APJACCEPTEDVERSIONJANUARY28,2006 PreprinttypesetusingLATEXstyleemulateapjv.6/22/04 THETULLY-FISHERRELATIONINCLUSTERCL0024+1654ATZ=0.412 ANNEJ.METEVIER3ANDDAVIDC.KOO UniversityofCaliforniaObservatories/LickObservatoryandDepartmentofAstronomyandAstrophysics,UniversityofCalifornia,SantaCruz,CA95064 LUCSIMARD HerzbergInstituteofAstrophysics,NationalResearchCouncilofCanada,Victoria,BCV9E2E7,Canada AND ANDREWC.PHILLIPS UniversityofCaliforniaObservatories/LickObservatory,UniversityofCalifornia,SantaCruz,CA95064 6 ApJacceptedversionJanuary28,2006 0 0 ABSTRACT 2 Usingmoderate-resolutionKeckspectra, we haveexaminedthe velocityprofilesof 15membersof cluster n Cl0024+1654atz=0.4.WFPC2imagesoftheclustermembershavebeenusedtodeterminestructuralparam- a eters, includingdisksizes, orientations,andinclinations. We comparetwo methodsof opticalrotationcurve J analysis for kinematic measurements. Both methods take seeing, slit size and orientation, and instrumental 0 effectsintoaccountandyieldsimilarrotationvelocitymeasurements. Fourofthegalaxiesinoursampleex- 3 hibitunusualkinematicsignatures,suchasnon-circularmotions.OurkeyresultisthattheCl0024galaxiesare marginallyunderluminous(0.50±0.23mag), giventheir rotationvelocities, as comparedto the localTully- 1 Fisher relation. In this analysis, we assume no slope evolution, and take into accountsystematic differences v betweenlocalanddistantvelocityandluminositymeasurements.Ourresultisparticularlystrikingconsidering 1 theCl0024membershaveverystrongemissionlines,andlocalgalaxieswithsimilarHαequivalentwidthstend 7 to be overluminouson the Tully-Fisherrelation. Cl0024 Tully-Fisher residualsappear to be correlatedmost 6 1 stronglywithgalaxyrotationvelocities,indicatingapossiblechangeintheslopeoftheTully-Fisherrelation. 0 However,wecautionthatthisresultmaybestronglyaffectedbymagnitudeselectionandbytheoriginalslope 6 assumed for the analysis. Cl0024 residuals also depend weakly on color, emission line strength and extent, 0 andphotometricasymmetry. InacomparisonofstellarandgasmotionsintwoCl0024members,wefindno / evidenceforcounter-rotatingstarsandgas,anexpectedsignatureofmergers. h p Subjectheadings:galaxies:clusters:individual(Cl0024+1654)—galaxies:evolution—galaxies:fundamen- - talparameters—galaxies:kinematicsanddynamics o r st 1. INTRODUCTION brighteningatz∼0.25- 0.6.Thesetwostudies,however,also a hintthattheremaybeachangeinTFRslopewithredshift. The Tully-Fisher relation (TFR, Tully & Fisher 1977) be- : v tween disk galaxy luminosities and rotational velocities is Recentstudiesusinglargersamplesoffieldgalaxies(≥60 i an essential diagnostic of galaxy evolution. By comparing compared to sample sizes of .20 in the studies mentioned X above)by Ziegler et al. (2002)and Böhm et al. (2004)have galaxyevolutionmodelstoTFRobservationsatz∼0through r provided further evidence for evolution in TFR slope, pos- a z ∼ 1, it is possible to probe dark matter halo properties sibly reconciling previous findings. More specifically, their and galaxy star formation histories (e.g., Mo & Mao 2000; work indicates that the mass-to-lightratios of the least mas- Navarro&Steinmetz2000;Ferreras&Silk2001;Buchalter, sivegalaxiesevolvemoststrongly.Theseauthorsattributethe Jimenez&Kamionkowski2001a,2001b;Mo&Mao2004). differing results of previous studies to selection effects and Observations of the distant field galaxy TFR have clearly small sample sizes. Their results are consistent with kine- demonstrated luminosity evolution since z ∼ 1, but the matic studies of blue compact galaxies at z≤1 (Koo et al. amountof evolutionis contested. Forbeset al. (1996), Vogt 1995, 1997; Phillips et al. 1997; Guzmán et al. 1996, 1997, et al. (1996, 1997) and Rigopoulou et al. (2002) find ≤1 1998). The latter studies demonstrate that distant compact mag brightening between z ∼0 and z∼ 1, whereas Rix et galaxies are overluminousas compared to the local TFR, in al.(1997)findevidencefor1.5magbrighteningatz∼0.25. manycasesanorderofmagnitudelessmassivethanexpected Inagreementwith thelatter work, Simard&Pritchet(1998) fortheirluminosities. andMallén-Ornelasetal.(1999)findevidencefor1.5–2mag While the work done to date is promising, there are still 1BasedonobservationsobtainedattheW.M.KeckObservatory,whichis waysin which distantTully-Fisherstudiescan be improved. operatedjointlybytheCaliforniaInstituteofTechnologyandtheUniversity For instance, selection effects are thought to be responsible ofCalifornia. for the differing results of some of the studies mentioned 2BasedinpartonobservationswiththeNASA/ESAHubbleSpaceTele- above.However,whileeffectssuchasmagnitudeincomplete- scope,obtainedattheSpaceTelescopeScienceInstitute,whichisoperated ness have been exploredin local studies (e.g. Willick 1994, bytheAssociation ofUniversities forResearch inAstronomy, Inc., under NASAcontractNAS5-26555. Giovanellietal. 1997),little workhasyetbeen donetoward 3NSFAstronomyandAstrophysicsPostdoctoralFellow quantifyingandcorrectingforsucheffectsondistantsamples. Electronicaddress:[email protected],[email protected] Furthermore,thevelocitymeasurementtechniquesusedinlo- Electronicaddress:[email protected] Electronicaddress:[email protected] cal and distant Tully-Fisher studies are often very different 2 Metevieretal. andmayaccountforsomeofthediscrepanciesbetweenpre- as to which processes are dominant. As a first step, we viousresults.AuthorsofdistantTully-Fisherstudiesalsotend havechosentostudytheTFRinrichclusterCl0024+1654at tocomparetheirsamplestotherelativelysmalllocalsample z=0.4,whereevolutionaryprocessesareverylikelytobeap- of Pierce & Tully (1992) to draw evolutionary conclusions. parent. Ingeneral,morphological,luminosity,andcolorevo- Whilethisisagoodstartingpoint,largerandbetter-calibrated lutionhavealreadybeenseeninclustergalaxiessincez≃0.5 localsamplesnowexistforcomparison(e.g.,Tully&Pierce (e.g., Dressler et al. 1997, Jrgensenet al. 1999, and Butcher 2000;Kannappan,Fabricant&Franx2002). & Oemler 1984, respectively). The redshift of this cluster Wealsonotethatwhilesignificantrecentprogresshasbeen aloneplacesitatanepochwherewewouldexpecttoobserve made investigatingthe evolutionof the Tully-Fisherrelation evolutionarysignatures. Cl0024was one of the two clusters inthefield,TFRevolutionintheclusterenvironmentisonly originallystudiedbyButcher&Oemler(1978)andthushas beginning to be explored. Many physical processes are ex- longbeenknowntohaveahighfractionofblue,presumably pectedtoaffectgalaxiesinthisdenseenvironment,including star-formingmembers.Furthermore,evidencehasbeenfound tidal encounters, interactions with the intracluster medium, for evolutionary processes such as mergers (Lavery, Pierce, andgroupinfall.Alloftheseprocessesarepredictedtoaffect & McClure 1992)and recentsubcluster infall (Czoske et al. cluster galaxydisks andgas, andin particulartheir mass-to- 2002). lightratios,thusaffectingtheTFR. Thestructureofthispaperrunsasfollows: inthenextsec- As a specific example, high-velocity tidal encounters be- tion, we discuss our observations of Cl0024+1654 and our tweenclustergalaxiesandwith thegravitationalpotentialof sample selection for this study. Note that our sample of 15 theclusteritself(“harassment")havebeenmodeledbyMoore Cl0024 members is one of the largest samples of rotation et al. (1996, 1998, 1999). These encountersare expectedto curvespresentedthusfarforgalaxieswithinasinglez>0.2 increasestarformationrateswhilestrippinggalaxiesofasig- cluster. We detail our basic spectral and image reductions, nificantfraction of their mass (Fujita 1998), thus decreasing two methods of rotation curve analysis, and we discuss the theirmass-to-lightratios. Gnedin(2003)predictsthatlower- differences between local and distant galaxy velocity mea- density galaxies in clusters are more likely to be disrupted surementsin §3. In §4, we present the Cl0024 Tully-Fisher andloseagreaterpercentageofmassintidalencountersthan relation, including a comparison to three local samples. In largespirals. Themass-to-lightratiosoflow-andhigh-mass §5,wediscussevolutionaryindicationsfromcorrelationsbe- galaxiesin clusters may therefore evolve differently. In dis- tweenTully-Fisherresidualsandothergalaxyproperties. We tantgalaxyclusters,wehavetheopportunitytoobservesuch alsotakealookattheeffectofmagnitudeincompletenesson evolutionaryprocessesinaction. DistantclusterTully-Fisher ouranalysis. We presentourconclusionsin §6. Throughout studies will therefore allow us to test model predictionsand this paper we assume H =70 km s- 1 Mpc- 1, Ω =0.3 and 0 M quantifyevolutionaryeffects. ΩΛ=0.7. Usingthiscosmology,onearcsecondcorresponds Few studies of the Tully-Fisher relation in distant clusters to5.332kpc. WepresentallphotometryintheVegasystem. currently exist. While studies of z∼0.1 clusters have been conductedwith significant sample sizes (>50 galaxies; e.g., 2. OBSERVATIONSANDSAMPLESELECTION Rubin et al. 1999, Dale & Uson 2003), kinematics of few Spectra of all galaxies presented in this paper were taken z>0.1 cluster disks have been measured. In a pioneering as part of a larger spectral survey of Cl0024+1654 (Mete- study, Vogt et al. (1993) measured the rotation velocities of vier et al., in preparation). Survey observations were made two cluster galaxies at z=0.20 and z=0.38. Franx (1993) in September 1995, September 1997, and September 2001 alsodemonstratedrotationinan“E+A"galaxyinAbell665at with the Low Resolution Imaging Spectrograph (LRIS, Oke z=0.18. Allthreeobjectswerefoundtobe≤1magbrighter etal. 1995)ontheKeck10-mTelescopes. AllCl0024spec- thanlocaldiskgalaxies. traweretakenthroughmulti-objectslitmaskswithslitwidths More recently, Milvang-Jensen et al. (2003) analyzed the of 0.9- 1′′. A variety of gratings (400, 600, 900, and 1200 rotation curves of eight members of cluster MS1054-03 at lines/mm)andsettingswereusedsuchthatdispersionsrange z=0.83and foundthat theywere ∼1.5mag more luminous from0.65- 1.85Åpixel- 1 (correspondingto∼30-80kms- 1 thanlocalfieldgalaxies.Bamfordetal.(2005)haveexpanded pixel- 1), and wavelength ranges cover at least Hα (9155Å, this study with a larger sample size of 22 members of three clusters at 0.3<z<0.9. They have found that the cluster observed)throughHβ (6780Å,observed)and in some cases membersaresomewhat(∼0.5mag)moreluminousthanfield [OII] (5200Å, observed) at the cluster redshift. The spatial galaxiesatthesameredshifts.Ontheotherhand,Ziegleretal. resolutionofallspectrainoursurveyis0.215′′pixel- 1. See- (2003;seeJägeretal.2004fordetailsonanalysistechniques), ingrangedfrom∼0.65- 1′′ FWHM, andinstrumentalreso- presented rotationcurvesof 13 membersof three clusters at lution ran from 1.0 to 2.9 Å FWHM (40 to 120 km s- 1). In 0.3<z<0.5andfoundnoevidenceforluminosityevolution manycases,slitswereapproximatelyalignedwithgalaxyma- ofclustergalaxieswithrespecttothefield. Otherthanthese joraxes. Slitmisalignmentshavebeenexplicitlyincludedin noteableexceptions,themajorityofkinematicstudiesindis- ourrotationcurveanalysis. tantclustershavefocusedonthefundamentalplaneofearly- ArchivalHubbleSpaceTelescope(HST)imagesofCl0024 typegalaxies. Theseworksindicatethattheamountoflumi- weretakenwithWFPC2aspartoftwoprograms.Deepimag- nosityevolutioninclusterearly-typesisconsistentwithpas- ingofasinglepointingatthecenteroftheclusterwastaken siveevolutionouttoz=0.83(vanDokkum&Franx1996;van (proposal 5453, PI Turner) to study the mass of the cluster Dokkumetal.1998;Kelsonetal.1997,2000a,b;Jrgensenet via strong lensing. Exposure times are 25.2 ksec and 19.8 al. 1999)andpossiblyoutto z=1.27(vanDokkum& Stan- ksec in B and I , respectively. More recently, shallower 450 814 ford2003). (4.0-4.4ksec)imagesoftheouterregionsoftheclusterhave As described above, environmentally-dependent physical been taken in I (proposal8559, PI Ellis) for a weak lens- 814 processes are expected to affect cluster disks more strongly ing study. The latter program provides imaging of 39 non- thanearly-types. Thedistantcluster TFRmayprovideclues contiguouspointingscoveringacircleofradius∼15arcmin, TFRinCl0024atz=0.4 3 withafillingfactorofapproximately50%. telescopeelevationand azimuthaswere usedduringthe ob- DiscrepanciesbetweentheresultsofTully-Fisherstudiesof jectexposuresinordertoreproduceandcombattheeffectsof distantfieldgalaxieshavegenerallybeenattributedtodiffer- fringing.Theresultingcombinedflatswereusedtocorrectfor ent sample selections. We have imposed very few selection pixel-to-pixelvariationsintwodimensions. Alongthelength criteria here: we have restricted our Tully-Fisher sample to of the slit, the flats were also used to correct for instrumen- emissionlineclustermemberswith0.37<z<0.41,andwe tal distortions and variationsin slit width. We then rectified have required that the galaxies in this sample lie within the thespectrainthespatialdirectionandwavelengthcalibrated HST-imaged region of the cluster. High-resolution WFPC2 against arc lamp exposures and known night sky lines. We imagesareessentialtoourstructuralanalysisforgalaxydisk sky-subtracted the resulting spectra, then co-added multiple sizes, inclinations, and position angles. In turn, these mea- exposures, accounting for sub-pixel offsets in the spatial di- surements are crucial for kinematic analysis. We have also rection.Finally,wemaderedshiftmeasurementsusingcross- requireddiskinclinationanglesrangebetween30◦<i<80◦. correlationsoftwaredevelopedbycoauthorA.C.Phillips. These simple selection criteria narrowedthe originalsample We obtained pipeline-processed WFPC2 images from the of 312totalobjectsin oursurveyto 44 clustermemberseli- Canadian Astronomy Data Centre archive service. Remain- gibleforTully-Fisheranalysis. Note thatwe havenotinten- ingreductionconsistedofcosmicrayremovalandstructural tionallyimposedselectionbasedoncolors,morphologies,or modelingofgalaxiesintheimages. Toremovecosmicrays, emissionlinestrengths. wecombinedexposuresoftheclustercore,whichweretaken Only15ofthe44objectsinourTully-Fisher-eligiblesam- withnooffsets. Exposuresoftheouterregionsofthecluster ple have extended, high signal-to-noise emission lines such had subpixel offsets and were therefore individually treated thatwe wereableto measurea reliableterminalrotationve- using the LACOSMIC routine (van Dokkum 2001). We fit locity. Thislowsuccessrateimposesadditionalselectionon a two-dimensional deVaucouleurs bulge + exponential disk top of the criteria described above. We explore these selec- modeltoeachgalaxyusingGIM2D(Simardetal.2002).This tioneffectsfurtherinFigure1,wherewecomparetheRmag- analysisprovidedgalaxybulge-to-totalfluxratios(B/Ts)and nitudes, B- R colors, morphologicaltypes (from Treu et al. disk inclinations, scale lengths, and position angles. These 2003),bulge-to-totalfluxratios(B/T),anddiskscalelengths measurementsarenotedinTable3. ofgalaxiesintheTully-Fisherandlargerclustersamples. In addition, in Figure 2, we present the distributions of emis- 3.2. RotationCurveAnalysis sion line extents and projected cluster-centric distances for Measuring the rotation velocities of distant galaxies from the galaxies in the final Tully-Fisher sample (15 galaxies) optical spectra is a challenging undertaking which requires andtheTully-Fisher-eligiblesample(44galaxies). Emission comparisonofemissionlinedatatoemissionlinemodels. In lineextentsweremeasuredinthespatialdirectionalongeach part this is because by z∼0.4, the size of a typical galaxy galaxy’sspectrumfromthetoptothebottomofthegalaxy’s (∼1′′)isroughlyequivalenttothesizeoftheseeingdiskand emission,assomegalaxiesdonotexhibitsymmetricemission theslitwidth. Therefore,lightandvelocityinformationfrom aboutthegalaxycentroid. Weestimatethattheerrorsonthe asubstantialfractionofagalaxyaregatheredinitsspectrum. extentmeasurementsareontheorderofonepixel(∼0.215′′). The resulting rotation curve is far from the optimal narrow InTables1and2,wequantifythemeanvalues,standarddevi- slicedownthegalaxymajoraxisacquiredinlongslitstudies ations,minimumandmaximumvaluesofthecomparedprop- of nearby galaxies. Below we provide a more complete list ertiesforthedifferentgalaxysamples. of factors one must consider when converting raw emission In general, we find that the galaxies in our Tully-Fisher linemeasurementsintomaximumdiskrotationvelocitiesfor samplearerelativelybrightandblueascomparedtotheother distantgalaxies: emission-line cluster members and the total cluster sample. Furthermore,theytendtobelarge,late-type,disk-dominated 1. Spatialdistributionofobservablegalaxyemission systems. GalaxiesinthefinalTully-FisherandTully-Fisher- eligible samples are similarly distributed within the cluster. 2. Velocitydistributionofobservablegalaxyemission However, galaxiesin the final sample have the largest emis- sion line extents. We are therefore mindful of the fact that 3. Inclinationofthedisk Cl0024 members with suppressed or centrally concentrated 4. Seeingblurringoftheobservedvelocitydistribution star formation, perhaps due to physicalprocesses within the cluster, are likely not included in our Tully-Fisher study. In 5. Instrumental blurring of observed emission due to in- Table3,wegivebasicdataforthefinalsampleof15Cl0024 strumentoptics memberswithreliablerotationcurvemeasurements. 3. DATAREDUCTIONANDANALYSIS 6. Slitwidthwithrespecttothesizeofthegalaxy 3.1. SpectralandImageReduction 7. Slit position angle with respect to the galaxy semi- WereducedallLRISspectrausingPythonmodulesdevel- majoraxis opedbyD.Kelson(seeKelsonetal.2000,Kelson2003). To prepare the spectra for this reduction, we performed over- 8. Slitpositionwithrespecttothegalaxycenter scan subtraction using standard IRAF procedures, and we 9. Anamorphicde-magnificationinthespectraldirection cosmic ray reduced the frames with a task written by coau- thor L. Simard. Using Python modules, each spectrum and 10. Pixelizationoftheobservedemissionline domeflatwasrectifiedinthedispersiondirectiontoaccount for “pincushion"-shaped distortion introduced by LRIS op- 11. Atmosphericdispersion tics. Wethencombineddomeflatfields;domeflatsfromtwo ofthethreerunsweretakenwiththesamegratinganglesand 12. Thicknessofthedisk 4 Metevieretal. 13. Presenceofbulge,bar,warps for factors 3 through 10. Through the implementation dis- cussedin§3.2.3,atmosphericdispersion(factor11)canalso Previousstudiesofdistantgalaxieshavemainlyusedoneof beaccountedfor. Wenotethatdiskthickness(factor12)has two techniques for deriving velocities from rotation curves. not been incorporated in rotation curve analysis techniques These two techniques are 1) comparison of velocity mea- presentedpreviouslyintheliterature,norisitconsideredhere. surements from Gaussian fits to observed and model emis- Similarly,theeffectsofabulge,bar,andwarpshavenotbeen sionlinesatseveralspatiallocations(Vogtetal.1996,1997; incorporated in distant galaxy rotation curve analysis. An- Rigopoulou et al. 2002; Ziegler et al. 2002, 2003; Böhm et other improvement that could be made in the future is the al.2004;Jägeretal.2004),and2)directcomparisonoftwo- direct use of color images to model emission line intensity dimensionalinformationfromobservedand simulatedemis- distribution,ratherthantheassumptionofanexponentialdis- sionlines(Simard&Pritchet1998,1999;Milvang-Jensenet tribution. al. 2003; Bamford et al. 2005). We have implemented both analysismethodsinourstudyofCl0024members;belowwe 3.2.1. GAUSS2D refertoourversionofmethod1asGAUSS2Dandourimple- OurGAUSS2D velocityanalysisfollowsthe methodused mentationofmethod2asGELFIT2D. byVogtetal.(1996,1997),Rigopoulouetal.(2002),Ziegler Both of our analysis techniquesrely upon the same emis- etal.(2002,2003),Böhmetal.(2004),andJägeretal.(2004). sionlinemodelingroutine. Theroutinewehaveadoptedas- We determined raw velocity measurements by fitting Gaus- sumesaninfinitelythin,rounddiskgalaxywithnobulge,bar, sianprofilesto thestrongestobservedemissionlinesateach orwarps. Thismodelgalaxyhasa truncatedexponentialin- rowalongthe slit. These fits providedGaussian amplitudes, tensityprofileandasymmetric“stepfunction"(e.g.,Persic& centers, widths, and linear background measurements, with Salucci 1991) or an arctangent (e.g., Willick 1999) velocity errors on each of the measurements. Fits were required to distribution. We found that both velocity functions yielded meetcertaincriteriachosentothrowoutnoisepeaksormea- similar rotation velocity measurements (generally within 10 surementswithunreliableS/N.Thesecriteriawere:Gaussian kms- 1)foroursample. We thereforehavechosentousethe amplitude>10 counts, center >2σ in significance, and 1Å arctangentfunctionforthispaper: < FWHM < 20Å. Gaussian centers were converted to ve- 2V r locitiesandwererequiredtodiffernomorethan100kms- 1 V(r)= arcarctan( ) (1) from one of the neighboringmeasurements. Generally, sev- π r to eralemissionlineswerefitforeachobject(doubleGaussians whereVarc is the asymptotic rotation velocity, and rto is the werefitto[OII]),andtheresultingvelocityinformationwas “turnover"radiuswhichdefinestheslopeoftheinnerveloc- converted to a single weighted mean and error at each row itycurve. Wenotethatmoreelaborateempiricaldescriptions alongtheslit. of galaxyvelocity distributionsmay better fit observedrota- To determine the rotation velocities of the galaxies in our tioncurves(see,e.g.,Courteau’s1997studyofnearbygalax- sample,weappliedthesameGaussianfittingtoemissionlines ies). Theyalsointroducenewparameterstobemodeledand modeledwithagridofV andr values.Gridswereinitially arc to thereforeweneglectthemhere. implementedwithV rangingbetween50and450kms- 1in arc Our emission line modeling routine first samples the as- 50km s- 1 increments, andwith r rangingbetween0.1 and to sumedintensityandvelocitydistributionsaccordingtoagrid 0.5′′ in 0.1′′ increments. We comparedobserved and model sizespecifiedbytheuser. Inordertosampleatleast10times velocity distributions to create corresponding χ2 grids, then acrosseachgalaxy,wegenerallysubsampledabovethereso- interpolated to determine the optimal V and r measure- arc to lutionofourmodeldataaccordingtothefollowingprescrip- ments (corresponding to the minimum χ2) with 68% confi- tion,wherepixscaleisthespatialpixelscaleofourdata,rd is dence intervals. This process was then repeated with more thediskscalelength,andiisthegalaxy’sinclination: refinedgridsforeachgalaxysuchthatV valuesweretested arc in increments of 10 km s- 1, and r in increments of 0.05′′. pixscale∗5 to subsamplingfactor= (2) Forsimplicity, we assumedmodelgalaxieswere centeredin r ∗cos(i) d theslitwhenusingthismethod. The routine then convolvesthe modelgalaxy’slightand ve- Incomparisonwithpreviousimplementationsofthisanal- locity profiles with a circular Gaussian seeing disk with a ysis method, our version incorporates some improvements. givenFWHM.Theseeing-degradedmodelgalaxyismasked Theemissionlinemodelsweusefullytakeintoaccountfac- withaslit,takingintoaccounttheslitwidthaswellasthepo- tors 3 – 7 and 9 – 10 above; it is unclear whether previous sitionangledifferencebetweentheslitandgalaxymajoraxis. authorshaveconsideredanamorphicmagnification(9)orpix- Thesubpixelpositionofthegalaxycenterwithrespecttothe elization (10) in their models. Furthermore, GAUSS2D al- centeroftheslitcanalsobeaccountedfor(asinGELFIT2D, lows the option of simultaneously fitting multiple emission §3.2.2)by varyingthe positionof the modelgalaxywith re- linesforagivengalaxy.Optimizationofthemeasuredveloc- specttothemodelslitmask. Themodelgalaxyisthencom- ity and confidence intervals are determined using a χ2 grid. pressedinthespatialdirectionduetotheinstrumentanamor- We estimated further contributions to errors by varying the phic factor and further convolved with a circular Gaussian followingfourparameters:diskinclinationandPAwereeach representing blurring from instrumental optics. The result- variedby±10◦,theseeingFWHMby±0.2′′,andtheinstru- inglightandvelocityprofilesare rebinnedandresampledto mentalprofileFWHMby±0.25pixels. Weaddedthelargest create a model emission line matching the resolution of the rangeof errorsdeterminedby varyingthese four parameters user’sdata. in quadrature with the formal fitting errors on our original In short, while our emission line modeling routine makes measurements to derive a final set of errors on ourV and arc somesimplifyingassumptionsabouttheintensityandveloc- r measurements. We note that previousstudies (e.g., Vogt to itydistributionsofemissionwithinagalaxy(items1and2on 1996,1997)haveonlytakenintoaccounterrorsduetoestima- our list of modeling considerationsabove), it fully accounts tionofthe inclinationandpositionangle, beyondthe formal TFRinCl0024atz=0.4 5 fittingerrors. signal-to-noisedata.Theoptimizationalgorithmemployedin GELFIT2Dhasalso beenusedinthegalaxystructuralmod- 3.2.2. GELFIT2D eling routine GIM2D; see Simard et al. (2002)for more de- Our second rotation curve analysis method is very simi- tails. GELFIT2Doutputsalogfilespecifyingbest-fitparam- lar to the ELFIT2D analysis described in detail by Simard eter values with errors as well as a thumbnail image of the & Pritchet (1999) and used by Simard & Pritchet (1998), best-fit model emission line and a residual (data – best-fit Milvang-Jensen et al. (2003), and Bamford et al. (2005). A model) image. Since GELFIT2D does not allow for simul- Metropolisoptimizationwrapperwasappliedtoouremission taneousfittingofmultipleemissionlines,wefitseverallines modeling routine in order to directly compare observed and separately for each galaxy, then took the weighted mean as modeledemissionlines, varymodeledparametersanddeter- our final GELFIT2D velocity measurement. We determined minebest-fitvalues. (Seebelowforamoredetaileddescrip- contributionsto the errorson ourV and r measurements arc to tionofthisoptimizationmethod.) by varying disk inclinations and PAs, as well as the seeing Specifically, this routine takes the following inputs: 1) a andinstrumentalFWHMs,andaddingthelargestrangeofre- two-dimensionalsky-andcontinuum-subtractedgalaxyemis- sulting errors in quadrature with the formal weighted errors sionline“thumbnailimage";2)aninitialguessandrangeof from our original measurements, as described at the end of possiblevaluesforeachmodeledparameter;3)alistoffixed §3.2.1. parameter values. Fixed parameters include the type of ve- Ourimplementationof GELFIT2Dincorporatessome im- locityfieldtobeusedintheemissionlinemodels(arctangent provementsover the similar ELFIT2D routine. Specifically, orstepfunction),seeingFWHM,observedwavelengthofthe GELFIT2D accounts for considerations3 – 10 on our mod- emission line, an optionalsecond observed wavelength (e.g. eling list, and provides some further flexibility in our as- to be used in modeling the [O II] doublet), galaxy inclina- sumptionsregardingconsideration1byallowingforacentral tion,positionanglebetweentheslitandgalaxymajoraxis,slit holeintheemissionintensitydistribution.GELFIT2D,unlike width,dispersion,spatialpixelscale,instrumentalFWHM,a ELFIT2D,explicitlytakesintoaccountthepositionangleoff- subsamplingfactortoaccountforpixelization,asigmavalue setbetweentheslitandgalaxymajoraxisaswellaspossible describingthenoiseinthethumbnailimagebackground,and offsets of the slit center with respect to the galaxy centroid. theCCDgain. However,wenotethatELFIT2Ddoeshavesomeadvantages GELFIT2Dthenoptimizesthefollowingeightparameters: overGELFIT2D,themostnoteablebeingtheoptiontospec- V ; r ; r , the emission line scale length; r , the in- ify an empirical seeing PSF and instrumental profile rather arc to em hole ner truncation radius (assuming a central hole in emission, thanassumingcircularGaussianprofiles. e.g.dueto dustextinction);offsetsofthegalaxycenterwith 3.2.3. Comparisonofanalysismethods respect to the input thumbnail image of emisson along and acrosstheslit(canbesubpixel);andtheoffsetoftheslitwith Imagesandtwo-dimensionalemissionlines,aswellasout- respecttothecenterofthethumbnailinthedispersiondirec- put from both of our rotation curve analysis techniques are tion. Inthecaseof[OII]emission,thefluxratiobetweenthe showninFigure3.GAUSS2DandGELFIT2Dsharethesame twolinesintheobserveddoubletisalsomodeled. emission line modeling routine and are therefore not com- Tostartthe model,aninitialgridofparameterswithinthe pletely independent. However, they differ in two significant user-specified range of possible values is first created. The ways:1)theroutinesusedifferentmethodsforcomparingob- correspondingemission line models are comparedto the in- servedandmodelemissionlines,and2)theoptimizationrou- put data image by calculation of the likelihood function for tinesusedtoconvergeonabest-fitmodelaredifferent. Both each model. The mostlikely initial modelis then chosen as routines have advantages and disadvantages that may affect a starting point for optimization. The Metropolis algorithm ourmeasurements,andwelistthemhere. (Metropolis et al. 1953, Saha & Williams 1994) is used to OurGAUSS2Dfittingroutinehastwodistinctadvantages. refine the best-fit parameter values. This algorithm gener- Forone,itdependslittleonanyassumptionaboutthespatial ates random perturbationsabout the initial model parameter lightprofile of a galaxy in the determinationof the galaxy’s values. The size of these perturbations is controlled by the rotation velocity. In this routine, velocity measurementsare Metropolis“temperature":ifamodelishot,theperturbations madeseparatelyforeachspatialrow;thevelocityateachrow arelarge;ifthemodeliscold,smallperturbationsaretried.At isdeterminedfromthecenterofaGaussianfittothegalaxy’s eachiteration,thelikelihoodthatthenewsetofparameterval- emission along the dispersion direction. For the most part, uesis correct,P , iscalculated. Thislikelihoodis compared therelativeamplitudesofthe Gaussian peaksin eachspatial 1 tothatofthepreviousiteration,P . Thenewtrialisadopted rowdonotaffecttherelativevelocitymeasurements. Dueto 0 ifP >P . IfontheotherhandP <P ,thenewtrialisstill seeing blurring and the small pixel scale of our data, emis- 1 0 1 0 adoptedP /P ofthetime. Thisallowsthealgorithmtowalk sionseeninadjacentspatialrowsisnotentirelyindependent, 1 0 itselfoutoflocalχ2 minima,aparticularlyimportantfeature though. Agalaxy’slightprofilecouldthereforehaveasmall for low signal-to-noise data. Furthermore, the shallower the effectontheresultingvelocitymeasurements. minimum,thehighertheprobabilitythatthemodelwillwalk A second advantage of this routine is that it concatenates itselfout. velocitymeasurementsfromauser-specifiednumberofemis- Convergenceisachievedwhenthedifferencebetweentwo sion lines for a given object before determining V . That arc likelihood values separated by 100 iterations is less than is, the emission lines can be fit together or separately. A 3σ of the likelihood value fluctuations. Once the Metropo- disadvantage of this method is that it assumes galaxy emis- lis algorithm converges, GELFIT2D determines 68% con- sionprofilesareGaussianalongthedispersiondirection.This fidence intervals by Monte-Carlo sampling the parameter doesnotnecessarilyreflectthetrueemissiondistributionand space where the likelihood has been maximized. In other maybiasvelocitymeasurements,astheyarederivedfromthe words, GELFIT2D does not assume that confidence inter- Gaussian-fitcentersoftheemission.Furthermore,thisroutine valsareGaussian. Thisisagainimportantinthecaseoflow simplydoesnottakefulladvantageofthetwodimensionsof 6 Metevieretal. informationavailablefromaspectrum. McClure(1992;hereafterLPM92)andlinewidthsweremea- GELFIT2D is a much simpler fitting routine in that it di- suredbyKooetal.(1997).Thesearetheonlythreeobjectsin rectly compares data to emission line models, without any oursamplethatoverlapwiththeLPM92andKooetal.stud- intermediate (e.g., Gaussian fitting) steps. GELFIT2D fits ies. Oneoftheseobjects(TFR10)appearstocontainalarge, a larger number of parameters than the GAUSS2D routine, knottyringofemission. LPM92describethisgalaxyashav- providing additional measurements. These include the off- ing a “disturbed" morphology. This is the largest and most set of a galaxy within a slit, the radius within which emis- rapidly rotating galaxyin our sample, and its velocity curve sion is truncated at the center of a galaxy, the emission line appears to turn over at large radii. The morphological and scalelength,andthefluxratioofthe[OII]doublet. Further- kinematic distortion in this galaxy indicate that it may have more,GELFIT2Dhasamuchmoresophisticatedmethodfor undergonea recentinteraction. Kooet al. reporta linewidth parameter optimization than GAUSS2D. While GELFIT2D σ=120kms- 1forthisobject,wherehereσreferstothestan- only runs on one emission line at a time, a possible benefit darddeviationmeasuredbyfittingaGaussiantothespatially isindependentmodelingofthepositionofthegalaxywithin collapsed (one-dimensional)emission. We measure a Gaus- theslitatredandbluewavelengths,indirectlyallowingusto sian σ =115 km s- 1 for TFR 10 but findV =370 km s- 1. arc accountfor atmospheric dispersion (factor 11). It should be Wediscusspossiblesourcesforthedifferencesbetweenthese noted that GELFIT2D also has disadvantages, the main one measurementsbelow. being the assumption of a symmetric exponential intensity Theremainingtwo“unusual"objects(TFR04andTFR08) profile. This assumption can stronglyaffect resulting veloc- have odd morphologies poorly fit with our GIM2D bulge + itymeasurements,particularlyforgalaxieswithasymmetries, diskmodeling. Bothobjectshavesuchsteeplyrisingrotation spiralarms,and/orstar-forminghotspots. curves at their cores that a pure step function (r ≃0′′) ve- to Both routines take on average 15-20 minutes to run per locity distribution convolved with realistic seeing could not galaxy. GAUSS2D requires real-time user input ofV and reproducetheobservedvelocitycurve. Therefore,ourveloc- arc r ranges and increments to be tested. GELFIT2D is com- ity measurements appear to be overestimated. This is most to pletelyautomated,butoptimizeseightparametersratherthan clearly apparent in output from GAUSS2D (see Figure 3). two. Because GELFIT2D fits each emission line separately, Since the GELFIT2D velocity measurements closely match this routine may take longer if a large number of lines are thosefromGAUSS2D,weassumetheyareoverestimatedas fit. Run-times for both GAUSS2D and GELFIT2D are also well. AsinthecaseofTFR10,linewidthsmeasuredbyKoo dependent upon the amount of subsampling desired: highly et al. (1997)are significantly smaller (40 and 50 km s- 1 for inclinedgalaxieswilltakethelongesttorunbecausethesub- TFR04andTFR08,respectively)thanourV measurements arc samplingfactorwillbelargest. (120and135kms- 1).However,wemeasuresimilarGaussian For ease of comparison,in Table 4 we againlist the mod- linewidths of 75 and 40 km s- 1 for the two objects, gener- eling factors described in §3.2. We also describe how and allyinagreementwithKooetal. Bothoftheseobjectswere whether we have taken them into account using GAUSS2D flaggedas probablemergers/interactinggalaxiesby LPM92; and GELFIT2D. In Table 5, we list velocity measurements weconsiderthemtidallydistorted. for our sample of 15 Cl0024 members determined via both Inthethreecaseswhereoursamplesoverlap(TFR04,TFR routines. Ingeneral,wefindthatthetwomethodsyieldgrat- 08,andTFR10),ourV measurementsaremuchlargerthan arc ifyinglysimilar results, as can be seen in Figure 4. We note thevelocitywidthsmeasuredbyKooetal.(1997)fromspa- thatin all cases, emission was measuredoutto radiibeyond tiallycollapsedemission.Thisisdueinparttoinherentdiffer- 2.2r , the radius at which local galaxy studies often deter- encesbetweenthemeasurementtechniques.Emissiontoward d mine rotation velocities (e.g., Courteau 1997). Objects with theouterregionsofagalaxy(wherevelocitiesareoftenhigh- truncated emission were not eliminated directly because of est) is given more weight in rotation curve analysis than in the small extentof their emission, but becausethe turnovers linewidthanalysis,wheretheemissionsignatureiscollapsed intheirvelocitydistributionswerenotstrongenoughforusto intoonedimension.Furthermore,Kooetal.fitthelinewidths measureV .Ofcourse,thelattercriteriondoesbiasoursam- of the three galaxies in question with Gaussians despite the arc pletowardgalaxieswithlargeemissionlineextents(seeFig- fact that the velocity profiles of these galaxies are complex, ure 2). However, we note that some galaxieswith relatively exhibiting 2-3 local peaks. However, we again caution that largeemissionlineextentsdidnotmakeitintoourfinalTully ourV measurementsmaybeoverestimatedforthesegalax- arc Fisher sample because the signal-to-noisein the outskirts of ies,asTFR10exhibitsaturnoveratlargeradiinotaccounted theiremissionwastoolowforustoreliablymeasureV . for by our models, and TFR 04 and TFR 08 show possible arc non-circularmotions. 3.2.4. UnusualGalaxiesintheSample It is not surprising that a significant fraction of the galax- Four of the objects in our sample yieldedparticularly odd iesinourCl0024Tully-Fishersample(27%)exhibitunusual emissiondistributionsand/orpoorkinematicfits(seetheAp- kinematics. Norisitsurprisingthatthesegalaxieswererela- pendix for more notes on individual objects). One object tivelypoorlyfitbyourrotationcurveanalysisroutines. Sim- (TFR01)exhibitshigh-ionizationemissionlinescharacteris- ulations of the rotation curves of interacting galaxies (Bar- ticofanAGN(e.g.,[NeV]λ3426)andhasameasured[OII] ton,Bromley,&Geller1999)predictcomplicatedbumpsand flux ratio I(λ3729)/I(λ3726) = 0.4, indicating electron den- wiggles, and observations of close pairs in the nearby field sities over1000cm- 3. This emission is particularlyconcen- (Bartonetal.2001)revealasignificantfraction(∼10%)with tratedtowardthecenterofthegalaxy:wemeasureadiskscale centrally concentrated emission. In the nearby Virgo clus- lengthof1.1′′andanemissionscalelengthofonly0.2′′. We ter, ∼50% of the 89 galaxies studied by Rubin, Waterman, caution that the derivedrotation velocity may representmo- & Kenney(1999)exhibitkinematic disturbances. While the tionofgasinthegalaxycoreonly. scales of many of these disturbances are too small for us The other three objects are Butcher-Oemler “blue" galax- to observe at z=0.4, some general trends (such as velocity ieswhosemorphologieswereexaminedbyLavery,Pierce,& turnoversat large radii) can be apparent (as in TFR 10). In TFRinCl0024atz=0.4 7 their study of z∼0.4 cluster galaxies, Ziegler et al. (2003) outofourV measurements. Insteadweinclination-correct arc notethatfourofthe30diskgalaxiestheyobservedexhibited themeasurementsin laterstepsin orderto keeptheorderof peculiarkinematicsandweredifficulttomodel,sotheywere our procedure consistent with the methods used in the local notincludedintheauthors’Tully-Fisheranalysis. studies. Instep2,wehavecalibratedtheconversionbetween Anomalous kinematic signatures have been found in dis- V andV byanalyzingdatainCourteau(1997),inwhich arc pmm tant field galaxy studies as well. Rix et al. (1997) identify V and V measurements were made for the same sam- arc pmm ∼20%oftheirz∼0.25sampleaskinematicallyunusual,with ple of local galaxies. Using an iterative least-squares fit to low[OII]fluxratios. Furthermore,Simard&Pritchet(1998) Courteau’sdata,wefind: foundthat∼25%oftheirsampleshowedunusualkinematics, generally with emission line scale lengths smaller than disk 2Varc=0.80(±0.02)Vpmm+23(±10)kms- 1 (3) scalelengths. In Table 7, we list our originalV measurements for each arc 3.3. ComparingVelocityWidthMeasurements Cl0024clustermember,aswellasourderivedWRi andWVpmm values. Wenotethatwehaveroundedallvelocitymeasure- InthemajorityofliteratureonthedistantgalaxyTFR(in- ments to the nearest 5 km s- 1 to reflect the precision of our cludingourownearlyanalysisoftheCl0024TFR,Metevier data. & Koo 2004),authorsdirectlycomparethe luminositiesand velocities of galaxies in their distant samples to a locally- 3.4. GalaxyLuminosities derivedTFRwithoutaddressingdifferencesinvelocitymea- surement methods for distant and local galaxies. However, WemeasuredobservedtotalRmagnitudesand3′′diameter systematic differences do exist between different measure- apertureB- RcolorsfromLRISimagingoftheCl0024field ment methods. These have been discussed in several TFR (600sexposuresinbothBandR). Thisphotometrywasthen studiesatz.0.25(e.g.,Courteau1997;Raychaudhuryetal. correctedforGalacticextinctionintwowaysinordertocom- 1997; Rix et al. 1997; Barton et al. 2001; Kannappan, Fab- pareourmeasurementsdirectlytothoseusedintheliterature. ricant, & Franx2002). Inthissection, we describelocalve- One method was an application of the extinction correction locitymeasurementmethodsandwedetailourprocedurefor givenbyBurstein&Heiles(1982,hereafterBH82),acorrec- convertingourV measurementstovelocitywidthsthatcan tionof0.09maginRintheCl0024field,andacorrectionof arc bedirectlycomparedtolocally-derivedvalues. 0.15maginB. Theothermethodwasapplicationofthecor- In §4, we compare the Tully-Fisher relation in Cl0024 rection from Schlegel, Finkbeiner, & Davis (1998, hereafter to the TFR derived from three local galaxy samples: those SFD98),0.15maginR. studied by Pierce & Tully (1992, hereafter PT92); Tully & The observed photometry was converted to restframe to- Pierce(2000,hereafterTP00);andKannappan,Fabricant,& tal M magnitudesand aperture (U- B) colors by C. N. A. B 0 Franx(2002,hereafterKFF02). BothPT92andTP00derive Willmer.Theprocedurefordoingthisisdescribedindetailin velocity widths from 21cm observations. For each galaxy, Willmeretal.(2005)andbasicallyfollowsthesesteps:empir- they measureW , the line width at 20% of the peak inten- icaltemplatespectrafromKinneyetal.(1996)areredshifted 20 sity. Fromthistheyderiveaninclination-corrected“rotation totheclusterz,andtheresultingSEDsareconvolvedwiththe width”Wi by dividing by sin i and applying the turbulence knowntransmissioncurvesofourfilters,thencomparedwith R correctiongiveninTully&Fouqué(1985). the observed photometry. Restframe photometrywas calcu- KFF02 measure “probable min-max” rotation velocities latedfromthebest-fittingtemplatespectrumforeachgalaxy. fromopticalemissionlineobservations. The“probablemin- TheresultingrestframeM magnitudeswerethencorrected B max” velocity, V , is half the difference between (a) the forinternalextinctionusingtherelationsgivenineitherTully pmm velocitydeterminedtostatistically exceed90%oftheveloc- & Fouqué (1985, hereafter TF85) or in Tully et al. (1998, itiesinthegalaxy’srotationcurveand(b)thevelocitydeter- hereafter T98), dependingon the literature we comparedto. minedtostatisticallyexceedonly10%ofthevelocitiesinthe WenotethattheinternalextinctioncorrectionsgiveninTF85 rotationcurve. BothKFF02andRaychaudhuryetal. (1997) are inclination-dependent, whereas the corrections given in demonstratethatV isarobustmeasurementofagalaxy’s T98 are depend both on a galaxy’s inclination and intrinsic pmm velocity, in part because it does not rely on a particular ro- luminosity(orrotationvelocity,Wi). R tation curve shape. However, this method is difficult to ap- In all, we derived four sets of restframe M magnitudes B plytodistantgalaxies,forwhichonemustmodelseeing,slit, for comparison to the literature. (1) Mdist magnitudes were B and instrumental effects and therefore make some assump- derivedusingSFD98 Galactic extinctioncorrectionsandthe tionsabouttheshapeofagalaxy’sintrinsicvelocitydistribu- TF85 internal extinction corrections. This method follows tion. that used in recent distant TFR studies such as Ziegler et In order to directly compare to other local TFR studies, al. (2002,2003),Milvang-Jensenetal. (2003),andBöhm et KFF02 convert their V measurements to velocity widths al. (2004). (2) MPT92 magnitudeswere derived using BH82 pmm B equivalenttoW ,radiolinewidthsmeasuredat50%ofpeak Galacticextinctioncorrectionsandthe TF85internalextinc- 50 intensity. KFF02derivearelationshipbetweenV andW tioncorrections,forcomparisontoPierce&Tully(1992).(3) pmm 50 by directly comparing optical and radio observations of the MTP00magnitudeswerederivedusingSFD98Galacticextinc- B galaxiesintheirsample.TheyalsofindthatW =W - 20km tion corrections and the T98 internal extinction corrections, 50 20 s- 1 (see also Haynesetal. 1999). KFF02adoptthe nomem- for comparison to Tully & Pierce (2000). (4) MKFF02 mag- B clatureW to describe their W -equivalent velocity mea- nitudeswerederivedusingBH82Galacticextinctioncorrec- Vpmm 50 surementsderivedfromV . tions and the T98 internal extinction corrections, following pmm In Table 6, we list the simple steps we have taken to con- the method used by Kannappan, Fabricant, & Franx (2002). vert our V measurements to velocity widths equivalent to Inthislattercase, wecalculatedWi tobeappliedintheT98 arc R Wi andW forcomparisontoPT92,TP00,andKFF02.We internalextinctioncorrectionusingthemethodoutlinedinTa- R Vpmm note that in step 1, we have taken the inclination correction ble 6, but with steps 6 and 7 switched. In other words, the 8 Metevieretal. turbulencecorrectionwasappliedtotherotationvelocitybe- offsetoftheCl0024relationfromPT92,wefindthatCl0024 fore the inclination correction in this case only. This same members are in this case only 0.16±0.23 mag brighter on procedurewasadoptedbyKFF02. averagethanlocalgalaxies. Inotherwords,matchingourve- Theinternalextinctioncorrectionswehavederivedforeach locity and luminositymeasurementtechniquesto those used galaxyarenotedinTable8;absoluteM magnitudesandrest- byPT92haschangedourresultsby∼0.5mag. B frame (U- B) colors are in Table 7. Restframe colorshave We have also made “matched" comparisons to the more 0 been calculated using the BH82 Galactic extinction correc- recently-published local TF relations of TP00 and KFF02, tions (see above) and T98 internalextinction correctionsfor showninFigure5(c)and5(d).TheTP00sampleislargerthan comparisonto KFF02. Like KFF02, we use an extrapolated PT92, drawnfroma rangeofenvironments,andinternalex- internalextinctioncorrectionfortheU band(see equation3 tinctioncorrectionshavebeenimprovedinthisstudy. KFF02 intheirpaper). isalsoanimprovementuponPT92.Theirsamplecomesfrom the Nearby Field Galaxy Survey (NGFS, Jansen & Kannap- 4. THECL0024TULLY-FISHERRELATION pan2001),asampleoflocalgalaxieschosenwithoutprefer- WepresenttheBbandTully-Fisherrelationforoursample ence for morphology, color, size, environment, or any other of15Cl0024membersinFigure5. Ineachofthefourpanels galaxy property. Specifically, in Figure 5(d) we compare to ofthisfigure,wemakeadifferentcomparisonoftheCl0024 the subsample of Sa-Sd galaxies in KFF02 with M <- 18 R TFR to a local Tully-Fisherrelation. This was motivatedby and inclinations i>40◦. We note that we find a slight off- thefollowing: insomeofthe veryfirststudiesofthe distant set(∼0.2mag)betweentheTP00andKFF02localrelations. galaxyTFR, Vogt et al. (1996, 1997)comparedtheir results AsimilaroffsethasbeenfoundindependentlybyKannappan to the local relation of PT92. Since then, larger local sam- (privatecommunication;seealsoKFF02),confirmingthatour ples(suchasTP00andKFF02)havebeenbetteranalyzed,for velocityandluminositymeasurement“matching”isaccurate. example with improved internal extinction corrections, and If we assume uniform shifts from the local TF relations withsomewhatdifferentlocalTFRresults. However,theau- withnochangeinslopeordispersion,itisclearfromFigure thorsof more recentstudies of the distant galaxyTFR (e.g., 5 thatthe Cl0024sample appearsmarginallyunderluminous Milvang-Jensenet al. 2003, Ziegler et al. 2003, Böhm et al. ascomparedtobothTP00(<∆TF>=0.29±0.17mag)and 2004) have continued to compare to the local PT92 relation KFF02 (<∆TF> =0.50±0.23 mag; we note that the zero- so that their results can be more directly juxtaposed against point errors on the reference TP00 and KFF02 Tully-Fisher thoseofVogtetal. InFigure5,wecomparetoPT92forthe relationsare.0.1mag). Thisis somewhatsurprising,asal- same reasons, but we also compare to the local relations of mostallotherdistantTFRstudieshavefoundthatbyz∼0.25, TP00 and KFF02 in order to be more comprehensivein our galaxiesaresomewhatoverluminousascomparedtothelocal analysis. TFR (see the introduction of this paper for a list of exam- IneachpanelofFigure5,theinverseTully-Fisherrelation ples). However,ourresultsareconsistentwithPT92who,as (velocityasafunctionofluminosity)isshown:inmagnitude- notedabove,foundthatlocalclustergalaxiesare∼0.25mag limitedsamples,fittingtheinverserelationhelpstoavoidbi- lessluminousintheBbandthantheirlocalfieldcounterparts. asesduetoasymmetricfaint-endscatterinluminosities(e.g., Furthermore, Kannappan et al. (2003) found a slight under- Schechter 1980). In Figure 5(a), we present a “raw" com- luminositywhentheyre-analyzedthedistantfieldsampleof parisonbetweenthe Cl0024TFR andthe PT92 relation. By Vogtet al. (1997). Specifically, Kannappanet al. foundthat thiswemeanthatwedirectlycompareourV -Mdist relation this<z>∼0.5sampleis.0.5magunderluminousascom- arc B totheirWi-MPT92 relationwithoutaccountingfordifferences paredtogalaxiesintheNGFSwithsimilarrotationvelocities R B in velocitymeasurementtechniquesor for differencesin ex- andsimilarlylargeemissionlineequivalentwidths. Kannap- tinctioncorrectionsusedtocalculaterestframeBmagnitudes. panetal.suggestthatthismaybeduetoadecreaseinstellar This is the type of comparison commonly made in distant massfractionwithlookbacktime.Ourresultsnotonlyhintat galaxy TFR studies in order to deduce luminosity evolution suchanunderluminosity,butalsohighlighttheimportanceof results. the choice of comparisonsample for studies of Tully-Fisher Because our sample spans a limited range in luminosi- evolution, and of “matching" measurements in the resulting ties, we examine the Cl0024 TFR in Figure 5(a) assuming comparison. the slope determined by PT92. Using the biweight method As in distant field galaxy TFR studies, there has thus far (Beers, Flynn, & Gebhardt 1990), we determine an offset been some evidence for brighter cluster galaxies, relative to fromthePT92fieldrelationof<∆TF>=- 0.69±0.24mag. a given rotation velocity, in the past. Milvang-Jensen et al. Thevalueofthisoffsetremainsconsistenttowithin∼0.1mag (2003) studied 19 field spirals at 0.15<z<0.90 and eight whetherweusethetotalCl0024TFRsampleoronlytheob- members of cluster MS1054-03 at z = 0.83. By making a jectswith“normal"kinematics. WenotethatPT92measured “raw"comparisonoftheir fieldsample to thelocalPT92re- aBbandzeropointoffsetbetweenlocalclusterandfieldsam- lation, they determined a relation between galaxy redshifts ples,indicatingthatlocalclustergalaxiesare∼0.25magless and their offsets from the local TFR: ∆TF ≈ - 1.6z, assum- luminousinthisbandthangalaxiesinthenearbyfield. This ing H =75 km s- 1 Mpc- 1 and q =0.05. Convertingto our 0 0 would make our Cl0024 sample 0.94 mag brighter than the cosmology, they predict ∆TF =- 0.93 mag at z=0.4. Our PT92localclustersample. “raw" Cl0024 TFR, with ∆TF =- 0.69 mag, is slightly less However,thisresultmaybemisleading. Ifweconvertour luminousthantheirprediction. V measurementsforCl0024memberstoWi (see§3.3)and However, Milvang-Jensen et al. showed that their cluster arc R deriverestframeM usingthesameGalacticandinternalex- sampleissomewhat(∼0.5–1.0mag)brighterthantheirfield B tinctioncorrectionsasthoseusedbyPT92(see§3.4),wecan sampleatthe sameredshift. Theysuggestthatthisluminos- makea“matched",ratherthan“raw",comparisonofthedis- ity enhancementmay reflect increased star formationin spi- tant cluster TFR to the local relation. This “matched” com- rals falling into cluster MS1054 for the first time. More re- parison is shown in Figure 5(b). Recalculating the biweight cently, Bamford et al. (2005)have expandedthis study with TFRinCl0024atz=0.4 9 largerfield(58galaxies)andcluster(22galaxies)samplesand 5.1. TFResidualsandOtherFundamentalGalaxyProperties have derivedsimilar results. These results appear to contra- Severalauthors(e.g., Verheijen2001) have searched for a dictours,aswellasthoseofZiegleretal.(2003),whostudied “thirdparameter"totheTully-Fisherrelationforspiralgalax- theTFRfor13clustergalaxiesatz∼0.5andfoundnosignif- ies, analogous to the dependence of velocity dispersion and icantluminosityevolution. This mayreflect truedifferences surface brightness on galaxy size for early-types (known as betweenthespiralpopulationsofdifferentclustersand/ordif- thefundamentalplane, Djorgovski&Davis1987). Untilre- ferencesbetweenoursampleselectiontechniques. Inthefu- cently, no strong evidence has been given for a relationship ture, we intend to explore this apparent discrepancy with a betweenTully-Fisherresiduals(∆TF)andothergalaxyprop- largersample of severalhundredspirals spanninga rangeof erties.However,intheirstudyofnearbyfieldgalaxies,KFF02 environmentsintheGOODSfieldsandExtendedGrothStrip. haveshownthat∆TFandgalaxycolorsarecorrelated,reflect- SpectroscopyinthesefieldsisunderwayaspartoftheDEEP2 ing an influence from galaxy star formation histories. This Survey(Davisetal.2003)andtheTeamKeckTreasuryRed- finding is supported by a similar trend found in the nearby shiftSurvey(Wirthetal.2004). UrsaMajorclusterbyVerheijen(2001).Althoughthenumber ofgalaxiesinoursampleisrelativelysmall,weattempthere 5. DISCUSSIONOFTULLY-FISHERRESIDUALS to look for correlations between Tully-Fisher residuals and otherfundamentalgalaxypropertiesin Cl0024, in the hopes FromFigure5,onecanseethattheobservedscatterinthe that they may provide clues about evolutionaryprocesses in Cl0024 TFR spans the 3σ confidence intervals of the PT92 thecluster. andTP00localrelations. Furthermore,scatterintheCl0024 Inthefollowinganalysis,wedefine∆TFasthedifference TFR is comparable to that found by KFF02, whose sample betweenagalaxy’sobservedluminosityanditspredictedlu- is unusual in that it has not been “pruned” to include only minosity, derived from a comparison of its rotation velocity normalspirals. Increasedscatter in the Tully-Fisherrelation totheCl0024TFR(characterizedbyasimple0.50magoffset has been linked on the observational side to galaxy-galaxy fromtheKFF02relation): interactions (Barton et al. 2001). On the theoretical side, it hasbeenlinkedto theratioof darkto luminousmasswithin ∆TF(mag)=MKFF02- {- 19.83- 10.09[log(W )- 2.5]+0.50} B Vpmm galaxies of different luminosities (Salucci, Frenk, & Persic (4) 1993). Using the biweight technique and comparing to the We have determined errors on these TF residuals by adding KFF02relation, we findσTF =1.00magin theCl0024TFR ourphotometryerrors(0.15mag)inquadraturewith ourve- (objectswith“normal"kinematicsonly,σTF increasesabitto locity measurement errors, converted to magnitudes. Our 1.14magif we includethefullsample). Thisis comparable ∆TFmeasurementsarelistedinTable9. to but slightly larger than the 0.82 mag dispersion found by WediscussTFresidualsintermsofmagnitudesinthispa- KFF02. After accounting for photometry errors (0.15 mag) perin orderto compareto local Tully-Fisherresidualanaly- and errors on our velocity measurements (corresponding to sis (e.g., KFF02). However, we note that this can be prob- 0.42mag),wedeterminetheintrinsicCl0024σTF=0.90mag. lematic for distant Tully-Fisher studies, including our own, Thisissomewhatlargerthantheintrinsicscatter(σTF =0.57 whichhavesignificantluminosityselectioneffects. Infuture mag)measuredbyKFF02 in theB band, andismuchlarger studies,abettertreatmentofthedatawillbetodiscussveloc- thanthetotalscatter,includingmeasurementerrors,reported ity residualsfromthe Tully-Fisherrelationfor distantgalax- by PT92 (σTF =0.41 mag) and by TP00 (σTF =0.38 mag). ies. Therefore,inTable9wealsolisttheCl0024memberTF Below,weanalyzethisscatter,or“residuals”fromtheCl0024 residualsasvelocities,determinedbycomparingthegalaxies’ Tully-Fisherrelation,inmoredetail. luminositiestotheCl0024TFR: Beforepresentingthisanalysis,wenotethatauthorsoflo- cal Tully-Fisher studies (e.g., Courteau 1997, Willick 1999) ∆TF(kms- 1)=WVpmm- 10{[MBKFF02+19.83- 0.50]/- 10.09+2.5} (5) havefoundthatusingV insteadofV reducesscatterinthe 2.2 arc Again,weaddourphotometryerrors(convertedtovelocities) TFR. Here, V is the rotation velocity measured at 2.15r , 2.2 d andvelocityerrorsinquadraturetodeterminetheerrorsonthe where rd is the disk scale length; the radius 2.15rd corre- residuals. Wealsoroundthevelocityresidualstothenearest spondstothepointatwhichtherotationamplitudeofapure 5kms- 1toreflecttheprecisionofourdata. exponentialdiskreachesitsmaximum(e.g.,Freeman1970). Asatest,wehaveredeterminedtheCl0024TFRbycalculat- 5.1.1. Luminosity ingV for the cluster members, entering the measured val- 2.2 In Figure 6 (top panels), we compare TF residuals (∆TF) ues ofV , r , and 2.15r for each galaxy into equation(1) arc to d to the fundamentalparametersof the TFR itself: luminosity of this paper (see §3.2 for the equation and Tables 3 and 5 (MKFF02) and velocity(logW ). As can be seen in Figure for the measurements). Furthermore, we have redetermined 6(aB), there is no dependenceVpomfm∆TF on luminosity: using radio-equivalent velocity widths based on the V measure- 2.2 the Spearman rank test on the “normal” sample, we find a ments, replacing step 2 of Table 6 with a similar calibration 77%probabilitythatthecorrelationbetween∆TFandMKFF02 derived from the min-max velocities, arctangent velocities, B occurredbychance. Aformallinefittothissampleyieldsa andturnoverradiipresentedinCourteau(1997),andthedisk slopeof- 0.42±0.27,indicatingthatthedataareinconsistent scalelengthsgiveninCourteau(1996).WefindthatusingV 2.2 withthenullhypothesis(zeroslope,ornocorrelation)atonly doesreducethetotalscatterintheCl0024TFR,measuredas the1.6σlevel.WeshadetheleftsideofFigure6(a)toindicate a simple offset from the KFF02 relation, to 0.42 mag; this our selection bias against galaxies with M >- 19.5. Only is comparable to our measurement errors alone. However, B one galaxy fainter than this limit (TFR 08) has made it into the choice of V or V does not qualitatively change the arc 2.2 oursampleduetoitsverystrongemission. results of our Tully-Fisher analysis or our analysis of Tully- FisherresidualsinCl0024. Therefore,we continuewithour 5.1.2. Velocity TFresidualanalysisbasedonV measurements. arc 10 Metevieretal. Ontheotherhand,inFigure6(b),TFresidualsforoursam- lower” measuredTully-Fisher slopes with increasing disper- pleappeartobecorrelatedwithrotationvelocity(thechance sion. (We note that “shallower”Tully-Fisherslopes actually probabilityof the correlation is six in 10,000), such that the appearsteeperinourdiagrams,aswehaveplottedtheinverse most slowly rotating systems are most overluminous. Fur- Tully-Fisherrelationin Figures5 and 7.) This slope change thermore, our formalfit to the “normal” sample is inconsis- isinthesamedirectionasthatindicatedbyourowndataand tent with the null hypothesis at the 9σ level. This may in- measured in other distant Tully-Fisher studies (e.g., Ziegler dicateslopeevolutionoftheTFRandbeevidenceformass- etal. 2002,Böhmetal.2004). Anapparentslopechangein segregated luminosity evolution, a possible outcome of ha- thisdirectionduetomagnitudeincompletenesshasalsobeen rassment(e.g.,Gnedin2003). Indeed,ifwedonotassumea foundinthelocalstudiesofWillick(1994)andGiovanelliet localTully-FisherslopeinCl0024,wefindthataninversefit al.(1997).Inourcase,theselectionbiasresultsinanincreas- to the“normal”sampleshownin Figure5(d)yieldsa Tully- ingly prominent and steep correlation between velocity and Fisher slope of- 7.04±0.30as opposedto the KFF02 slope ∆TFwithincreasingdispersion.FromFigure7andTable10, of- 10.09±0.39.Evidenceforaslopechangeinthesamedi- weseethatanyTully-Fisherslopeevolutioninferredparticu- rectionhasalsobeenobservedinthefield(Simard&Pritchet larlyfromourlow-luminosityCl0024datapointsisstrongly 1998,Mallen-Ornelasetal. 1999,Ziegleret al. 2002,Böhm affected by magnitude incompleteness in combination with etal.2004),sothismaynotbespecifictotheclusterenviron- measurementerrorsandtheintrinsicdispersionofthegalax- ment. ies’properties.However,iftherewerenoslopeevolution,we Our sample is small and incomplete at low luminosities, wouldexpecttoseeaturn-offto∆TF=0atthehigh-velocity soweexplorehowmagnitudeselectionaffectsmeasurements endinthelog(velocity)-∆TFdiagram(seeFigure7b).Wedo of slope evolutionbeforeplacing greatweighton our result. notseethisintheCl0024sample(Figure6b). While incompletenesseffects on Tully-Fisher measurements Itispossiblethatanincorrectmeasurementoftheslopeof havebeenstudiedingreatdetailatlowredshifts(e.g.,Willick theTully-Fisherrelationwouldcauseusnottoseeaturn-off 1994, Giovanelli et al. 1997), these effects are significant to∆TF=0atthehigh-velocityendoftheFigure6(b). This yetrelativelyunexploredin distantTully-Fisherstudies. We wouldbethecaseparticularlyifwemeasureda“steeper”,or have shaded Figure 6(b) to demonstrate how luminosity in- more strongly negative, slope than that which characterized completeness at M >- 19.5 affects the distribution of data the true distribution of our sample. However, as explained B points in this diagram. It is possible that the correlationbe- above,itismuchmorelikelythatwewouldmeasureanoverly tweenvelocityand∆TFwefindmaybeartificiallytightbe- “shallow”slope,givenourmagnitudeincompleteness. Inthe cause we cannot observe galaxies to the lower left in this bottom panels of Figure 7, we demonstrate the effect of a plot.WeinvestigatethisfurtherinFigure7,wherewedemon- “shallow” slope measurement on the log(velocity)-∆TF re- stratehowmagnitudeselectionaffectsTully-Fishermeasure- lation. InFigure7(c),weplotthelog(velocity)-∆TFrelation mentsofthreerandomlygeneratedgalaxypopulations:alow- for the high-dispersion sample of generated data, as this is dispersion sample (black points), a medium-dispersionsam- the sample for which it is most difficult to measure a Tully- ple (dark grey points), and a high-dispersion sample (light Fisherslope.Here,asinFigure7(b),wehavederived∆TFby greypoints). We haveperturbedthevelocitiesandluminosi- comparingthegeneratedgalaxymagnitudestotheirexpected ties of the galaxies in each of these samples around the B- magnitudes,giventheirvelocitiesandtheknowninputTully- bandTFRmeasuredinKFF02,increasingtheperturbationsas Fisher relation. In Figure 7(d), we again plot log(velocity) thegalaxies’luminositiesandvelocitiesdecreasetoreflectthe versus∆TF, but this time we have calculated ∆TF by com- fact that we typically incur larger measurementerrorsat the paring generated galaxy magnitudes to those expected from low-luminosityendoftheTully-Fisherrelation.Thenumbers the measured Tully-Fisher relation (see Table 10), assuming ofgalaxieswe havegeneratedin each luminositybinfollow the input relation was unknown. As can be seen in this di- theshapeoftheg-bandluminosityfunctiongiveninBlanton agram, an underestimated (or less strongly negative) Tully- etal.(2001),with0.45subtractedfromtheg-bandmagnitude, Fisherslopestillresultsinaturn-off,orhereaturn-up,atthe asthisisthetypicalg-BcolorofanSab galaxy(Fukugitaet high-velocityend of the log(velocity)-∆TFrelation. Again, al.1995). wedonotseethisintheCl0024sample(seeFigure6b),and In Figure 7(a), we show the Tully-Fisher relation for the we therefore conclude that the Tully-Fisher slope evolution three samples we have generated. This panel is shaded weseeintheclustermaybereal. to demonstrate a selection bias against galaxies with M > Wewouldneedalargergalaxysampletodiscernmorecon- B - 19.5,asseenintheCl0024sample. Foragivenlowveloc- clusivelywhetherornottheslopeoftheTully-Fisherrelation ity, one can see that only the highest-luminosity data points isevolving.Furthermore,quantifyingtheeffectofmagnitude make it into the unshaded region of the diagram. In Figure selectiononourmeasurementofTully-Fisherslopeevolution 7(b), we present the corresponding log(velocity)-∆TF rela- requiresMonte-Carlosimulationswith knowledgeof galaxy tion,alsoshadedtoreflectourmagnitudeselectionbias. The number counts built in. That work is beyond the scope of low-velocity, high-luminosity galaxies show up as a tail to- thispaper. Wecautionherethattheapparentslopeevolution ward the upper left of the unshaded region of the diagram. foundby otherauthors(e.g., Böhm et al. 2004)may also be Thistailisparticularlyprominentforthehigh-dispersionsam- affectedbymagnitudeincompleteness.Itisalsopossiblethat ple, and could lead one to measure Tully-Fisher slope evo- theirresultsaredrivenbylow-luminositygalaxieswithtrun- lution despite the fact that no slope change was input into catedrotationcurvesor otherkinematic anomaliesthathave the sample. This is clear in Table 10, where we list the the resultedin underestimatedrotation velocities(Kannappan& input Tully-Fisher and log(velocity)-∆TF relations, as well Barton 2004). This does not appear to be the case for our asthemeasuredTully-Fisherandlog(velocity)-∆TFrelations sample (see §5.1.6), as Cl0024 members with the smallest forthe galaxieswithM ≤- 19.5ineachofthethreegener- emission line extents are generally the most underluminous. B atedsamples. Again,thispointstowardthefactthattheTully-Fisherslope Themagnitudeselectionbiasresultsinincreasingly“shal- evolutionweseeinCl0024maybereal. Futurestudieswith