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Astronomy&Astrophysicsmanuscriptno.Alvarado-Gomez_et_al_2016A_low-res_V2 (cid:13)cESO2016 January19,2016 Simulating the Environment Around Planet-Hosting Stars I. Coronal Structure J.D.Alvarado-Gómez1,2,G.A.J.Hussain1,3,O.Cohen4,J.J.Drake4,C.Garraffo4,J.Grunhut1 andT.I.Gombosi5 1EuropeanSouthernObservatory,Karl-Schwarzschild-Str.2,85748GarchingbeiMünchen,Germany e-mail:[email protected] 2Universitäts-SternwarteMünchen,Ludwig-Maximilians-Universität,Scheinerstr.1,81679München,Germany 3InstitutdeRechercheenAstrophysiqueetPlanétologie,UniversitédeToulouse,UPS-OMP,F-31400Toulouse,France 4Harvard-SmithsonianCenterforAstrophysics,60GardenStreet,Cambridge,MA02138,USA 5CenterforSpaceEnvironmentModeling,UniversityofMichigan,2455HaywardSt.,AnnArbor,MI48109,USA 6 1 Received—–;accepted—– 0 2 ABSTRACT n a Wepresenttheresultsofadetailednumericalsimulationofthecircumstellarenvironmentaroundthreeexoplanet-hostingstars.A J state-of-the-art global magnetohydrodynamic (MHD) model is considered, including Alfvén wave dissipation as a self-consistent 8 coronal heating mechanism. This paper contains the description of the numerical set-up, evaluation procedure, and the simulated 1 coronalstructureofeachsystem(HD1237,HD22049andHD147513).Thesimulationsaredrivenbysurfacemagneticfieldmaps, recoveredwiththeobservationaltechniqueofZeemanDopplerImaging(ZDI).Adetailedcomparisonofthesimulationsisperformed, ] where two different implementations of this mapping routine are used to generate the surface field distributions. Quantitative and R qualitativedescriptionsofthecoronaeofthesesystemsarepresented,includingsynthetichigh-energyemissionmapsintheExtreme S Ultra-Violet(EUV)andSoftX-rays(SXR)ranges.Usingthesimulationresults,weareabletorecoversimilartrendsasinprevious . observationalstudies,includingtherelationbetweenthemagneticfluxandthecoronalX-rayemission.Furthermore,forHD1237 h weestimatetherotationalmodulationofthehigh-energyemissionduetothevariouscoronalfeaturesdevelopedinthesimulation. p Weobtainvariations,duringasinglestellarrotationcycle,upto15%fortheEUVandSXRranges.Theresultspresentedherewill - o beused,inafollow-uppaper,toself-consistentlysimulatethestellarwindsandinnerastrospheresofthesesystems. r Key words. stars:coronae–stars:magneticfield–stars:late-type–stars:individual:HD1237–stars:individual:HD22049– t s stars:individual:HD147513 a [ 11. Introduction et al. 2008; Alvarado-Gómez et al. 2015; Hussain et al. 2016). v Long-term ZDI monitoring of particular Sun-like targets have 3Analogous to the 11-year Solar activity cycle, a large fraction showndifferenttime-scalesofvariabilityinthelarge-scalemag- 4of late-type stars (∼ 60%) show chromospheric activity cycles, neticfield.Thisincludesfastandcomplexevolutionwithoutpo- 4 withperiodsrangingfrom2.5to25years(Baliunasetal.1995). larityreversals(e.g.HNPeg,BoroSaikiaetal.2015),erraticpo- 4 Foraverylimitednumberofthesesystems,includingbinaries, laritychanges(e.g.ξBoo,Morgenthaleretal.2012)andhintsof 0 thecoronalX-raycounterpartsoftheseactivitycycleshavealso magneticcycleswithsingle(e.g.HD190771,Petitetal.2009), . 1been identified (e.g. Favata et al. 2008; Robrade et al. 2012). anddouble(e.g.τBoo,Faresetal.2009)polarityreversalsina 0Theseperiodicsignaturesappearasaresultofthemagneticcy- time-scaleof1-2years. 6 cleofthestar.InthecaseoftheSun,thisiscompletedevery22 Furthermore, ZDI maps have proven to be very useful in 1 years over which the polarity of the large-scale magnetic field otheraspectsofcoolstellarsystemsresearch.Applicationscover : vis reversed twice (Hathaway 2010). These elements, the cyclic magneticactivitymodellingforradialvelocityjittercorrections Xiproperties of the activity and magnetic field, constitute a major (Donati et al. 2014), transit variability and bow-shocks (Llama benchmark for any dynamo mechanism proposed for the mag- etal.2013),coronalX-rayemission(Johnstoneetal.2010;Ar- arneticfieldgeneration(Charbonneau2014). zoumanianetal.2011;Langetal.2014)andmasslossratesin Recent developments in instrumentation and observational connectionwithstellarwinds(Cohenetal.2010;Vidottoetal. techniqueshaveopenedanewwindowforstellarmagneticfield 2011). studiesacrosstheHRdiagram(seeDonati&Landstreet2009). In the case of planet-hosting systems, ZDI-based studies In particular, the large-scale surface magnetic field topology in have tended to focus on close-in exoplanet environments by starsdifferentfromtheSuncanberetrievedusingthetechnique applying detailed global three-dimensional magnetohydrody- of Zeeman Doppler Imaging (ZDI, Semel 1989; Brown et al. namic(MHD)models,originallydevelopedforthesolarsystem 1991; Donati & Brown 1997; Piskunov & Kochukhov 2002; (BATS-R-US code, Powell et al. 1999). This numerical treat- Hussain et al. 2009; Kochukhov & Wade 2010). Several stud- ment includes all the relevant physics for calculating a stellar ieshaveshowntherobustnessofthisprocedure,successfullyre- corona/wind model, using the surface magnetic field maps as covering the field distribution on the surfaces of Sun-like stars, driver of a steady-state solution for each system. Within the overawiderangeofactivitylevels(e.g.Donatietal.2008;Petit MHD regime, two main approaches have been considered: an Articlenumber,page1of15 A&Aproofs:manuscriptno.Alvarado-Gomez_et_al_2016A_low-res_V2 ad-hoc thermally-driven polytropic stellar wind (i.e., P ∝ ργ, spectro-polarimetricdata.However,asdescribedbyBrownetal. withγasthepolytropicindex,Cohenetal.2011;Vidottoetal. (1991),ZDIisnotabletoproperlyrecoververysimplefieldge- 2012, 2015), and a more recent description, with Alfvén wave ometries(e.g.dipoles),andismoresuitablefor complex(spot- turbulence dissipation as a self-consistent driver of the coronal ted)magneticdistributions.ThislimitationisremovedintheSH- heating and the stellar wind acceleration in the model (Cohen ZDIimplementation.Bothproceduresarerestrictedbytheincli- et al. 2014). This last scheme is grounded on strong observa- nation angle of the star and therefore, a fraction of the surface tionalevidencethatAlfvénwaves,ofsufficientstrengthtodrive field that cannot be observed, is not recovered in the maps. To the solar wind, permeate the solar chromosphere (De Pontieu correctforthiseffect,previousnumericalstudieshavecompleted et al. 2007; McIntosh et al. 2011). Additionally, this numerical the field distribution by a reflection of the ZDI map across the approachhasbeenextensivelyvalidatedagainstSTEREO/EUVI equatorialplane(e.g.Cohenetal.2010).Morerecently,Vidotto andSDO/AIAmeasurements(seevanderHolstetal.2014).The et al. (2012) have included complete symmetric/antisymmetric modelspresentedinthispaperarebasedonthislatesttreatment SH-ZDImapstoshowthatthemapincompletenesshasaminor oftheheatingandenergytransferinthecorona. impact over their simulation results. However, for the simula- In this work we present the results of a detailed numerical tions performed here, which include the latest implementation simulation of the circumstellar environment around three late- of BATS-R-US, this may not be the case. A larger impact may type exoplanet-hosts (HD 1237, HD 22049 and HD 147513), be expected on the overall coronal structure, as the mechanism using a 3D MHD model. This first article contains the results forthecoronalheatingandthewindaccelerationisdirectlyre- ofthesimulatedcoronalstructure,whilethewindandinneras- lated to the field strength and topology (e.g. Alfvén waves, see trosphere domains will be presented in a follow-up paper. The vanderHolstetal.2014). simulationsaredrivenbytheradialcomponentofthelarge-scale surfacemagneticfieldinthesestars,whichhavebeenrecovered using two different implementations of ZDI (Sect. 2). All three systemshavesimilarcoronal(X-ray)activitylevels(seetable1). WhilethesearemoreactivethantheSuntheywouldbeclassified asmoderatelyactivestarsandwellbelowtheX-ray/activitysat- uration level. A description of the numerical set-up is provided in section 3, and the results are presented in section 4. Section 5 contains a discussion in the context of other studies and the conclusionsofourworkaresummarizedinsection6. 2. Large-ScaleMagneticFieldMaps HD 1237, HD 147513 and HD 22049 are cool main sequence stars(G8,G5andK2respectively)withrelativelyslowrotation rates(P ∼7−12days).EachofthesesystemshostaJupiter- rot massplanet(M sini > M ),withorbitalseparationscompara- p ble to the solar system planets (Hatzes et al. 2000; Naef et al. (cid:88) 2001;Mayoretal.2004;Benedictetal.2006).Table1contains asummaryoftherelevantastrophysicalparametersforeachsys- tem,takenfromvariousobservationalstudies. Previousworkshaverecoveredthelarge-scalemagneticfield Fig.1.SurfaceradialmagneticfieldmapsofHD1237.Acomparison onthesurfacesofthesestars,byapplyingZDItotime-seriesof betweenthestandardZDI(top)andtheSH-ZDI(bottom)ispresented. circularlypolarisedspectra(Jeffersetal.2014;Alvarado-Gómez ThecolourscaleindicatesthepolarityandthefieldstrengthinGauss et al. 2015; Hussain et al. 2016). For the stars included in this (G).Notethedifferenceinthemagneticfieldrangeforeachcase.The work,thishasbeendonewiththespectropolarimeterNARVAL stellarinclinationangle(i=50◦)isusedforthevisualizations. at the Telescope Bernard Lyot (Aurière 2003), and the polari- Figures1and2showacomparisonbetweenthereconstruction metricmode(Piskunovetal.2011)oftheHARPSechellespec- proceduresappliedtoHD1237andHD22049,respectively.In trograph (Mayor et al. 2003) on the ESO 3.6m telescope at La general,themapsobtainedusingZDIshowamorecomplexand SillaObservatory.Forconsistency,theZDImapsincludedinthe weakerfielddistributionincomparisontotheSH-ZDI,wherea simulations have been reconstructed using data from the same instrument/telescope†(i.e.HARPSpol). smootherfieldtopologyisobtained.Whiletherearesimilarities in the large-scale structure, discrepancies are obtained in terms For the magnetic field mapping procedure, we considered two different approaches; the classic ZDI reconstruction, in oftheamountofdetailrecoveredineachcase.Thesedifferences arise as a consequence of the constraints imposed for complet- which each component of the magnetic field vector is decom- ing the SH-ZDI maps, which are all pushed to symmetric field posedinaseriesofindependentmagnetic-imagepixels(Brown distributions. In general, the spatial resolution of the SH-ZDI etal.1991;Donati&Brown1997),andthesphericalharmonics maps depend on the maximum order of the spherical harmon- decomposition(SH-ZDI)wherethefieldisdescribedbythesum ics expansion (l ). For each case this is selected in such a of a potential and a toroidal component, and each component max way that the lowest possible l value is used, while achiev- is expanded in a spherical-harmonics basis (see Hussain et al. max ing a similar goodness-of-fit level (reduced χ2) as the classic 2001;Donatietal.2006).Bothproceduresareequivalent,lead- ZDI reconstruction (HD 1237: l = 5, HD 22049: l = 6, ing to very similar field distributions and associated fits to the max max HD147513:l = 4).Highervaluesofl wouldnotalterthe max max †Therefore,forHD22049((cid:15)Eridani)weonlyconsidertheJanuary large-scale distribution, but introduces further small-scale field 2010dataset(seePiskunovetal.2011;Jeffersetal.2014). withoutsignificantlyimprovingthegoodness-of-fit.Thisstepis Articlenumber,page2of15 Alvarado-Gómezetal.:EnvironmentaroundPlanet-HostingStars-I.CoronalStructure Table1.Planet-hostingsystemsandtheirobservationalproperties. StarID S.Type Teff R∗ M∗ Prot i Age Activity Mpsini a (cid:104)εBr(cid:105) [K] [R ] [M ] [days] [◦] [Gyr] log(R(cid:48) ) log(L ) [M ] [AU] ZDI SH-ZDI (cid:12) (cid:12) HK X HD1237a G8V 5572 0.86 1.00 7.00 ∼50 ∼0.88 −4.38 29.02 3.37 0.49 4.65 30.77 (cid:88) HD22049b K2V 5146 0.74 0.86 11.68 ∼45 ∼0.44 −4.47 28.22 1.55 3.39 2.32 30.66 HD147513c G5V 5930 0.98 1.07 10.00 ∼20 ∼0.45 −4.64 28.92 1.21 1.32 −† 6.21 Notes.Thevalueslistedincolumns1−12aretakenfrompreviousstudiesofeachsystemandreferencestherein:(a)Naefetal.(2001);Alvarado- Gómezetal.(2015)(b)Drake&Smith(1993);Hatzesetal.(2000);Benedictetal.(2006);Jeffersetal.(2014)and(c)Mayoretal.(2004);Hussain etal.(2016).Thelasttwocolumnscontainthe(radial)magneticenergydensity,ε = B2/8π,averagedoverthevisiblesurfaceofthestar,and Br r estimatedfromthestandardZDIandtheSphericalHarmonicsimplementation(SH-ZDI). (†)Duetothelowinclinationandsimplefieldgeometry,thestandardZDIreconstructionwasnotpossibleinthiscase(seeBrownetal.1991). Fig.2.SurfaceradialmagneticfieldmapsofHD22049.Seecaptionof Fig. 4. Surface radial magnetic field maps of the Sun during activity Fig.1.Thestellarinclinationangle(i = 45◦)isusedforthevisualiza- minimum(CR1922,top)andmaximum(CR1962,bottom)takenby tions. SOHO/MDI. Note the difference in the magnetic field range for each case.Aninclinationanglei=90◦isusedforthevisualizations. To evaluate our numerical results, we have performed two additionalsimulationstakingtheSunasreference.Themagnetic field distributions during solar minimum (Carrington rotation 1922,endofcycle22),andsolarmaximum(Carringtonrotation 1962, during cycle 23) have been considered for this purpose. The large-scale magnetic field is taken from synoptic magne- tograms,generatedbytheMichelsonDopplerImagerinstrument (MDI,Scherreretal.1995)onboardtheSolarandHeliospheric Observatoryspacecraft(SOHO,Domingoetal.1995).Figure4 Fig. 3. Surface radial magnetic field maps of HD 147513 using SH- showsthecomparisonbetweentheglobalmagneticfielddistri- ZDI. Two rotational phases (Φ) are presented. The stellar inclination butionfortheseactivityepochs.Duringactivityminimum,weak angle(i=20◦)isusedforthevisualizations. magnetic regions (a few Gauss) tend to be sparsely distributed acrosstheentiresolarsurface(nopreferentiallocationforthese regionsisobserved).Strongersmall-scalemagneticfields,upto particularly important for a consistent comparison, as the final twoordersofmagnitude,canbefoundduringactivitymaximum. recovered field strengths depend on this. All these differences Inthiscasethedominantfieldsarehighlyconcentratedinbipo- have a significant impact in the coronal and wind structure, as larsectors(activeregions)andlocatedmainlyintwolatitudinal they depend on the field coverage and the amount of magnetic beltsat∼±30◦.Still,weakermagneticfieldscanbefoundalong energy available in each case (see Table 1). In the case of HD theentiresolarsurface. 147513thestandardZDIreconstructionwasnotpossible,given Finally,asisshowninFigs.1to4,thenumericalgridforall its low inclination angle (i ∼ 20◦) and fairly simple large-scale theinputsurfacemagneticfielddistributionsisthesame.There- topology. Therefore, for this system we only consider the SH- fore, the resolution of the solar coronal models was adapted to ZDI map presented in Fig. 3, previously published by Hussain match the optimal resolution of the stellar simulations. In this etal.(2016). way, a more consistent comparison of the results can be per- Articlenumber,page3of15 A&Aproofs:manuscriptno.Alvarado-Gomez_et_al_2016A_low-res_V2 formed. The surface grid resolution (∼10−2 R ) is sufficient to andmagneticfield,B,canbeextracted.Wepresentthesimula- ∗ resolve entirely the magnetic structures on the stellar ZDI/SH- tionresultsinthefollowingsection. ZDI maps. However, in the solar case the internal structure of theactiveregionsandthesmall-scalestructuresarenotresolved. Theimpactofthislimitedresolutioninmagneticfieldmapsfor 4. Results solar simulations has been investigated previously by Garraffo Weperformadetailedevaluationofthesolutionsetsfortheso- etal.(2013).Theyfoundthatthestructureofthestellarwindis lar minimum and maximum cases in Sect. 4.1. Sections 4.2 to less sensitive to this factor than the coronal structure and asso- 4.4containthesimulationresultsofthecoronalstructureforthe ciatedemission(e.g.EUVandX-rays).Thiswillbeexploredin starsconsidered.Ineachcasewepresentthedistributionofthe moredetailintheevaluationprocedure,presentedinSect.4.1. thermodynamicconditions(n,T),aswellasthemagneticenergy density(ε ),associatedwiththeradialfield.Acommoncolour Br scaleisadoptedforallstarstofacilitatecomparison‡. 3. 3DMHDNumericalSimulation In addition, synthetic coronal emission maps are generated The numerical simulations presented here are performed using at SXR and EUV wavelengths. This is done by integrating the the three-dimensional MHD code BATS-R-US (Powell et al. squareoftheplasmadensitytimestheemissivityresponsefunc- 1999) as part of the Space Weather Modeling Framework tion of a particular instrument, along the line-of-sight towards (SWMF, Tóth et al. 2012). As discussed previously by Cohen theobserver.IntheSXRrangeweconsiderthespecificresponse et al. (2014), the SWMF encompasses a collection of physics- function of the AlMg filter of the SXT/Yohkoh instrument, to based models for different regimes in solar and space physics. synthesise images in the 2 to 30Å range (0.25 – 4.0 keV, red Thesecanbeconsideredindividuallyorcanbecoupledtogether images).FortheEUVrangesensitivitytablesoftheEIT/SOHO to provide a more realistic description of the phenomenon or instrument are used, leading to narrow-band images centred at domain of interest. For the systems considered here, we have the Fe IX/X 171Å (blue), Fe XII 195Å (green), and Fe XV included and coupled two overlapping domains to obtain a ro- 284Å (yellow)lines.Thecoronalemissionatthesewavelengths bustcombinedsolution.Theresultspresentedinthispapercor- hasbeenextensivelystudiedinthesolarcontext,servingalsoto respondtothestellarcoronadomain(SCmodule).Afollow-up calibratetheresultsfromtheSWMFinvariousworks(seeGar- studywillcontainthewindandtheinnerastrospheredescription raffoetal.2013;vanderHolstetal.2014).Thisprocedurealso (IHmodule).Thesolutionforeachdomainisobtainedusingthe allowsthedirectcomparisonofthesyntheticimages,generated mostup-to-dateversionoftheSWMFmodules†. fordifferentstars.ForHD1237andHD22049weadditionally Thestellarcoronadomainextendsfromthebaseofthechro- compare the results driven by the different maps of the large- mosphere (∼1R ) up to 30R . A three-dimensional potential ∗ ∗ scalemagneticfield(Sect.2). fieldextrapolation,abovethestellarsurface,isusedastheinitial condition. This initial extrapolation is performed based on the photospheric radial magnetic field of the star (e.g. ZDI maps, 4.1. EvaluationoftheSolarCase Sect. 2). In addition to the surface magnetic field distribution, ThesimulationresultsfortheSunarepresentedinAppendixA. thismodulerequiresinformationaboutthechromosphericbase The synthetic images provide a fairly good match to the solar density, n , and temperature, T , as well as the stellar mass, 0 0 observations obtained during 1977-May-07 (activity minimum, M ,radius,R androtationperiod,P .Thisdiffersfromprevi- ∗ ∗ rot Fig.A.1)and2000-May-10(activitymaximum,Fig.A.2)§.The ous ZDI-driven numerical studies, where these thermodynamic steady-statesolutionproperlyrecoversthestructuraldifferences boundaryconditionsaresettocoronalvaluesandtherefore,not forbothactivitystates.Anopen-fielddominatedcoronaappears self-consistentlyobtainedinthesimulations(Cohenetal.2011; in the solar minimum case, displaying coronal holes near the Vidottoetal.2012,2015). polarregionsoftheSun.Inturn,thesolarmaximumcaseshows Forthestarsconsideredhere,weassumedsolarvaluesforthe mainlyclose-fieldregionsacrossthesolardisk,withalmostno chromosphericbasedensity(n =2.0 × 1016m−3),andtemper- 0 openfield-linelocations.Thiswillhavevariousimplicationfor ature(T =5.0×104K).Thisisjustifiedfromthefactthatthese 0 the associated solar wind structure, which will be discussed in systems,whilemoreactivethantheSun,arestillwithintheX- thesecondpaperofthisstudy. rayun-saturatedregimeandtherefore,thephysicalassumptions In general, the differences in the magnetic activ- behind the coronal structure and the solar wind acceleration in ity/complexityareclearlyvisibleinthesteady-statesolution.As the model are more likely to hold. This assumption permits a expected, the thermodynamic structure of the corona, and the consistentcomparisonwiththesolarcaseandbetweenthesys- associated high-energy emission, show large variation in both tems considered. The remaining initial required parameters for activity states. To evaluate the simulation results, we need to eachstararelistedinTable1.Forthesolarrunsweusetheside- quantitatively compare the numerical solutions for the Sun to realrotationrateof25.38days(Carringtonrotation). therealobservations(i.e.basedontheSXR/EUVdata).Aswas Weuseanon-uniformsphericalgrid,dynamicallyrefinedat discussed in Sect. 2, this is particularly important as the solar thelocationsofmagneticfieldinversion,whichprovidesamax- simulations presented here have been performed with limited imumresolutionof∼10−3R∗.Thenumericalsimulationevolves spatial resolution (see also Garraffo et al. 2013). To do this, until a steady-state solution is achieved. Coronal heating and we contrast the simulation results to archival Yohkoh/SXT and stellarwindaccelerationduetoAlfvénwaveturbulencedissipa- SOHO/EIT data∗ covering both activity epochs (Carrington tionareself-consistentlycalculated,takingintoaccountelectron rotations1922and1962). heatconductionandradiativecoolingeffects.Forfurtherdetails thereaderisreferredtoSokolovetal.(2013)andvanderHolst ‡Exceptinthemagneticenergydensitydistributionforsolarmini- etal.(2014).Fromthisfinalsolution,allthephysicalproperties, mumcase(Fig.A.1),wheretherangeisdecreasedbyafactorof10. such as number density, n, plasma temperature, T, velocity, u §For a quick-look comparison with the observations from various instrumentsduringthesedates,visithttp://helioviewer.org/. †Codeversion2.4 ∗AvailableattheVirtualSolarObservatory(VSO) Articlenumber,page4of15 Alvarado-Gómezetal.:EnvironmentaroundPlanet-HostingStars-I.CoronalStructure Table2.EvaluationresultsfortheEUVrange.Thelistedvaluescorrespondtoaveragesoveranentirerotation,obtainedfromtheobservations (Obs)andthesimulations(Sim).Thetwofilterwavelength-ratio(inÅ)usedfortheparametersestimationareindicatedineachcase. Parameter Min(Obs) Min(Sim) Max(Obs) Max(Sim) 195/171 284/195 195/171 284/195 195/171 284/195 195/171 284/195 (cid:104)T(cid:105)[×106K] 1.06 1.77 1.14 1.63 1.13 1.79 1.16 1.66 (cid:104)EM(cid:105)[×1026cm−5] 4.51 5.08 1.19 0.98 8.42 14.9 5.52 5.06 FortheSXRrange,weusethedailyaveragesforthesolarirra- the observations (Obs). A similar level of agreement (with re- dianceat1AU,describedinActonetal.(1999),andcomputea versedsign)isachievedforthehottercomponentofthecorona meanvalueforeachCarringtonrotation.Thisleadsto1.02×10−5 (284/195ratio).Furthermore,thesimulatedSXRemissionprop- Wm−2forsolarminimum,and1.21×10−4Wm−2forsolarmax- erly recovers the nominal estimates for both activity periods, imum,inthe2–30Å range.IntermsofSXRluminosities,these withresultingvalueslyingbetweentheobservationalestimates values correspond to 2.86×1025 ergs s−1 and 3.42×1026 ergs ofActonetal.(1999)andJudgeetal.(2003).Inasimilarman- s−1,respectively.However,morerecentestimates,presentedby ner, the fiducial EUV luminosities during minimum and maxi- Judgeetal.(2003),leadtolargervaluesintheSXRluminosities mum of activity are well recovered. However, we should note during the solar activity cycle (i.e. 1026.8 ergs s−1 during activ- here that He II 304Å line tends to dominate the GOES-13 B ity minimum, and 1027.9 ergs s−1 for activity maximum). From bandpass.Thislineisoverlystrongcomparedwithexpectations the steady-state solutions, we simulate the coronal emission in based on collisional excitation (e.g. Jordan 1975; Pietarila & the SXR band with the aid of the Emission Measure distribu- Judge 2004), and therefore our model spectrum is expected to tion EM(T) (Sect. 5.1), and following the procedure described significantlyunder-predicttheobservedflux.Thatweobtainrea- inSect.5.2.Thisyieldssimulatedvaluesof2.79×1026ergss−1 sonablygoodagreementislikelyaresultofouremissionmea- and2.49×1027ergss−1duringactivityminimumandmaximum, suredistributionbeingtoohighattransitionregiontemperatures respectively. (seeSec.5.1,Fig.11).Incontrast,largerdiscrepanciesarefound A similar procedure is applied for the EUV range. Images for the EM distribution (over the sensitivity range of the EIT acquiredbytheEITinstrumentduringbothactivityperiods,are filters)forbothcoronalcomponents.Duringactivityminimum, used for this purpose. We consider 3 full-disk images per day differences up to factors of −3.8 and −5.2 appear for the low- (oneforeachEUVchannel,excludingthe304Åbandpass),for andhigh-temperaturecorona,respectively.Slightlysmallerdif- atotalof87imagesperrotation.Aftertheimageprocessing,we ference factors prevail during activity maximum for both com- performedtemperatureand EM diagnostics,usingthestandard ponents,reaching−1.5and−3.0respectively. SolarSoftWare(SSW)routinesforthisspecificinstrument†.This Someofthesediscrepanciescanbeattributedtoassumptions leadstoaroughestimateofbothparameters,givenapair(ratios) ofthemodeloritsintrinsiclimitations(seevanderHolstetal. ofEUVimages.Weusethetemperature-sensitivelineratiosof 2014).Inthiscase,asdiscussedpreviouslyinSect.2,theyarise Fe XII 195Å/ Fe IX/X 171Å and Fe XV 284Å/ Fe XII 195Å mostlyduetothespatialresolutionofthesurfacefielddistribu- (for a combined sensitivity range of 0.9 MK < T < 2.2 MK). tions. The overall lower densities of the corona and the imbal- ThereaderisreferredtoMosesetal.(1997)forfurtherinforma- ance of emission at different coronal temperatures, are directly tion.AswiththeSXRrange,wecomputemeanobservedvalues related with the amount of confining loops and therefore, with of these parameters for both rotations, and compare them with the missing (un-resolved) surface magnetic field and its com- simulated quantities, derived from the synthetic EUV emission plexity. In addition, as will be presented in the Sect. 5.2, the maps.TheobtainedvaluesarepresentedintheTable2. simulated stellar X-ray and EUV luminosities appear underes- We also compared the synthetic EUV emission to archival timated. This may indicate that some adjustments are required data from the GOES-13/EUVS instrument‡. These measure- in the coronal heating mechanism, when applying this particu- mentsspandifferentsolaractivityperiodsincomparisontothe lar model to resolution-limited surface field distributions (e.g. epochs considered in the simulations (CR 1922 and CR 1962). ZDI data). Further systematic work will be performed in this Therefore, we interpret these quantities as nominal values for direction, analogous to the numerical grid presented in Cohen the EUV variation during minimum and maximum of activity. & Drake (2014), including also other coronal emission ranges WeconsiderGOES-13datafromchannelsA(50−150Å)andB covered by current solar instrumentation (e.g. Solar Dynamics (250−340Å),leadingtoaverageEUVluminosities,foractivity Observatory,Pesnelletal.2012). minimumandmaximum,of∼2−5×1027ergs−1and∼1×1028 erg s−1, respectively. The simulated coronal emission, synthe- 4.2. HD1237(GJ3021) sisedinthesamewavelengthranges,providesverygoodagree- ment to the observations, leading to ∼1.4×1027 erg s−1 during The coronal structure obtained for HD 1237 shows a relatively solarminimum,and∼1.3×1028ergs−1atsolarmaximum. simpletopology.Twomainmagneticenergyconcentrations,as- Theresultsfromtheevaluationprocedureareconsistentbe- sociated with the field distributions shown in Fig. 1, dominate tween the EUV and SXR ranges, showing a reasonable match thephysicalpropertiesandthespatialconfigurationinthefinal between the simulations and the overall structure of the solar steady-state solution. The outer parts of these regions serve as coronaforbothactivityperiods.Goodagreementisobtainedfor foot-pointsforcoronalloopsofdifferentlength-scales.Closeto thelow-temperatureregion(195/171ratio),withdifferencesbe- thenorthpoleanarcadeisformed,whichcoversoneofthemain low+8%inthemeantemperatureforbothepochs.Thesignin- polarityinversionlinesofthelarge-scalemagneticfield.Ascan dicatestherelativedifferencebetweenthesimulation(Sim)and beseeninFigs.5and6,denserandcoldermaterialappearsnear theselinesonthesurface,resemblingsolarprominencesorfila- †MoreinformationcanbefoundintheEITuserguide ments.Largerloopsextendinghigherinthecorona,connectthe ‡Seehttp://www.ngdc.noaa.gov/stp/satellite/goes/. oppositeendsofbothmagneticregions. Articlenumber,page5of15 A&Aproofs:manuscriptno.Alvarado-Gomez_et_al_2016A_low-res_V2 Fig.5.SimulationresultsforthecoronalstructureofHD1237drivenbytheZDIlarge-scalemagneticfieldmap.Theupperpanelscontainthe distributionofthemagneticenergydensity(ε ,left),thenumberdensity(n,middle)andtemperature(T,right).Forthelasttwoquantitiesthe Br distributionovertheequatorialplane(z=0)ispresented.Thesphererepresentsthestellarsurfaceandselectedthree-dimensionalmagneticfield linesareshowninwhite.ThelowerimagescorrespondtosyntheticcoronalemissionmapsinEUV(blue/171Å,green/195Å andyellow/ 284Å)andSXR(red/2–30Å).Theperspectiveandcolourscalesarepreservedinallpanels,withaninclinationangleofi=50◦. Fig. 6. Simulation results for the coronal structure of HD 1237 driven by the SH-ZDI large-scale field map. See caption of Fig. 5. The three- dimensionalmagneticfieldlinesarecalculatedinthesamespatiallocationsasinthesolutionpresentedinFig.5. Articlenumber,page6of15 Alvarado-Gómezetal.:EnvironmentaroundPlanet-HostingStars-I.CoronalStructure Fig.7.SimulationresultsforthecoronalstructureofHD22049drivenbytheZDIlarge-scalemagneticfieldmap.Theupperpanelscontainthe distributionofthemagneticenergydensity(ε ,left),thenumberdensity(n,middle)andtemperature(T,right).Forthelasttwoquantitiesthe Br distributionovertheequatorialplane(z=0)ispresented.Thesphererepresentsthestellarsurfaceandselectedthree-dimensionalmagneticfield linesareshowninwhite.ThelowerimagescorrespondtosyntheticcoronalemissionmapsinEUV(blue/171Å,green/195Å andyellow/ 284Å)andSXR(red/2–30Å).Theperspectiveandcolourscalesarepreservedinallpanels,withaninclinationangleofi=45◦. Fig.8.SimulationresultsforthecoronalstructureofHD22049drivenbytheSH-ZDIlarge-scalefieldmap.SeecaptionofFig.7.Thethree- dimensionalmagneticfieldlinesarecalculatedinthesamespatiallocationsasinthesolutionpresentedinFig.7 Articlenumber,page7of15 A&Aproofs:manuscriptno.Alvarado-Gomez_et_al_2016A_low-res_V2 Theseloopsconfinecoronalmaterialviamagneticmirroring,in- Alargefilamentcrossingtheentirediskisvisibleinbothsolu- creasingthelocaldensityandtemperatureoftheplasma.Some tions,beingmoresmoothintheSH-ZDIasisexpectedfromthe ofthisheatedplasmaisvisibleinthesyntheticemissionimages underlyingfielddistribution. ofthelowercorona(lowerpanelsofFigs.5and6). ThecomparisonbetweentheZDIandSH-ZDIsolutionleads Inside the two large magnetic energy regions, the coronal to similar results as for HD 1237. The variation in the average fieldlinesaremainlyopen.Thisleadstothegenerationofcoro- coronal density, temperature and magnetic field strength reach nal holes, where the material follows the field lines and leaves factors of 2.5, 1.6 and 4.3, respectively (see Table 3). The dif- thestar.Inturn,thisdecreasesthelocalplasmadensityandtem- ferencesinthesyntheticemissionmapsarealsosomewhatpre- peratureinbothregions,makingthemappeardarkinthecoronal served with respect to the HD 1237 simulations; Less coronal emissionmaps.Thesecoronalholeswillhaveastronginfluence featuresarevisibleinEUVchannelsoftheSH-ZDIsolution,and inthestructureofthestellarwindandtheinnerastrosphere.This theSXRemissionisdominatedbytheclosedfieldregions,dis- willbediscussedindetailinthesecondpaperofthisstudy. tributedinthiscaseinvariouslocationsofthethree-dimensional Intermsofthefielddistribution(i.e.ZDI/SH-ZDI,Sect.2), structure. theglobalstructureofthecoronaofHD1237issimilarinboth Finally,itisinterestingtonoteherethesimilaritiesbetween cases. This was expected since the largest features, in the sur- the quantitative average properties of the ZDI solution of HD face field distributions, are common in both procedures. How- 22049andthesolarmaximumcase.Theresultingmeantemper- ever,ascanbeseendirectlyinFigs.5and6,severalqualitative atures and field strengths are commensurate among these sim- andquantitativedifferencesappearinvariousaspectsofthere- ulations. However, large differences are evident in the qualita- sultingcoronalstructure.First,despitehavingthesamethermo- tiveaspectsofbothsolutions(seeFigs.7andA.2).Nocoronal dynamicbaseconditions,theSH-ZDIsolutionleadstoalarger holes are obtained for the solar maximum case, and the high- coronawithanenhancedhigh-energyemission.Thisisaconse- energy emission is highly concentrated from small portions of quence of the available magnetic energy to heat the plasma, in thecorona(associatedwithactiveregions).Thisagaincanbeun- combination with the size of the coronal loops (and therefore, derstoodintermsoftheamountofmagneticstructuresresolved theamountofmaterialtrappedbythefield). inthesurfacefielddistribution.Despitethedegradedresolution Toquantifythesedifferences,weestimatedtheaverageden- for the solar case, the number of bipolar regions on the surface (sustainingdensecoronalloops)ismuchlargerthaninthelarge- sity, temperature and magnitude of the coronal magnetic field, scale field maps recovered with ZDI. Instead, the ZDI coronal inside a spherical shell enclosing the region between 1.05 and solution for HD 22049 is much more similar to the solar min- 1.50 R . This range captures the bulk of the inner corona, with ∗ imum case (Fig. A.1). This clearly exemplifies the importance thelowerlimitselectedtoavoidpossiblenumericalerrorsinthe ofcombiningquantitativedescriptions,togetherwithqualitative average integration (due to the proximity with the boundary of spatially-resolvedinformationforarobustcomparison. thesimulationdomain).Theintegratedvaluesobtainedforeach parameter,andfortheotherstars,arelistedintheTable3. For HD 1237 we obtain differences by a factor of ∼1.4 in 4.4. HD147513(HR6094) temperature,∼2.1indensityand∼3.5inmagneticfieldstrength, We present the steady-state coronal solution for HD 147513 in amongbothcases.AsthecoronaishotteranddenserintheSH- Fig.9.Aswasmentionedearlier,weonlyconsidertheSH-ZDI ZDI case, the resulting high-energy emission is almost feature- lessintheEUVchannels(T ∼ 1−2MK).Inaddition,theim- fielddistributioninthiscase(seeSect.2).Thecoronalstructure isdominatedbyarathersimpleconfigurationofpoloidalloops, pactofthesurfacefieldcompletenessisclearintheSXRimage, drivenbythesurfacefielddistribution(mainlyfromthedipolar where the coronal holes are shifted to lower latitudes and the and quadrupolar components). This generates bands of trapped emissioncomesfrombothhemispheresofthestar(incontrastto material,separatedbythemagneticpolarityinversionlinesand thesimulatedemissioninthisrangefortheZDIcase). distributedatdifferentlatitudes.Fewopenfieldregionsarevis- As expected, HD 1237 shows enhanced coronal conditions ible in the coronal structure, which are again located inside the compared to the Sun, especially for the SH-ZDI case (see Ta- largestmagneticenergyconcentrations.Oneoftheseregionsap- ble 3). For the ZDI case the mean coronal density appears to pearsinthenorthpoleofthestar,whichsuffersasmalldistortion be lower than the Solar maximum value (by ∼25%). This may in the EUV images due to a numerical artifact of the spherical be connected with the incompleteness of the ZDI maps (Sect. grid.Theline-of-sightSXRemissiondisplaysaring-likestruc- 2), since a similar situation occurs for the ZDI solution of HD ture close to the limb, corresponding to the hottest material of 22049byroughlythesameamount. thesteady-statecorona.Somefaintemissioncanbealsoseenin- side the stellar disk. As the estimated inclination angle for this 4.3. HD22049((cid:15) Eridani) star is small (i ∼20◦), the coronal features are visible at almost allrotationalphases. ThesolutionsforHD22049arepresentedinFigs.7and8.The The coronal properties listed in Table 3, show an average coronalstructureinthiscaseishighlycomplex,withseveralhot densitycomparabletothesolarcaseinactivitymaximum.How- anddenseloopsconnectingthedifferentpolarityregionsofthe ever, as was presented in Sect. 4.1, the limited resolution of surfacefielddistribution.Insomelocations,thematerialisable the surface field distribution can strongly affect this parameter. toescapenearthecuspoftheloops,resemblinghelmetstreamers GiventherelativelylowresolutionfortheSH-ZDImapforthis in the Sun. For the SH-ZDI simulation, some of this escaping star, we expect larger discrepancies than the ones obtained for materialisevenvisibleintheEUVsyntheticmaps(inparticular the solar case. In this sense, the average values obtained from inthe195Åchannel–GreenimageinFig.8). thesimulationcorrespondonlytoroughestimatesoftheactual SimilartoHD1237,twolargecoronalholesarevisibleinthe conditions of the corona. This is considered in more detail in synthetichigh-energyemissionmaps(especiallyintheZDIsim- Sect.5.1.Still,thegeometricalconfigurationofthissystempro- ulation).Howeverinthiscase,thecorrelationwiththestronger videsaninterestingviewofthecoronalfeatures,thatcannotbe magnetic features in the surface is less clear as for HD 1237. easilyobtainedevenforthesolarcase. Articlenumber,page8of15 Alvarado-Gómezetal.:EnvironmentaroundPlanet-HostingStars-I.CoronalStructure Table3.Averagephysicalpropertiesoftheinnercorona(IC)region(from1.05to1.5R ). ∗ Parameter HD1237 HD22049 HD147513 Sun ZDI SH-ZDI ZDI SH-ZDI SH-ZDI CR1922(Min) CR1962(Max) (cid:104)n(cid:105) [×107cm−3] 3.66 7.74 3.38 8.30 4.80 1.80 4.78 IC (cid:104)T(cid:105) [×106K] 2.49 3.42 2.06 3.20 2.79 1.48 2.07 IC (cid:104)B(cid:105) [G] 4.58 16.43 3.34 14.39 5.37 0.94 2.31 IC Fig.9.SimulationresultsforthecoronalstructureofHD147513drivenbytheSH-ZDIlarge-scalemagneticfieldmap.Theupperpanelscontain thedistributionofthemagneticenergydensity(ε ,left),thenumberdensity(n,middle)andtemperature(T,right).Forthelasttwoquantities Br thedistributionovertheequatorialplane(z = 0)ispresented.Thesphererepresentsthestellarsurfaceandselectedthree-dimensionalmagnetic fieldlinesareshowninwhite.ThelowerimagescorrespondtosyntheticcoronalemissionmapsinEUV(blue/171Å,green/195Å andyellow /284Å)andSXR(red/2–30Å).Theperspectiveispreservedinallpanels,withaninclinationangleofi=20◦. 5. AnalysisandDiscussion Figure 10 contains the computed EM(T) for all the considered cases. As expected, the peak values are located at logT > 6.0, Usingthesimulationresultswecanrelatethecharacteristicsof andmovetowardslargeremissionmeasuresandhighertemper- thesurfacefielddistributions,withtheobtainedcoronalproper- atures,withincreasingaverage(radial)magneticenergydensity tiesandtheenvironmentaroundthesesystems.Wewillfocusour (cid:104)ε (cid:105)(seeTable1). discussiononthreemainaspects,includingthethermodynamic Br In a similar manner to the solar case (Sect. 4.1), we com- structure,thecoronalhigh-energyemission,andthestellarrota- pare the simulated quantities to observational values. The ZDI tionalmodulationofthecoronalemission. and SH-ZDI simulations of HD 22049 yield maximum EM values of logEM(cid:39)49.1 (at logT(cid:39)6.4) and logEM(cid:39)50.0 (at 5.1. ThermodynamicCoronalProperties logT(cid:39)6.6), respectively. The peak temperature and emission measure of the ZDI model are significantly lower than those From the simulated 3D structure in each star, we calculate the derived from both EUV and X-ray spectra (logEM(cid:39)50.7 at emissionmeasuredistribution,EM(T),definedby logT(cid:39)6.6±0.05, Drake et al. 2000; Sanz-Forcada et al. 2004; Ness & Jordan 2008). The SH-ZDI emission measure fares (cid:90) somewhatbetter,withgoodagreementintermsofthepeaktem- EM(T)= n2(T)dV(T), (1) perature.However,thismodelstillpredictsanemissionmeasure V(T) significantlylowerthanobserved,byroughlyafactorof5. wheren(T)istheplasmadensityatthetemperatureT,theinte- ForHD147513availableobservations,fromthebroad-band grationonlyincludesthevolumeofthegridcellsatthatpartic- filters of the Extreme Ultraviolet Explorer (EUVE) Deep Sur- ulartemperature,andthevolumecoversalltheclosedfieldline veytelescope,onlyprovideroughestimatesofthecoronalcon- regionsinthesteady-statesolutions.Weusetemperaturebinsof ditions, suggesting a probable emission measure in the range 0.1inlogT startingfromthebasetemperature(i.e.logT (cid:39)4.9), logEM ∼ 51–52 (Vedder et al. 1993) but with no discrimina- up to the maximum temperature achieved in each simulation. tion on the temperature. In turn, the peak of the simulated dis- Articlenumber,page9of15 A&Aproofs:manuscriptno.Alvarado-Gomez_et_al_2016A_low-res_V2 Fig.10.EmissionmeasuredistributionsEM(T)calculatedfromthe3D steady-state solutions. Each colour corresponds to one of the simula- tionspresentedinSect.4,includingthesolarruns(AppendixA). tribution is located at logT(cid:39)6.5, with an associated value of logEM(cid:39)49.7. The discrepancy in emission measure might be expected given the relatively low spatial resolution of the SH- Fig. 11. Simulated high-energy coronal emission vs. unsigned radial ZDImapdrivingthesimulation(Sections2and4.4).Thepeak magneticflux(cid:104)Φ (cid:105).Eachpointcorrespondstooneofthesimulations Br s temperature is also slightly lower than what might be expected describedinSect.4,includingthesolarcasesasindicated.Thesevalues based on the emission measure distribution and the observed arecalculatedfromsyntheticspectra,basedontheEM(T)distributions peaktemperatureofHD22049. (Sect.5.1),andintegratedintheSXR(2−30Å,green),X-ray(5−100Å, In the case of HD 1237, there are no observational con- red)andEUV(100−920Å,blue)bands.Thesolidlinescorrespondto straintsintheliteratureregardingtheEMdistribution.Fromthe fitstothesimulateddatapoints.Thedashedlinesarebasedonobserva- numericalsimulations,weobtainpeakvaluesoflogEM(cid:39)49.3 tionalstudiesusingX-ray,againstmagneticfieldmeasurementsusing atlogT∼6.5fortheZDIcase,andlogEM(cid:39)50.2atlogT∼6.7 ZB(Pevtsovetal.2003)andZDI(Vidottoetal.2014). fortheSH-ZDIcase. Inallthestellarcases,thesimulatedEM distributionsshow respect to the large-scale magnetic field flux (recovered with maximaclosetotheexpectedvaluesforstarswithintheconsid- ZDI).Theyalsofoundapower-lawrelationforbothparameters eredlevelsofactivity(seeTable1).However,theemissionmea- (L ∝ Φ1.80±0.20). These observational results have been inter- suresaresystematicallylowerthanindicatedbyobservation. X B preted as an indication of a similar coronal heating mechanism ThebehaviourofthesimulatedEMdistributionforthesolar amongthesetypesofstars. maximum case (red line in Fig. 10) is particularly interesting, compared with the remaining simulations. Both the peak emis- In this context, we have considered this relation from a nu- sion measure and temperature are in good agreement with as- merical point of view, by simulating the coronal high-energy sessments from full solar disk observations (e.g. Laming et al. emission (based on the EM(T) distributions presented in the 1995; Drake et al. 2000). However, the observations indicate previous section) and comparing the predicted fluxes with the a slope in the EM vs. temperature of order unity or greater, underlying surface magnetic field flux distributions (ΦB = whereas the model prediction is much flatter. This results in a 4π|Br|R2∗). In this analysis, we have included the results from substantial over-prediction of the cooler emission measure at all the considered cases (e.g. solar and ZDI/SH-ZDI), treating temperatures logT ≤ 6 compared with observations. The so- the solutions independently. This allows us to explore a broad lar minimum EM distribution (yellow line in Fig. 10) is more rangeforbothparameters,whilemaintainingtheconsiderations similartothestellarcasesinthisregard.Thesedifferenceshave and limitations of the data-driven numerical approach. In prin- aconsiderableimpactinthepredictedcoronalemission,asdis- ciple, this can be also studied from a more generic numerical cussedinthenextsection. point of view (i.e. including different simulated field distribu- tions). However, this would require implicit assumptions about thefieldstrengthandspatialconfiguration(mostlyinfluencedby 5.2. High-EnergyEmissionandMagneticFlux thesolarcase),introducingstrongbiasesintheanalysis.There- foreconsideringthedifferentrecoveredfieldmaps(e.g.ZDI/SH- An observational study performed by Pevtsov et al. (2003) ZDI) as independent observations, represents a reasonable ap- showedarelationbetweentheunsignedmagneticfieldflux,Φ , B proximation. and the X-ray emission, L , covering several orders of mag- X nitude in both quantities (L ∝ Φ1.13±0.05). The analysis in- Spectraweresimulatedforeachoftheemissionmeasuredis- X B cludedvariousmagneticfeaturesoftheSun,togetherwithZee- tributions,EM(T),overtheX-rayandEUVwavelengthregimes, man Broadening (ZB) measurements of active dwarfs (spec- from1to1100Åona0.1Ågrid,coveringallthebandpassesof tral types F, G and K), and pre-main sequence stars (see Saar interest to this work. Emissivities were computed using atomic 1996). More recently, Vidotto et al. (2014) investigated the be- datafromtheCHIANTIdatabaseversion7.1.4(Dereetal.1997; haviour of various astrophysical quantities, including L , with Landi et al. 2013) as implemented in the Package for INTer- X Articlenumber,page10of15

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