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Astronomical Distances or Measuring the Universe (Chapters 7, 8 & 9) by Rastorguev Alexey, professor of the Moscow State University and Sternberg Astronomical Institute, Russia Sternberg Astronomical Institute Moscow University Content • Chapter Seven: BBW: Moving Photospheres (Baade-Becker-Wesselink technique) • Chapter Eight: Cepheid parallaxes and Period – Luminosity relations • Chapter Nine: RR Lyrae distance scale Chapter Seven BBW: Moving Photospheres (BaadeBecker-Wesselink technique) Astronomical Background • W.Baade-W.Becker-A.Wesselink-L.Balona technique (BBWB) is applicable to pulsating stars (Cepheids and RR Lyrae variables) or stars with expanding envelopes (SuperNovae) • W.Baade (Mittel.Hamburg.Sternw. V.6, P.85, 1931); W.Becker (ZAph V.19, P.289, 1940); A.Wesselink (Bull.Astr.Inst.Netherl. V.10, P.468, 1946): • photometry and radial velocities give rise to radius measurement and independent calculation of star’s luminosity (a) For a pair of phases with the same temperature and color (say, B-V), the Cepheid’s apparent magnitudes V differ due only to the ratio of stellar radii: R m 2.5 lg R R1 B-V 2 1 2 2 (b) Radii difference Pulsation Phase (R1-R2) can be calculated by integrating the radial velocity curve, due to VR ~ dR/dt R2 • A number of pairs • (R1 – R2) ~∫VR·dt and R1/R2 ≈ 10-0.2m give rise to the calculation of mean radius, <R> = (Rmax + Rmin)/2 I. BBW Surface-brightness technique (SB) Eλ θLD • θLD is “limb-darkened” angular diameter • Flux incident, Eλ ~ Φλ·θLD2, where Φλ being surface brightness (do not depending on the star’s distance!) • Apparent magnitude, mλ ~ -2.5 log Eλ , so • 0.5∙log θLD ~ -0.1·mλ - Fλ + c , with Fλ as the “surface-brightness parameter” • It can be easily shown that the “surfacebrightness parameter” is expressed as • Fλ = 4.2207 – 0.1∙mλ0 - 0.5∙ log θLD = =log Teff + 0.1 BC(λ), • where BC(λ) is the bolometric correction to the mλ magnitude, i.e. • BC(mλ) = Mbol - Mλ • The surface-brightness parameter is shown to relate with the color CI (due to surface brightness dependence on the effective temperature Φλ ~ Teff4 and CI-Teff relations) • Fλ ≈ a·CIλ + b • Example relation is shown; interferometric calibrations (Nordgren et al. AJ V.123, P.3380, 2002) • The calibrations for surface brightness parameter, Fλ, can be also derived from the photometric data for normal stars (dwarfs, giants and supergiants) with the distances determined, say, by precise trigonometric technique or other data • See, for example, M.Groenewegen “Improved Baade-Wesselink surface brightness relations” (MNRAS V.353, P.903, 2004) • From both relations, • 0.5∙log θLD ≈ -0.1·mλ - Fλ + c • Fλ ≈ a·CIλ + b • log θLD ~ -0.2·mλ + 2a·CIλ + const Light-curve Color-curve • Direct calculation of star’s angular diameter vs time • Radial velocity curve integration gives absolute radius change, and being relate to apparent angular diameter change, distance to the pulsating star follows II. Maximum Likelyhood technique by L.Balona (MNRAS V.178, P.231-243,1977) uses all light curve and precise radial velocity curve • Background: • (a) Stefan-Boltzmann low: Lbol ~ σT4 • (b) Effective temperature and bolometric correction are connected with normal color (see examples) • (c) Radius change comes from the integration of the radial velocity curve Luminosity classes: Working interval lg Teff – (B-V)0 relation by P.Flower (1996) Working interval ΔMbol Luminosity classes ΔMbol – (B-V)0 relation by P.Flower (ApJ, V469, P.355, 1996) Quadratic approximations can be written for lgTeff, ΔMbol by (B-V)0 (and by other normal colors) in the range 0.2 < (B-V)0 < 1.6 lg Teff ( B V )0 ( B V ) 2 M bol ( B V )0 ( B V ) ( B V )0 ( B V ) E ( B V ) 0 2 0 Basic equations of the Balona approach Lbol 4Teff R (Stefan - Boltzmann law) 4 2 Teff R Lbol 4 Sun L bol TSun RSun 4 M bol M Sun bol 2 Lbol 2.5 lg Sun Lbol R 10 lg Teff 10 lg TSun 5 lg RSun Substituti ng M bol M V M bol From the distance modulus expression, d M V V 5 lg 5 AV , after substituti on of all (1 pc) values we wright th e light curve MODEL as R V A ( B V ) B ( B V ) 5 lg C, RSun 2 where A, B, C are the constants , V and ( B V ) R R r (t ) is current radius with mean value R are light and color curves , and Here constants A, B and C: A 2( 10 ) E ( B V ) ( 10 ), B ( 10 ), d Sun C 5 lg 5 RV E ( B V ) M bol 10 lg TSun (1 pc) ( 10 ) ( 10 ) E ( B V ) ( 10 ) E ( B V ) 2 These constants enclose information on color excess E(B-V) and the star’s distance d How to calculate the radius change? dS: ring area -V0: photosphere velocity (to the observer) Contribution of the circular ring to the observed radial velocity Calculating R(t)=<R>+r (t): integrating radial velocity curve Vr Ring contribution to the measured radial velocity: 1) V ( ) r cos ring contributi on to Vr ; 2) 2 r sin r d 2 r sin d ring area ; 3) cos projection effect to light flux ; 4) (1 cos ) limb darkening Ring " weight " : 2 W ( ) 2 r sin cos (1 cos ) 2 Mean radial velocity weighted along star’s limb = observed Vr /2 Vr V ( ) W ( ) d 0 /2 W ( ) d 0 /2 r 2 sin cos (1 cos ) d 0 /2 sin cos (1 cos ) d 1 r p 0 p is the projection factor connecting radial velocity and the photosphere speed Projection factor values: • In the absence of limb darkening p=3/2 • In most studies p=1.31 accepted r pVr • But: projection factor depend on – Limb darkening coefficient – Velocity of the photosphere – Instrumental line profile used to measure radial velocity Theoretical spectral line will be distorted due to instrumental profile Theoretica l line profile : 20 r v F (v) v 1 , 2 V0 V0 v ( here cos , 0 v V0 ) V0 2 Instrument al Gaussian p rofile : I N ( v, V ) ( 2 ) 1 / 2 (v V ) exp 2 2 1 2 Line profile calculation enables to derive theoretical value of the projection factor, p Observed line profile (with taking into account line broadening due to instrumental effects) can be calculated as the convolution V0 f (V ) F ( v ) I N (v,V ) dv 0 Some examples of the line profiles for different line broadening due to instrumental effects Instrumental width Solid: normal Observed profile Good Gaussian fit Theoretical profile Small velocity Some examples of the line profiles for different line broadening due to instrumental effects Instrumental width Theoretical profile Normal curve Observed profile Large velocity Normal curve (blue line) Bad Gaussian fit • Modern calculations confirm the variation of p by at least ~5-7% due to different effects • (Nardetto et al., 2004; Groenewegen, 2007; Rastorguev & Fokin, 2009) Example: projection factor and line width vs photosphere velocity, V0 From Gauss tip From line tip • Projection factor p and its variation with the velocity V0 , limb darkening coefficient ε and instrumental width σ should be “adjusted” to proper spectroscopic technique used for radial velocity measurements • Example: More than 20000 VR measurements have been performed by Moscow team for ~165 northern Cepheids with characteristic accuracy ~0.5 km/s and σ ~ 15 km/s Radius change, r(t), can be calculated by integrating the radial-velocity curve, Vr (t), from some t=0 (where R(0)=<R>) t t dr r(t ) ~ dt ~ p Vr dt dt 0 0 ΔR, Solar units Vr, km/s Example: TT Aql radial velocity curve (upper panel) and radius change (bottom panel) Pulsation phase Fitting the light curve for TT Aql Cepheid (+) with the model (solid line) V V A (B V ) B (B V ) 2 5 lg ( R r) C RSun A 1.69 0.20 B 0.18 0.08 C 14.09 0.15 R (82 1.6) R Sun Pulsation phase Steps to luminosity calibration • <R>, A, B, C enable: – To calculate mean bolometric and visual luminosity of the star and its distance – To refine transformations of Teff to normal colors and bolometric corrections (additionally) • BBWB technique has been applied to Cepheid and RR Lyrae variables and turned out to be very effective and independent tool for P-L calibrations (see later) • For Fundamental tone Cepheids: • log R/RSun = 1.23 (±0.03) + (0.62 ±0.03) log P by M.Sachkov (2005) Cepheid radii can be used to classify Cepheids by FU the pulsation 1st mode (first-overtone pulsators have shorter periods at equal radii) • Well known possibility to measure the distances to some SuperNova remnants via their angular sizes and the envelope expansion velocities is also can be considered as the modification of the moving photospheres technique • Possible explosion asymmetry can induce large errors to estimated parameters t1 t2 SN t2 D ~ VR (t ) dt t1 VR Δφ D • Optical and NIR interferometric direct observations of the radii changes of nearest Cepheid are of great importance and very promising tool to measure their distances and correct the distance scale • B.Lane et al. (ApJ V.573, P.330, 2002): • Palomar PTI 85-m base length optical interferometer Distance within 10% error Phase • P.Kervella et al. (ApJ V.604, L113, 2004): interferometric (ESO VLT) apparent diameter measurements (filled circles) as compared to BW SB technique (crosses) D ~ 566 ±20 pc Very good agreement Chapter Eight Cepheid parallaxes and Period – Luminosity relations • • • • • Astrophysical background Overtone pulsators Use of Wesenheit index Luminosity calibrations P-L or P-L-C ? Cepheids “econiche” Cepheids as calibrators for these methods 100 pc … 50 Mpc pc • Cepheids and RR Lyrae variable stars populate Instability Strip on the HRD (see blue strip) where most stars become unstable with respect to radial pulsations • Instability Strip crosses all branches, from supergiants to white dwarfs G.Tammann et al. (A&A V.404, P.423, 2003) • Instability strip for galactic Cepheids (members of open clusters and with BBWB radii) in more details: • MV-(B-V) and MI-(V-I) CMDs • Comprehensive review of the problem by: Alan Sandage & Gustav Tammann “Absolute magnitude calibrations of Populations I and II Cepheids and Other Pulsating Variables in the Instability Strip of the Hertzsprung-Russell Diagram” (ARAA V.44, P.93-140, 2006) Cepheids: named after δ Cepheus star, the first recognized star of this class • Young (< 100 Myr) and massive (3-8 MSun) bright (MV up to -7m) radially pulsating variable stars with strongly regular brightness change (light curves) • Typical Periods of the pulsations: from ~1-3 to ~100 days (follow from P ~ (Gρ)-1/2 expression for free oscillations of the gaseous sphere: mean mass density of huge supergiants, ρ, is very small as compared to the Sun) • Luminosities: from ~100 to 30 000 that of the Sun • Evolution status: yellow and red supergiants, fast evolution to/from red (super)giants while crossing the instability strip (solid lines) Evolution tracks for 1-25MSun stars on the HRD • Relative fraction of Cepheids population depends on the evolution rate while crossing the instability strip: • slower evolution means more stars at the appropriate stage • (a) Tracks are not Cepheids evolution tracks, The differences in the evolution parallel to the lines the instability rates at different give strip and of constant periods crossings P=const rise to the questions on the lines (red) lg bright L IS relative contribution of faint Cepeids •and Evolutional period for the same changevalue happens period • (b) Evolution rate during 2nd & 3rd crossings is slower than for 1st crossing, defining the IS population fraction • (c) Luminosity depend on the crossing number An extra source of P-L scatter • dP/dt is visible when observing on long time interval (~100 yr) P increase + P decrease • At equal periods: Cepheids withlong … but it requires different masses time monitoring but withtodifferent Impossible use for crossing number extragalactic Cepheids, • lg (dP/dt) vs lg P: crossing number Maybe, any spectroscopic diagnostics (as features will be found compared to the responsible for crossing theory) • Perspective tool to identify crossing number and to refine the P-L relation… • The duration of the Cepheids stage is typically less than 0.5 Myr and, taking also in consideration the rarity of massive stars at all, we guess that Cepheids form very poor galactic population • Statistics of Cepheids discovered: ~3000 proven and suspected in the Galaxy, ~2500 in the LMC, ~1500 in the SMC, ~Thousands are found and, ~50 000 are expected to populate the Andromeda Galaxy (M31) • Easily recognized by its high brightness and periodic magnitude change among other stars, even in distant galaxies (up to 50 Mpc) • Typical population of young clusters, spiral and irregular galaxies • Luminosity increases with the Period (P-L relation) • Cepheids are still among most important “standard candles” Hertzsprung Sequence of Cepheids (normalized) light curves. Bump position. (from P.Wils) A.Udalski et al. “The Optical Gravitational Lensing Experiment. Cepheids in the LMC. IV. Catalog…” (Acta Astronomica V.49, P.223, 1999) • Apparent mean I magnitude corrected for differential absorption inside LMC vs log P(days) for fundamental tone (FU) and first overtone (FO) cepheids: • <I> ≈ a + b∙lg P • PFO / PFU ≈ 0.71 • (Δ lg P ≈ 0.15) W(I) Brightest Cepheids Distances are the same: absolute magnitudes <MI> are also linear on log P ! • Linearity of log P-log L relation retains also for Cepheids absolute magnitudes • Simple estimate: • Brightest LMC Cepheids reach <MV> ≈ -7m • These “standard candles” can be seen from the distance ~50 Mpk (with ~27m limiting magnitude accessible to HST) • Brightest Cepheids can be widely used as secondary sources of distance calibrations to spiral galaxies hosted by SN Ia etc. We can see Cepheids even in distant galaxies • Overtone Cepheids are clearly seen on the “apparent magnitude – period” diagrams of nearby galaxies as having smaller periods for the same brightness • Problem with Milky Way Cepheids: due to distance differences, how to identify overtone pulsators among Cepheids with different distances ? • Milky Way Cepheids sample is supposed to be contaminated by unidentified first-overtone pulsators • This problem greatly complicates the extraction of the P-L relation directly from observations of Milky Way cepheids Sources of calibrations of the Cepheids absolute magnitudes • (a) Trigonometric parallaxes (HIPPARCOS and HST FGS) • (b) Membership of Cepheids in open clusters and associations • (c) BBWB mean radii • (d) Luminosity refinement by the statistical parallax technique (a) Cepheids trigonometric parallaxes • P-L relation <MV> ≈ a + b∙lg P from van Leeuwen (2007) data for 45 parallaxes (σp/p < 0.5). Total of 87 Cepheids shown. Good slope, bad zero-point: ~0.7-0.8m fainter as compared to conventional P-L relations. Lutz-Kelker Bias: shifts to top but is too uncerntain for ~50% errors • To separate the correction to P-L slope from the correction to zero-point, we can rewrite P-L relation in the equivalent form • <MV > = (a + b) + b·(lg P – 1), where (a + b) is <MV> (at P=10d) with the “conventional” values for • (a + b) ≈ -3.9 … –4.2 • (a + b) can be considered as zero-point “substitute” • Common way to refine the constants • <MV> (at P=10d) vs lg P (from new HIPPARCOS reduction by van Leeuwen, 2007, and extinction data). • Red: 45 Cepheids with σp/p < 0.5 HIPPARCOS • Blue: all Cepheids parallaxes alone disable to derive fine P-L relation! (a + b)st Partly, overtone pulsators? • “How to deal with the Lutz-Kelker bias?” – That’s the question not yet finally solved (M.Groenewegen & R.Oudmaijer, A&A V.356, P.849, 2000) • Should the Lutz-Kelker correction be added to each star of the sample (or the selection by the parallax is always biased) ? • Some authors use “reduced parallax” approach instead of distances approach (see C.Turon Lacarrieu & M.Creze “On the statistical use of trigonometric parallaxes”, A&A V.56, P.373, 1977): 0.2 MV p ~ 10 • P-L relation: <M> = a + b·lg P • (a) zero-point • (b) slope • Why not to estimate the slope of the P-L relation directly from LMC Cepheids ? – • The slopes of the P-L relations in other galaxies may differ due to systematic differences in the metal abundances and Cepheids ages (A.Sandage & G.Tammann, 2006) • Before ~2003, most astronomers used the slope of LMC Cepheids to refine zero-point of Milky Way Cepheids • If metallicity effects are really important, application of single P-L relation to other galaxies populated by Cepheids can introduce additional systematic errors (see detailed discussion in A.Sandage et al., 2006) Problems with the interstellar extinction • Cepheids color excess are uncertain because of: – Finite width of the instability strip (~0.2m) due to evolution effects – Uncertainty of cepheids “normal colors” • • Wesenheit index (Wesenheit function) is often used to reduce the effects of the interstellar extinction (B.Madore in “Reddening-independent formulation of the P-L relation: Wesenheit function”; ROB No.182, P.153, 1976) Example: Wesenheit index for (V-I) color • From true distance modulus we have: MV V 10 5 lg p (mas) AV • Wesenheit index definition: Constant! AV W ( VI ) V 10 5 lg p (mas) (V I ) E( V I ) Wesenheit Wesenheit index do notindex depend on the extincton but only the normal color color •on Substituting apparent ( V I ) ( V I )0 E( V I ) Normal color as well as <MV> we derive: is linear on lg P AV (see instability strip picture!), W ( VI ) V 10 5 lg p (mas) AV ( V I )0 E( VP I ) so W(VI) is also linear on lg AV MV ( V I )0 W ( VI ) MV ( V I )0 E( V I ) where const β = AV/E(V-I) ≈ 2.45± follows from the extinction law • Wesenheit Index can be introduced for any color: W(BV), W(VK) etc. • W incorporates intrinsic color (and Period – Color relation) • The advantage of using the Wesenheit index W instead of the absolute magnitude M is that – (a) Wesenheit index is almost free of any assumptions on cepheids individual color excess, particularly in our Milky Way, and – (b) it reduces the scatter of the P-L relations Use of the Wesenheit index • M.Groenewegen & R.Oudmaijer, “Multicolour PL-relations of Cepheids in the HIPPARCOS catalogue and the distance to the LMC” (A&A V.356, P.849, 2000) • A.Sandage et al. “The Hubble constant: a summary of the HST program for the luminosity calibration of type Ia SuperNovae by means of Cepheids” (ApJ V.653, P.843, 2006) • F.van Leeuwen et al. “Cepheid parallaxes and the Hubble constant” (MNRAS V.379, P.723, 2007) • F.van Leeuwen et al. “Cepheid parallaxes and the Hubble constant” (MNRAS V.379, P.723, 2007) W(VI) Wesenheit index W(VI) for 14 Cepheids with most reliable parallaxes from HIPPARCOS and HST FGS: Route to P-L relation W(VI) W(VI) = α·lg P + γ • To derive P-L relation: • MV ≈ W(VI) + β·(V-I)0 • Normal colors are also linearly dependent on the period: CI0 ≈ δ·lg P + ε Example: Period – Color (P-C) relation for galactic Cepheids from G.Tammann et al. (A&A V.404, P.423, 2003). Wide strip (σCI≈0.07m) (V-I)0 vs lg P • To derive P-L relation: W M V: • MV ≈ W(VI) + β·(V-I)0 • MV ≈ (α + β·δ) ·lg P + (γ + β· ε) • Serious problem: effects of [Fe/H] • Theoretical approach: • A.Sandage et al. “On the sensitivity of the Cepheid P-L relation to variations of metallicity” (ApJ V.522, P.250, 1999) • I.Baraffe & Y.Alibert “P-L relationships in BV IJHK-bands for fundamental mode and 1st overtone Cepheids” (A&A V.371, P.592, 2001) • G.Tammann et al. (A&A V.404, P.423,2003): • P-C relations for Galaxy, LMC & SMC • L/SMC are metal-deficient relative to the Galaxy LMC/SMC Cepheids are bluer than in the Milky Way • Overall impression: [Fe/H] differences affect also P-L relations (slope & zeropoint) • Key question: Systematic error induced to P-L based distances when we neglect metallicity differences • From A.Sandage et al. new stellar atmospheres models and synthetic spectra (ApJ V.522, P.250, 1999): • At P = 10d: bol B V I dM/d[Fe/H] (mag/dex) 0.00 +0.03 -0.08 -0.10 “…The agreement of the RR Lyrae distance to the LMC, the SMC, and IC 1613 with the Cepheid distance determined on the basis of only a mild (if any) metallicity dependence of the P-L relation for classical Cepheids is our principal conclusion”. • M.Groenewegen & R.Oudmaijer (A&A V.356, P.849, 2000): • ΔM = MGal – MLMC for VIK bands (LMC is ~0.3-0.4 dex metal-deficient as compared to MW: W.Rolleston et al., A&A V.396, P.53, 2002) • Corrections disagree due to the differences in the theoretical models ! • M.Groenewegen “Baade-Wesselink distances and the effect of metallicity in classical Cepheids” (A&A V.488, P.25, 2008) • Problem was investigated by P-L relations based on BBWB Cepheids radii … • “Obtaining accurate distances to stars is a non-trivial matter (Yes! – A.R.)… The metallicity dependence of the PL-relation is investigated and no significant dependence is found. A firm result is not possible as the range in metallicity spanned by the current sample of galactic Cepheids is 0.3–0.4 dex, while previous work suggested a small dependence on metallicity only (typically −0.2mag/dex).” • There is no common agreement in the reality of significant differences in the slopes of the P-L relations in different galaxies due to differences in [Fe/H] • (F.van Leeuwen et al. (2007): “…The main conclusion … is that within current uncertainties <the P-L slope - A.R.> is the same in the Galaxy as in the LMC…”) • As a consequence, some ambiguity remains in the calibrations of other standard candles based on the Cepheids distance scale (b) Cepheids in open clusters and associations • Another way to derive independently the slope and zero-point of the P-L relations of galactic Cepheids comes from open clusters and associations (young stellar groups hosted by the Cepheid variables) • Their distances calculated by the MSfitting are good to about few per cent • Approximately 30-50 galactic Cepheids are considered as possible cluster members L.Berdnikov et al. “The BVRIJHK period-luminosity Metallicity differences have been relations for Galactic classical Cepheids” (AstL V.22, P.838, 1996) Cepheids in 5 open clusters: taken– 9into account empirically, by days days adding the term proportional to Very poor statistics! the difference of the galactocentric distances (due to “mean” [Fe/H] Zero-points Slope gradient across the galactic disk, Δ[Fe/H] / ΔRG) ~ -0.05… -0.10 ± days days Multicolor (BVRCRICIJHK) P-L relations for galactic Cepheids P-L slopes as compared to the LMC Cepheids Optics | NIR LMC m • D.Turner & J.Burke “The distance scale for classical cepheid variables” (AJ V.124, P.2931, 2002) • The list of 46 Cepheids as possible members of young stellar groups (clusters and associations) • (Future prospects) • D.An et al. “The distances to open clusters from main- sequence fitting. IV. Galactic Cepheids, the LMC, and the local distance scale” (ApJ V.671, P.1640, 2007) New distances New P-L for the galactic Cepheids: (c) Distance scale from BBWB radii Comparing Cepheids P-L derived from 23 cluster Cepheids (red) with that from Wesselink radii (blue) (D.Turner & J.Burke, 2002) Insignificant slop difference ~0.19 Mean: <MV>≈-1.20m-2.84m·lg P • A.Sandage et al. (A&A V.424, P.43, 2004) BBWB P-L (circles) for 36 galactic Cepheids P-L for 33 cluster members (dots) P-L are very close within errors • Rms scatter: σ ~ 0.19…0.27m MB0 Galaxy • A.Sandage et al. (A&A V.424, P.43, 2004) • LMC Cepheids: Instability Strip break on MV0-(B-V)0 CMD • Hint on P-L break at P=10d ? • Complicates the use of P-L for distance measurements Constant lg P lines • Nonlinear calculations of the Cepheids models also seem to support an idea on two Cepheids families divided by the period value Plim ~ 9-10d • Theory: large fraction of the Cepheids with P < Plim are suspected to be 1st overtone pulsators For • • • 0.5 1.0 1.5 2.0 lg P “Broken” at P=10d P-L relations for LMC Cepheids (A.Sandage et al., 2004, 2006) (a) Flatter P-L for P > 10d can introduce systematic distance errors to distant galaxies where only brightest Cepheids are observed (b) Poor statistics (~ 2 dozens) of brightest Cepheids introduces extra scatter A.Sandage et al. (2004, 2006): • Comparing “broken” P-L (BVI bands) for LMC (solid line) with conventional P-L for the Milky Way Galaxy (BBWB & cluster cepheids: dots & circles) • Close at P ~ 10d (after reducing LMC zeropoints by ~0.15m) Systematic differences ! <MB> <MV> <MI> • A.Sandage et al. (2004) “closing speech”: • “…The consequences of the differences in the slopes of the P-L relations for the Galaxy, LMC, and SMC weakens the hope of using Cepheids to obtain precision galaxy distances. Until we understand the reasons for the differences in the P-L relations and the shifts in the period−color relations, (after applying blanketing corrections for metallicity differences), we are presently at a loss to choose which of the several P-L relations to use (Galaxy, LMC, and SMC) for other galaxies. • Although we can still hope that the differences may yet be caused only by variations in metallicity, which can be measured, this can only be decided by future research such as survey programs to determine the properties of Cepheids in galaxies such as M33 and M101 where metallicity gradients exist across the image. But until we can prove or disprove that metallicity difference is the key parameter, we must provisionally assume that this is the case, and use either the Galaxy P-L relations, or the LMC P-L relations, or those in the SMC.” • Detailed study of the Cepheids populations in the Local Group galaxies may seem “unfashionable” to most of the astronomical community • This is the reason why a number of key questions still remain unexplained, including the effects due to the differences in metallicity The use of Cepheids P-L-C manifold is theP-L-C “cousin” (Period – Luminosity - Color) relations of the Fundamental Plane for elliptical galaxies • Cepheids P-L-C manifold in lg T – lg P – lg L coordinates • Projections give P-L & P-C relations and the Instability Strip • Constructing the P-L-C “plane”: • The intrinsic scatter of the P-L relation is due to the finite width of the instability strip and the sloping of the constant-period lines. • The scatter can be reduced by βλ=ΔMλ / ΔCI forofP=const introducing a P-L-C relation the form λ taken • Mλ = αλ·lg P - βλ·CIλ + γλ , CIλ is color index (λ) where βλ is the slope of the constantperiod lines on the appropriate CMD • A.Sandage P-L-C relation translates the magnitude et to al. the value an unreddened Cepheid (2004) would have if it were lying on the ridge line • CMDs of theand P-C and P-L relations the (except for observational errors) constant period lines (red) for LMC Cepheids • The slopes vary with P • Earlier, the use of P-L-C relation instead of P-L, gave unsatisfactory results because constant slope of the constant period lines, ΔMV/Δ(B-V), have been supposed for all P, L and colors • A.Sandage et al. (2004, 2006): • P-L-C constants α, β, γ depend on the period and vary significantly from galaxy to galaxy lg P<1 V lg P>1 lg P<1 V lg P>1 lg P<1 I lg P>1 lg P<1 I lg P>1 • A.Sandage et al. (2004) • LMC Cepheids MV - βV-(B-V)(B-V) and MI –βI-(V-I)(V-I) vs lg P relations: reduced scatter (σ ≈ 0.07…0.17m) • Very attractive idea! • Least squares solutions for lg P>1 (lower) & lg P<1 (upper) are shown • Note: • Reduced scatter of the P-L-C relation may seem attractive, but in the absence of independent data on the intrinsic color differences (say, due to metallicity or extinction differences), this technique can give rise to artificial errors in the absolute magnitude • A.Sandage explains: • A.Sandage et al. (2004): “The P-L-C relation can only be used if it can be proven that the Cepheids under consideration follow the same P-L and P-C relations. Otherwise any intrinsic color difference is multiplied by the constant-period slope β and erroneously forced upon the magnitudes with detrimental effects on any derived distances.” • It would be wrong idea to apply the LMC P-LC relation to Milky Way Cepheids which have different P-L (BVI ) relations and (necessarily !) also different P-C relations (for B−V, V−I ). – Clear as day! (A.R.) (d) Luminosity refinement by the statistical parallax technique • The applicability of the statistical parallax technique to the Milky Way Cepheids requires very accurate radial and tangential velocities. Observational errors obviously should not exceed the intrinsic scatter of space residual velocities. HIPPARCOS proper motions joined with the extensive set (~20000) of CORAVEL radial velocity measurements made by the Moscow group (N.Gorynya et al., VizieR Cat. III/229, 2002) became real base to Cepheids statistical parallaxes, and enabled to A.Rastorguev et al. (AstL V.25, P.595, 1999) to derive the corrections to the Cepheids distance scale (L.Berdnikov et al., 1996), i: extension by ~7% (ΔMV ≈ -0.15m) Relative magnitude NIR/MIR prospects • An example of the Cepheid light curve (SU Cyg) in UBVRIJK bands (top-down): • The amplitude decreases with wavelength, as well as the scatter of multicolor P-L relations • Few brightness estimates in NIR (>2.2 μm) suffice to estimate mean magnitude and the distance • NIR/MIR data are of great importance for distance scale refinement and luminosity calibrations • W.Freedman et al. “The Cepheid P-L relation at mid-infrared wavelengths. I.” (ApJ V.679, P.71, 2008) • Single-epoch observations for 70 LMC Cepheids from SPITZER (1 point at each light curve!) • Slope steeper in MIR (>3.3 mμ) than in NIR and optics • W.Freedman et al. “The Cepheid P-L relation at midinfrared wavelengths. I.” (ApJ V.679, P.71, 2008) • P-L relations in MIR (>3.3 mμ) are nearly the same: • RMS scatter of MIR P-L relations is ~0.07m, so even single MIR observation can give the distance precise to ~8% • Very promising tool to measure large extragalactic distances Addendum to Cepheids discussion: LMC as the touchstone of the distance scale adjustment • LMC is hosted by a wide variety of stellar populations, from very young to old ones; as a consequence, LMC with its ~50 kpc distance, is very “suitable” stellar system to apply different tools of distance measurements used different “standard candles”, such as Cepheids, RR Lyrae, RCG, Tip Red Giants, MS-fitting, binaries, Miras etc. • Ideally, all distances to LMC should agree within appropriate errors of methods used • In the mid-1980’s, measurement of H0 with the goal of 10% accuracy was designated as one of three “Key Projects” of the HST (M.Aaronson & J.Mould, ApJ, V.303, P.1, 1986), with LMC as the central object • Real HST observations began in the 1991 • Results in: W.Freedman et al. “Final Results from the Hubble Space Telescope Key Project to Measure the Hubble Constant” (ApJ V.553, P.47, 2001) • LMC weighted “mean” distance: • (m-M)0 ≈ 18.50 ± 0.10m LMC distances from Cepheids: ΔM ≈ 0.6m HST KP Systematic difference between Cepheids and RR Lyrae distances is clearly seen: “short” vs “long” distance scale ? (m-M)0 • Most reliable conventional Cepheids distance scales derived by different approaches, differ from each other at the 0.15-0.2m level (7-10% in the distance) • Their systematic errors are unknown • Which one is true? • Concluding remark of A.Sandage & G.Tammann (2006): • “Clearly, much work lies ahead. We are only at the beginning of a new era in distance determinations using Cepheids. It can be expected that much will be discovered and illuminated in the years to come”. Chapter Nine RR Lyrae distance scale RR Lyr star is an archetype of old halo population (Horizontal Branch) short-period variable stars RR Lyr is the brightest and nearest star of this type with its <MV> ≈ 9.03 ± 0.02m, <B-V> ≈ 0.44 ± 0.04m, D ≈ 260 pc , (HIPPARCOS, 2007) • M.Marcony & G.Clementini (ApJ V.129, P.2257, 2005) • Periods < 1d • Examples of LMC RR Lyrae light curves in BV bands Observations vs theory Large amplitude, Δm ~ 1m • Examples of the LMC RR Lyrae light curves in I band (OGLE program, I.Soszynski et al., Acta Astr. V.53, P.93, 2003) • RR are simply discernible among field stars in stellar systems • <MV> ≈ +1m T.Brown et al. (AJ V.127, P.2738,2004) • HST ACS • M31 RR Lyrae light curves example • <[Fe/H]> ≈ -1.6 from periods distribution • NIR light curve of RR Lyr star: look at small amplitude. RR Lyr: nearest star of this type. Not so bright as Cepheids but very important for distance scale subject in the galactic halos, bulges and thick disk populations • RR Lyrae variable stars in the Instability Strip on the HRD • In contrast to Cepheids, RR Lyrae variables are among oldest stars of our Milky Way • Evolution status: horizontal branch (HB) stars • RR Lyrae variables populate galactic halos (H) and thick disks (TD) (as single stars), and globular clusters of different [Fe/H] • Evolution stage: Helium core burning • Age: ≥ 10 Gyr RR Lyrae M2 • LifeTime: ~100 Myr V const ? BHB (EHB) TP H TD Close luminosities for the same [Fe/H] (rms ~ 0.15m) • The duration of RR Lyrae stage (and HB stage at all) is negligible as compared to the age of stars, ≤100 Myr vs ~10-13 Gyr (<1%), but comparable with lifetime of Red Giants • Therefore, HB population is comparable with RG population in size, but RR Lyrae form only a small fraction of all stars above Turn-Off point on the CMD • Thousands of RR Lyrae are found and catalogued in the Milky Way halo and in its globular clusters • Post-ZAHB tracks for low-mass stars (by B.Dorman (ApJS V.81, P.221, 1992) with [Fe/H]=-1.66 and Blue & Red edges of the Instability Strip (IS) • Masses on ZAHB are labelled Stars evolve from ZAHB to second RG tip IS Zero-Age Horizontal Branch (ZAHB) Stellar evolution for low-mass stars • Dots are separated by 10 Myr time interval • HB position is almost the same for clusters of different age HF IS Gyr age • Universality of RR Lyrae population luminosity • D.VandenBerg et al. (ApJ V.532, P.430, 2000) theoretical ZAHB levels for different [Fe/H] and [α/Fe] values • [Fe/H] seems to be the key parameter responsible for RR Lyrae optical luminosity • The slopes of P - L and [Fe/H] - L relations seems to be definitely found from the theory as well as from observations in globular clusters and nearby galaxies differ by [Fe/H] • Zero-point refinement is Main problem in RR Lyrae distance scale studies • From late 1980th, it became customary to assume a linear relation between RR Lyrae optical absolute magnitude and metallicity of the form • <Mopt> = a + b·[Fe/H] • The calibration problem reduced to finding a and b by whatever calibration method was used. The three most popular have been: • (a) theory • (b) the BBWB moving atmosphere method • (c) distances of globular clusters; HST & HIPPARCOS parallaxes • (d) statistical parallaxe technique (a) P.Demarque et al. (AJ V.119, P.1398, 2000) • Is there universal slop of the <MV> - [Fe/H] relation? • Theoretical slopes μ (a) G.Bono “RR Lyrae distance scale: theory and observations” (arXiv:astro-ph/0305102v1, 2003) • RR Lyrae models in NIR do obey to a welldefined PLZK relation: • • <MK> ≈ -0.775 − 2.07·lg P + 0.167·[Fe/H] with an intrinsic scatter of ~0.04m (with small contribution from [Fe/H] term) (a) M.Catelan et al. “The RR Lyrae P-L relation. I. Theoretical calibration” (ApJSS V.154, P.633, 2004) • • • • <MI> ≈ <MJ> ≈ <MH> ≈ <MK> ≈ +0.109 – 1.132·lg P + 0.205·[Fe/H] -0.476 – 1.773·lg P + 0.190·[Fe/H] -0.865 – 2.313·lg P + 0.178·[Fe/H] -0.906 – 2.353·lg P + 0.175·[Fe/H] • <MV> ≈ +1.258 + 0.578·[Fe/H] + 0.108·[Fe/H]2 • (this nonlinear function of [Fe/H] do not depend on lg P: • <MV> ≈ +0.63m at [Fe/H]=-1.5 ) • Two important RR Lyrae features: • (a) <MV> depend on [Fe/H] and practically does not depend on period • (b) <M> in NIR (JHK bands) depend on the period and practically do not depend on [Fe/H] • [M/H] = [Fe/H] + + lg (0.638·10[α/Fe] + 0.362) Takes into account differences in [α/Fe] (from theory: M.Catelan et al., 2004) • Usually, RR Lyrae distance scales are characterized by the mean absolute magnitude referred to [Fe/H] = -1.5, the maximum of [Fe/H] distribution function of RR Lyrae field stars and GGC (galactic globular clusters) • (b) BBWB technique rewiev: C.Cacciari & G.Clementini in: Stellar Candles for the Extragalactic Distance Scale ( Ed. D.Alloin & W.Gieren, Lecture Notes in Physics, V.635, P.105-122, 2003): • <MV>RR = (0.20±0.04)[Fe/H] + (0.98±0.05) • C.Cacciari et al. (ApJ V.396, P.219, 1992): <MV>RR vs [Fe/H] <MV>RR ≈ 0.20∙[Fe/H] + 1.04 <MK>RR vs lg P <MK>RR ≈ -2.79·lg P -1.08 • Notes to BBWB technique applied to RR Lyrae variables: • (a) Zero-points and slopes are in general agreement with the theory • (b) Interstellar absorption problems seem to be not so important for RR Lyrae (halo stars with small color excess) as compared to the Cepheids (c) RR Lyr – nearest RR-type variable - HST trigonometric parallax • G.Fritz Benedict et al. (AJ V.123, P.473, 2002) – HST FGS3 parallax for RR Lyr • pRR • For RR Lyr star itself: • MV(RR) ≈ +0.61 ± 0.1m • with [Fe/H] ≈ -1.39 • <V> ≈ +9.0m • HIP: old HIPPARCOS • data (1997) (c) RR Lyr HIPPARCOS trigonometric parallax • F.van Leeuwen “HIPPARCOS, the new reduction of the raw data” (Springer: 2007) • – new RR Lyr parallax: pRR • • • pRR ≈ (3.88 ± 0.39) mas means MV(RR) ≈0.61±0.09m • • in ideal accord with HST FGS3 estimate • Taking into account <MV>RR variation with [Fe/H], we can extrapolate <MV>RR to RR Lyrae with [Fe/H] ≈ -1.50 (at the maximum of the metallicity distribution function) by using the slope d<MV>RR/d[Fe/H] ≈ 0.2 as • <MV>RR ([Fe/H] = -1.50) ≈ +0.59m ~ 0.15m brighter than its conventional value, ~0.72-0.75m Archetype - RR Lyr star is not the best “standard candle” ! Notes: • (a) Estimated <MV> for individual stars can differ from “mean” absolute magnitude by ~0.15m, intrinsic scatter for the HB stars • (b) All RR Lyrae calibrations used the trigonometric parallaxes (MS-fitting of globular clusters populated by RR Lyrae based on subdwarf stars, direct RR Lyrae distances) suffer from Lutz-Kelker bias • There is no common consensus in the statement that the Lutz-Kelker correction really should be applied to individual stars… (c) M.Frolov & N.Samus (AstL V.24, P.174, 1998) • K-band P-L RR Lyrae relation for 173 RR in 9 globular clusters of different [Fe/H] • <MK> ≈ -2.338 (±0.067) lg P – 0.88 (±0.06) (with rms scatter ~0.06m) • Synthetic P-L diagram • P-L slope is very reliable, but zero-point can differ from this because it depends on clusters distances adopted (c) F.Fusi-Pecci et al. (AJ V.112, P.1461, 1996) • <MV>HB calibration (<MV>HB ≈ >MV>RR) • HST data for 9 M31 Globular clusters • <MV>HB ≈ (0.13 ± 0.07) [Fe/H] +(0.95 ± 0.09) • Zero-point depends on M31 distance adopted (d) RR Lyrae statistical parallaxes • Comprehensive rewiev of the problem in: A.Gould & P.Popovsky “Systematics in RR Lyrae statistical parallax. III” (ApJ V.508, P.844, 1998) • <MV>RR ≈ 0.77±0.13m at [Fe/H]=–1.6 from 147 RR Lyrae 3D velocity field and • <MV>RR ≈ 0.80±0.11m at [Fe/H]=–1.71 from 865 RR Lyrae 2D velocity field • Fainter than from other data sources (d) RR Lyrae statistical parallaxes • A.Dambis & A.Rastorguev “Absolute Magnitudes and Kinematic Parameters of the Subsystem of RR Lyrae Variables” (AstL V.27, P.108, 2001) • <MV>RR ≈ 0.76±0.12m for “halo” RR population at [Fe/H]=–1.6 • <MV>RR ≈ 1.01+0.15·[Fe/H] from RR Lyrae subdivided into 5 independent groups by [Fe/H] <MV>RR ≈ 0.79m ([Fe/H]=–1.5) Notes to (d): • Statistical parallax technique seem to underestimate RR Lyrae luminosity (and the distance scale) • C.Cacciari et al. (2003) note two main sources of the systematical errors: – (a) Contamination of halo RR Lyrae sample by thick disk stars (with differential rotation in the Milky Way) – (b) Inhomogeneity of the galactic halo that can include considerable fraction of stars came from “accreting” Milky Way satellites identified in SDSS in recent years • Two halo subsystems would have different dynamical characteristics and origins, the slowly rotating subsystem being associated to the Galactic thick disk, and the fast rotating (possibly with retrograde motion) subsystem belonging to the accreted outer halo • From new paper of E.Bell et al. (ApJ V.680, P.295, 2008): “… a dominant fraction of the stellar halo of the Milky Way is composed of the accumulated debris from the disruption of dwarf galaxies” • Any kinematical inhomogeneity of the sample used can introduce unpredictable systematical errors to the distance scale • The statistical parallax technique, very powerful in itself, need more adequate kinematical models for halo populations and more extended RR Lyrae samples, with good radial velocities and proper motions • Comparing RR Lyrae <MV> vs [Fe/H] theoretical relation (solid line) with the statistical and trigonometric parallaxes calibrations (A.Sandage et al., 2006): systematical differences Dambis & Rastorguev (2001) LMC distances from RR Lyrae: ΔM ≈ 0.5m (m-M)0 • G.Fritz Benedict et al. (AJ V.123, P.472, 2002) gave a summary of all the distance measurements to LMC galaxy, performed by 21 different methods, with “mean” value close to (m-M)0≈18.50m • Ranking by value B.Schaefer (2008) test of Guess what happened in ~2001 ? LMS distance measurements • Main goal was to check if: – (a) All measurements are really independent and unbiased – (b) All random errors are correctly reported Consider the relative deviation parameter: D = (μ-<μ>) / σ • K-S (Kolmogorov-Smirnov) statistical test of cumulative |D| distribution: theory (smooth) vs published measurements (step function) • An excess of small |D| is seen after 2002: ~68% are within 0.5 σ instead of 68% within 1 σ as it follows from the theory, or too many too presise estimates • An excess of large |D| is seen among the results before 2001 (year of publication the results of HST Key Project – HST KP), or too much too inaccurate estimates • (I) Before the year 2001, the many measures spanned a wide range (from 18.1m to 18.8m), with the quoted error bars being substantially smaller than the spread, and hence the consensus conclusion being that many of the measures had their uncertainties being dominated by unrecognized systematic problems • (II) After 2001 (HST KP results), community has generally accepted and widely popularized value μ≈18.50±0.10m, and “independent” measures clustered tightly around it, indeed, too tightly. This concentration is a symptom of a worrisome problem: (a) correlations between papers, (b) widespread overestimation of error bars, (c) band-wagon effect Summary to Cepheids and RR Lyrae • Cepheids as very bright and uniquely identified stars are among most “popular” standard candles in the distant galaxies, but their distance scale is still uncertain by ~10% (systematic + random error) • RR Lyrae are good standard candles used to refine the distances to the “beacon” galaxies (such as LMC/SMC, M31/33 etc.) in the Local Volume (up to ~10 Mpc), and to calibrate other secondary standard candles (SN Ia, Tulli-Fisher & Faber-Jackson relations etc.) • Much work has to be done with Cepheids and RR Lyrae variables in recent years and in the future, in the context of GAIA and SIM observatories