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1B11 Foundations of Astronomy Star names and magnitudes Liz Puchnarewicz [email protected] www.ucl.ac.uk/webct www.mssl.ucl.ac.uk/ 1B11 Our night sky Our Sun is one of approximately 200 billion stars in our Galaxy, the Milky Way. It lies in one of the spiral arms, about two-thirds of the way out from the centre, which is called Sagittarius A* On a clear dark night in the UK, we can see ~3000 distinct stars, plus the fuzzy glow from the plane of the Milky Way. From the very earliest times, humans have grouped patterns of stars into constellations, often animals and characters from myths and legends. There are now 88 official constellations. 1B11 Star positions The most important parameter you can know about any astronomical source is its position on the sky. Why? 1. Isolate, identify and re-visit the source 2. Check for transient sources, supernovae etc. 3. Associate sources at different wavelengths By grouping stars into constellations, our ancestors developed the first system for unambiguously identifying celestial sources. Now, we use co-ordinate systems based on angular distance scales. Astronomical co-ordinates 1B11 Constellation names Constellations, their names and boundaries were defined by the International Astronomical Union (IAC) in 1930. The brightest stars have their own names, eg Orion, Vega, Aldebaran, Polaris, Betelgeuse. Many “naked-eye” objects are identified by their constellation name abbreviated to an IAU 3-letter standard, followed by a letter from the Greek alphabet in order of decreasing brightness (eg, Sirius,the brightest star in Canis Majoris, is also known as aCMa). This was devised by Bayer in 1603. If there are more than 24 stars in a constellation, then the remainder are numbered in order of Right Ascension (Flamsteed, 1925). 1B11 Faint stars and catalogues Fainter stars Some stars which are too faint to be seen with the naked eye are identified by a catalogue number, eg HD = “Harvard Revised” HR = “Henry Draper” eg Sirius = aCMa = HR2491 = HD48915 These catalogues give information on the position, colour, brightness and type of stars. There are now many, many different types of astronomical catalogue. VizieR is a web service run by the CDS which is effectively a catalogue of catalogues. 1B11 Multiple and variable stars Multiple stars Most stars in the Galaxy (at least a half) are in binary and multiple systems. In these cases, components are labelled A, B, C…. etc. in order of decreasing brightness. Eg. 61Cyg is a double star – the brighter component is 61CygA, the fainter one is 61CygB. Variable stars Many stars are variable, which complicates labelling based on brightness! If they have a Bayer designation (eg dCep), they keep these. Otherwise, their constellation name is prefixed by one or two letters, depending on the time of discovery. 334 combinations of letters are available – after that they are prefixed by Vnnn where nnn is >334. 1B11 Nebulae and galaxies Non-stellar objects In the late 18th Century, Charles Messier compiled a list of about 100 diffuse objects, to distinguish these from comets. This has become known as a collection of beautiful deep sky objects, including galaxies, nebulae and clusters of stars. All 110 Messier objects can be seen at the SEDS Messier Database. Another catalogue of fuzzy objects, the New General Catalogue, was compiled in 1888 and contains 7840 objects including galaxies, star clusters, planetary nebulae and supernova remnants. 1B11 Example of a constellation Constellation of Asterix aAst bAst RRAst eAst NGC1234 gAst dAstA dAstB M25 1B11 The magnitude scale Hipparchus (120BC) and Ptolemy (180AD) devised the magnitude scale for measuring stellar brightness, based on the response of the eye, which is logarithmic. brightest stars are 1st magnitude faintest stars are 6th magnitude this star this star is 100 times brighter than [Pogson (1856)] A difference in 1 magnitude = a factor of 2.512 in brightness 1B11 Defining magnitudes Thus Pogson defined the magnitude scale for brightness. This is the brightness that a star appears to have on the sky, thus it is referred to as apparent magnitude. Also – this is the brightness as it appears in our eyes. Our eyes have their own response to light, ie they act as a kind of filter, sensitive over a certain wavelength range. This filter is called the visual band and is centred on ~5500 Angstroms. Thus, strictly speaking, these are apparent visual magnitudes, mv. 1B11 More on the magnitude scale For example, if star A has mv=1 and star B has mv=6 Their flux ratio, flux (arbitrary units) 100 fA/fB = 2.512 mv(A)-mv(B) = 2.5125 = 100 1 1 6 apparent visual magnitude, mv 1B11 Converting from fluxes to magnitudes So if you know the magnitudes of two stars, you can calculate the ratio of their fluxes using fA/fB = 2.512 mv(A)-mv(B) Conversely, if you know their flux ratio, you can calculate the difference in magnitudes since: mB-mA = Dmv = 2.5log10(fA/fB). To calculate the apparent visual magnitude itself, you need to know the apparent visual flux for an object at mv=0, then: mS-m0 = mS = 2.5log10(fm=0) - 2.5log10(fS) => mS = - 2.5log10(fS) + C where C is a constant, ie C = 2.5log10(fm=0) 1B11 Magnitudes of different sources -12.0 Full Moon -5.0 Venus -1.5 Sirius 0.0 4.5 Vega Andromeda Galaxy 6.0 Naked eye limit 7.0 Neptune 14 Pluto 25 4m ground-based telescope limit 29 Hubble Space Telescope limit 1B11 How low can we go? We can see stars as faint as mv=6. The Hubble Space Telescope can reach mv=29. How much fainter is this? FHST/Feye = 100(mHST-meye)/5 = 10(mHST-meye)/2.5 = 109.2 In other words, HST can see stars which are over a billion times fainter than we can see with the naked eye. 1B11 Magnitude systems Flux (arbitrary units) Every star has a different temperature => a different “colour” Curves are spectra for 3 stars, hot, Sunlike and cool. 4400 5500 7000 Wavelength (Angstroms) Measurements in different colour bands give different magnitudes for different stars. 1B11 UBV Johnson System Different types of stars emit strongly at different wavelengths, thus will have different strengths depending on the filter used to observe them. transmission (arbitrary units) Harold Johnson (1921-1980) pioneered the standard UBV system of filters for measuring magnitudes in various colours. U 3600A 3000 B 4400A 4000 V 5500A 5000 6000 Wavelength (Angstroms) 1B11 UBV Johnson System In the Johnston UBV system, each filter is about 1000A wide. Filter name band Apparent magnitude Central wavelength ultraviolet U mu 3600 blue B mb 4400 visible V mv 5500 red R mr 7000 infra-red I mi 8000 (other colour filter systems are available!) The system was extended to R and I, then J,H,K in the IR. Flux (arbitrary units) 1B11 Colour index Every star has a different temperature => a different “colour” Wavelength (Angstroms) Star B-V V-R blue -ve -ve yellow +ve -ve red +ve +ve V-R B V R 4400 5500 7000 B-V 1B11 Colour index You can use many different combinations of colour index, depending on the type of objects you’re looking at the science you’re interested in. eg., (U-B), (B-V) for hot stars is useful (V-R), (R-I) for red stars or for red properties of source population For example: Spica (aVir) B=0.73 V=0.96 => (B-V) = -0.23 Betelgeuse (aOri) B=2.66 V=0.96 => (B-V) = +1.86 So Spica is brighter in the blue, Betelgeuse is brighter in V. 1B11 Temperatures, colours and classification Spectral class Colour Surface temp (K) B-V example O Blue-white 30000-35000 -0.4 Naos B Blue-white 11000-30000 -0.2 Rigel, Spica A Blue-white 7500-11000 0.0 Sirius, Vega F Blue-white to white 6000-7500 +0.3 Canopus, Procyon G White to yellowwhite 5000-6000 +0.5 Sun, Capella K Yellow-orange 3500-5000 +0.8 Arcturus, Aldebaran M Red <3500 +1.3 Betelgeuse, Antares 1B11 Temperatures, colours and classification And thereafter, stars are further subclassified using the numbers 0-9: O B A F G K M R N S 0,1,2,3,4,5,6,7,8,9 For example, our Sun is a G2 type star and has a temperature of 5800K. 1B11 Absolute magnitudes Knowing how bright a star is on the sky is very useful – but the stars all lie at very different distances from the Earth. Scientifically, we want to know a star’s intrinsic flux – ie its luminosity. Astronomers have two ways of quantifying this – Absolute magnitudes and Luminosities The absolute magnitude is the magnitude a star would have if it were placed 10 parsecs away from the Earth. 10pc 1B11 Absolute magnitudes The flux from any source falls off as the inverse square of the distance, ie intrinsic flux observed flux 2 distance Example: a star lies at distance d with apparent magnitude m and flux Fm. If this star was 10 parsecs away so that the flux was FM, then (because of the inverse square law): Fm 10pc 2 FM d But from the definition of magnitudes, m B m A Dm V 2.5 log 10 Definition of magnitudes fA fB 1B11 Distance modulus So since Then mB m A Dm V 2.5 log 10 FM m M 2.5 log 10 Fm fA fB 2 d 5 log d 5 log (10) 2.5 log 10 10 10 10 m M 5 log 10 d 5 where m-M is known as the distance modulus The absolute (V band) magnitude of the Sun is +4.6. Definition of magnitudes 1B11 Absolute bolometric magnitude So mbol 2.5 log 10 Fbol C Similarly, we can define an absolute bolometric magnitude, Mbol (ie mbol at 10 pc). Visual magnitudes can be converted to bolometric magnitudes via the bolometric correction, BC: BC (mbol mV ) (Mbol MV ) FV 2.5 log 10 Fbol Mbol MV BC BC is always negative and is determined empirically. Definition of magnitudes 1B11 Reddening and extinction reddening extinction Any dust which lies between an observer and a source will absorb light from the source and use it to heat the dust. This is extinction. Dust will also scatter the light and blue light is scattered more than red, which makes the source look more red (although strictly speaking, “less blue”) and this is called reddening. This effect makes sunsets and sunrises red. 1B11 Reddening and colour excess Extinction is hard to measure because it is monochromatic, but scattering is easier because its effect is wavelengthdependent so will manifest itself as a colour change. Observed colour = (B – V) Intrinsic colour = (B – V)0 Reddening is measured by the colour excess which is defined as: E(B – V) = (B – V) – (B – V)0 It’s measured in magnitudes – and it’s always positive! (why?) Colour index 1B11 Correcting for reddening and extinction Spectral features (absorption and emission lines, red continuum) Spectral type Intrinsic continuum shape Generally, extinction is given by: Calculate (B – V)0 A = m – m0 Where m0 would be the apparent magnitude if there was no extinction. In the V band: AV = V – V0 ~ 3.1E(B – V) 1B11 Including extinction in distance modulus Remember the distance modulus equation: m – M = 5log10d –5 Strictly speaking, m in this equation has been assumed to be unaffected by dust, so it should read: m0 – M = 5log10d –5 From A = m – m0, => m0 = m – A (m – M) = 5log10d – 5 + A Distance modulus Flux fl (erg cm-2 s-1 A-1) 1B11 Bolometric luminosity Stellar spectrum V Wavelength, l (Angstroms) Filter band magnitudes (eg U, B, V) will only give the flux at particular wavelengths (shaded). For the total bolometric luminosity, need to integrate over all wavelengths (pink). Fbol = integ(0-inf)Flambda dl where Fl is the flux at each wavelength (l) in the spectrum. 1B11 Bolometric magnitudes Alternatively, the total intrinsic emission of a star integrated over all wavelengths may be expressed as a bolometric magnitude, Mbol. Since mB-mA = Dmv = 2.5log10(fA/fB) Mbol(Sun) – Mbol(star) = 2.5log10(Lstar/LSun) Mbol(Sun) = +4.75 Log10(Lstar/LSun) = 1.90 – 0.4Mbol(star) Converting fluxes to magnitudes