /sin(i), the angle of inclination.
m1 + m2 = (P/2πG) (v1r+v2r)3
sin3(i)
Hertzsprung-Russell Diagram
Tuesday, February 21, 2012
Spectral Classification of Stars
How would you measure a star’s mass ?
m1 + m2 = (P/2πG) (v1r+v2r)3
sin3(i)
m1
m2
v2r / sin(i)
v1r / sin(i)=
v2r
v1r
=
Combine our two formula:
To get (rearranging terms):
m23
(m1 + m2)2sin3(i)
Pv1r3=
2πG
This is the mass function, depends only on the period, P, and radial velocity, v1r. In practice, only a spectrum for one star in binary pair is
available. Mass function sets a lower limit on m2. In rare cases of eclipsing spectroscopic binaries, i ≈90o and both masses can be measured directly.
Hertzsprung-Russell Diagram
Tuesday, February 21, 2012
Eclipsing Binaries:
http://www.astro.cornell.edu/academics/courses/astro101/herter/java/eclipse/eclipse.htm
Tuesday, February 21, 2012
Spectral Classification of StarsMass-Luminosity relation
Tuesday, February 21, 2012
Spectral Classification of Stars
Ejnar Hertzsprung Henry Norris Russell
This is the Hertzprung-Russell (HR) diagram, which is a stellar classification system developed by Ejnar Hertzprung and Henry Norris Russel in Denmark around 1910.
The HR diagram relates the magnitudes and colors of stars as a function of their temperature and luminosity.
Hertzsprung-Russell Diagram
Tuesday, February 21, 2012
Henry Norris Russell’s first diagram
Tuesday, February 21, 2012
Spectral Classification of StarsEnormous Range in Stellar Radii !
If stars cool over time as they contract, there should be a relation between their temperatures and luminosities.
R = L1
T2 4πσ√Hertzsprung (1873-1967) found that stars of Late type (G and later) have a large range in luminosity. If two stars of the same spectral type (same Temperature)
then more luminous star is larger.
Giants: Stars with big radii & Dwarfs: Stars with small radii. Our Sun is a G0 dwarf.
Similar Conclusions reached by Henry Russell (1877-1957)
Tuesday, February 21, 2012
Spectral Classification of StarsHertzsprung-Russell Diagram
Tuesday, February 21, 2012
Spectral Classification of StarsHertzsprung-Russell Diagram
Tuesday, February 21, 2012
Lum
inos
ity
Temperature: Hotter
Brighter
TextHR diagram where data points
show measurements from 22,000 real stars from the
Hipparcos satellite.
30,000 K 10,000 K 7500 K 6000 K 5000 K 4000 K 3000 K
(Lines are Theoretical, expected luminosities and
temperatures of stars)
Color Index: B-V
Tuesday, February 21, 2012
Abs
olut
e M
agni
tude
(M
)(L
umin
osity
)
Temperature (Color, B-V)Hotter
Brighter HR diagram
Spectral Type
Tuesday, February 21, 2012