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The Magnitude Scale Measuring the brightness of astronomical objects • While cataloging stars in the sky, the Greek Astronomer Hipparchus developed the “magnitude” system, which is still used by astronomers today. • Hipparchus gave the brightest stars an apparent magnitude, m = 1 and the faintest stars, m = 6. Note that fainter stars have higher magnitude values Classify brightness of stars by using magnitudes Orion Constellation Classify brightness of stars by using magnitudes Betelgeuse (α Ori) m=0.45 δ Ori m=2.40 ζ Ori m=1.85 ο Ori m=4.70 η Ori m=3.35 Orion Constellation κ Ori m=2.05 Rigel (β Ori) m=0.15 The Magnitude Scale Measuring the brightness of astronomical objects “Brightness” of an object is measured in terms of its radiant flux, F, received from the object. F is the total amount of light energy of all wavelengths that crosses a unit area. Flux is the number of Joules of light energy per second per one square meter. Flux has units of Watts / meter2. The measured flux depends on the intrinsic Luminosity, L and its distance from the observer. Luminosity has units of Watts (Energy per second). Same object located farther from the Earth, would appear less bright - it would have lower flux The Magnitude Scale Measuring the brightness of astronomical objects R L Mathematically, consider a star of instrinsic Luminosity, L, surrounded by a spherical shell of radius, R. Area of Sphere = 4πR2. The Flux = F = L / (4πR2). The Magnitude Scale Measuring the brightness of astronomical objects Example : Luminosity of the Sun is L⊙ = 3.839 x 1026 W. What is the flux of the Sun at a distance of 1 AU = 1.496 x 1011 m ? F = L / (4πR2) = 1365 W m-2 This value is defined as the solar irradiance (also called “solar constant”, S on the inside cover of your book). What is the flux of the Sun at a distance of 10 parcsecs = 2.063 x 106 AU ? F1 / F2 = (R2 / R1)2 = (2.063 x 106 AU / 1 AU )2 = 4.3 billion times lower than solar irradiance ! The Magnitude Scale Measuring the brightness of astronomical objects • Present-day magnitude scale is defined such that the 1 magnitude corresponds to a change in flux by a factor of 2.512. mA - mB = -2.5 x log10( FA / FB ) • If FA = FB x 2.512, then -2.5 x log10 (FA / FB ) = -2.5 x log10 (2.512) =-2.5 x (0.4) = -1 mag. • Thus, mA - mB = -1 mag. Star A is 1 magnitude brighter than Star B. (Star B is 1 mag fainter than Star A). The Magnitude Scale Measuring the brightness of astronomical objects • In addition, present-day magnitude scale is defined such that the star Vega has a magnitude of 0 (by definition). mA - mB = -2.5 x log10( FA / FB ) • If FA = FB x 2.512, then -2.5 x log10 (FA / FB ) = -2.5 x log10 (2.512) =-2.5 x (0.4) = -1 mag. • Thus, mA - mB = -1 mag. Star A is 1 magnitude brighter than Star B. (Star B is 1 mag fainter than Star A). The Magnitude Scale Measuring the brightness of astronomical objects • Present-day magnitude scale is defined such that one magnitude corresponds to a change in flux by a factor of 2.512. mA - mB = -2.5 x log10( FA / FB ) • m⊙ = -26.83 mag for the Sun (denoted by Greek symbol ⊙). The faintest galaxies yet observed have mg = 30 mag (observed by the Hubble Space Telescope). This corresponds to a flux ratio of m⊙ - mg = -2.5 x log10( F⊙/Fg ) F⊙ / Fg = 10-0.4 x (m⊙ - mg) = 10-0.4 x (-26.83 - 30) = 6 x 1022 The Magnitude Scale Measuring the brightness of astronomical objects Absolute Magnitude, M, is the magnitude of a an object if it were placed at a distance of 10 parsecs (definition). 10+0.4(m - M) = (F10 / F) = (d / 10 pc)2 Solving for d: (d / 10 pc) = 100.2(m-M) m - M = 5 log10(d / 10 pc) or m - M = 5 log10(d) - 5, for d in units of parsec m-M is defined as the Distance Modulus. The Magnitude Scale Measuring the brightness of astronomical objects Absolute Magnitude, M, is the magnitude of a an object if it were placed at a distance of 10 parsecs (definition). It is intrinsic to an object and never changes. (Like an object’s Luminosity.) Apparent Magnitude, m, is the magnitude of an object as it appears to be. It depends on how far away the object is from the observer. (Like an object’s Flux.) They are related by the Distance Modulus, DM = m - M. The Magnitude Scale Measuring the brightness of astronomical objects Example: What is the absolute magnitude of the Sun ? Msun = msun - 5 log10(d / 10 pc) msun = -26.83 and d=1 AU = 4.85 x 10-6 pc. Msun = +4.74 The distance modulus is: msun - Msun = -31.57 The Magnitude Scale Measuring the brightness of astronomical objects Example: What are the absolute magnitude and distance modulus of the Vega ? MVega = mVega - 5 log10( d / 10 pc ) mVega = 0. and dVega = 7.75 pc. MVega = +0.55 The distance modulus is: mVega - MVega = -0.55. The Magnitude Scale Measuring the brightness of astronomical objects Compare the flux and luminosity of the Sun and Vega. msun - mvega = -2.5 log10( Fsun / FVega ) Fsun / FVega = 10-0.4(msun-mvega) = 10-0.4(-26.83 - 0) = 54 billion ! Lsun / LVega = Fsun (dsun)2 / FVega (dVega)2 = 0.021 The Sun appears to be more than 50 billion times brighter than Vega, but the Sun has only 2.1% of the Luminosity of Vega. Distance matters ! Classify brightness of stars by using magnitudes Orion Constellation Classify brightness of stars by using magnitudes Betelgeuse (α Ori) m=0.45 δ Ori m=2.40 ο Ori m=4.70 ζ Ori m=1.85 η Ori m=3.35 Orion Constellation κ Ori m=2.05 m=6.20 Rigel (β Ori) m=0.15 Make Observations (take data) Ask Questions Scientific Process Results of new Experiments does not support hypothesis. Revise hypothesis or choose new one. Suggest Hypothesis Make Predictions Make new Test supports hypothesis, make Experiments additional predictions and test them too. Repeat ad nausem. to Test Predictions From Malcolm Gladwell’s, Outliers The Color Index The apparent and absolute magnitudes covered so far are bolometric magnitudes (bolometric comes from the word bolometer which is an instrument that measures the increase in temperature in the flux it receives at all wavelengths). In practice, detectors measure an object’s flux within a certain wavelength region defined by the sensitivity of the detector. Astronomers use measurements of an object’s flux within two (or more) different filters to measure an object’s Color Index. Blue = 329 nm Green = 656 nm Red = 673 nm % Transmittance U B V R I Wavelength (nm) The color of an object can be measured precisely by using filters that measure the relative flux of the object within narrow wavelength ranges. Some astronomical filters are: U : ultraviolet, filter centered at 365 nm B : blue, filter centered at 440 nm V : visual, filter centered at 550 nm R : red, filter centered at 630 nm I : infrared, filter centered at 900 nm For more examples of images from many-colored filters, see: http://hubblesite.org/gallery/behind_the_pictures/ meaning_of_color/toolbox.php The Color Index The Color index is defined as the difference between the magnitude of an object measured in two different colors: Definitions: U, B, V (other capital letters) refer to the apparent magnitude measured in that filter. MU, MB, MV refer to the absolute magnitude measured in that filter. The Color Index The Color index is defined as the difference between the magnitude of an object measured in two different colors: U - B is the color index between ultraviolet and blue light. B - V is the color index between blue and visual light. Note that U - B = MU - MB and B - V = MB - MV Because magnitudes decrease with increasing flux, an object with smaller color index said to be bluer than an object with higher color index. Example: U - B = -2.5 log10 [ F(365nm) / F(440nm) ] F(365) / F(440) = 10-0.4(U-B) As U - B gets smaller, 10-0.4(U-B) gets bigger, and the flux at 365nm gets larger than the flux at 440 nm. The Color Index The relation between apparent magnitude and flux are related by: U = -2.5 x log10( ∫Fλ x SU(λ) dλ ) + CU Where the integral is over all wavelengths. The Sensitivity Function, SU, is the fraction of the objects flux that is detected as a function of wavelength in the U filter (each filter has a sensitivity function), like those shown here: Log Flux per nm T = 30,000 K T = 10,000 K U filter B filter V filter 6,000 K 3,000 K 100 1000 K 1000 Wavelength [nm] 10,000 Objects with different blackbody temperatures have different amounts of light measured in the UBV filters. (Measuring the relative amount of light at even shorter or longer wavelengths would give us even more information !) Log Flux per nm T = 30,000 K T = 10,000 K U filter B filter V filter 6,000 K 3,000 K 100 1000 K 1000 Wavelength [nm] 10,000 We calculate the amount of light in a filter by integrating the filter and the object’s spectrum, e.g., for the U-filter: U = -2.5 x log10( ∫Fλ x SU(λ) dλ ) + CU Where Fλ is the Flux per nm of the object, SU is the filter’s Sensitivity function and CU is a constant. The Color Index A very hot star has a surface temperature of 42,000 K and a less hot star has a surface temperature of 10,000 K. Estimate their B-V colors (given that CB - CV = CB-V = 0.65): B = -2.5 x log10( ∫Fλ x SB(λ) dλ ) + CB V = -2.5 x log10( ∫Fλ x SV(λ) dλ ) + CV Approximate that (where Bλ(T) is the Planck function at wavelength λ and temperature T) ∫Fλ x SB(λ) dλ = B440(T) ΔλB and ∫Fλ x SV(λ) dλ = B550(T) ΔλV where ΔλB = 98 nm and ΔλV = 89 nm (approximate as square filters) The Color Index B - V = -2.5 x log10( B440(T) ΔλB / B550(T) ΔλV ) + CB-V B440(T) / B550(T) = (550/440)5 x [ (ehc/(550nm)kT - 1) / (ehc/(450nm)kT - 1) ] hc/k =(6.626 x 10-34 J s) x (2.998 x 108 m / s) / (1.38x10-23 J / K) = 0.0144 [m * K] ∴ B440(42000K) / B550(42000K) = (3.05)x[ 0.865 / 1.180 ] = 2.236 B440(10000K) / B550(10000K) = (3.05) x [ 12.71 / 25.38 ] = 1.527 42,000K => B - V = -2.5 x log10(2.236 x 98nm/89nm) + CB-V = -0.33 10,000K => B - V = -2.5 x log10(1.527 x 98nm/89nm) + CB-V = 0.09 Stars with higher temperatures have lower color index (bluer colors) Stars with lower temperatures have higher color indexes (redder colors) The Color Index Color is related to temperature Betelgeuse (α Ori) m=0.45 T = 3600 K Appears Redder Recall relation of Flux per unit wavelength for blackbody radiation. Rigel (β Ori) m=0.15 T = 13,000 K Appears Bluer Orion Constellation The Color Index The Bolometric Correction is defined as the difference between an object’s bolometric magnitude (the magnitude corresponding to the flux over all wavelengths) and its visual (V) magnitude. BC = mbol - V = Mbol - MV where mbol = -2.5 x log10( ∫Fλ dλ ) + Cbol Note that there is no sensitivity function (like for the magnitude measured in each color filter). For the bolometric magnitude, the integral is over all wavelengths ! Combine Luminosity and Color information for Stars Recall that the luminosity has a strong temperature (T) dependence L = 4πR2 σT4 Now we know that for objects that emit like blackbodies, their color has a temperature dependence. This is similar to Wein’s Law: λmax = C / T (C is a constant) This means that stars (which emit like blackbodies) can be classified on a Luminosity - Temperature plot. Combine Luminosity and Color information for Stars 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. Ejnar Hertzsprung Henry Norris Russell The HR diagram relates the magnitudes and colors of stars as a function of their temperature. We will return to this later this semester. Absolute Magnitude (M) (Luminosity) Brighter Hotter Theoretical HR diagram Temperature (Color, B-V) Absolute Magnitude (M) (Log Luminosity) Brighter 30,000 K 7500 K Text 5000 K 4000 K 3000 K (Lines are Theoretical, expected luminosities and temperatures of stars) HR diagram where data points show measurements from 22,000 real stars from the Hipparcos satellite. Hotter Log Temperature (Color, B-V)