------------------------------------------------------------------------ 6251.tex, A&A Letters, 2006, in press Content-Type: multipart/mixed; boundary="------------010902000606030003020103" X-MailScanner-Information: Please contact postmaster@aoc.nrao.edu for more information X-MailScanner: Found to be clean X-MailScanner-SpamCheck: not spam, SpamAssassin (score=0, required 5, autolearn=disabled) X-MailScanner-From: leo@ph1.uni-koeln.de X-Spam-Status: No This is a multi-part message in MIME format. --------------010902000606030003020103 Content-Type: text/plain; charset=ISO-8859-15; format=flowed Content-Transfer-Encoding: 7bit --------------010902000606030003020103 Content-Type: text/x-tex; name="6251.tex" Content-Transfer-Encoding: quoted-printable Content-Disposition: inline; filename="6251.tex" =20 \documentclass{aa} %[referee] % astro-ph/0610147 \usepackage{txfonts} \usepackage[ansinew]{inputenc} \usepackage{textcomp} \usepackage{graphicx} \usepackage{latexsym} %\usepackage{natbib} %\bibliographystyle{aa} \begin{document} \title{K-band polarimetry of an Sgr~A* flare with a clear sub-flare struc= ture\thanks{Based on observations at the Very Large Telescope (VLT) of th= e European Southern Observatory (ESO) on Paranal in Chile; Program: 077.B= -0552(A), PI: A. Eckart.}} \author{L. Meyer\inst{1}\thanks{Member of the International Max Planck Re= search School (IMPRS) for Radio and Infrared Astronomy at the Universitie= s of Bonn and Cologne.} \and R. Sch\"odel\inst{1} \and A. Eckart\inst{1} = \and V.~Karas\inst{2} \and M. Dov\v{c}iak\inst{2} \and W. J. Duschl\inst{= 3,4} } \institute{I.Physikalisches Institut, Universit\"at zu K\"oln, Z\"ulpiche= r Str. 77, 50937 K\"oln, Germany \and Astronomical Institute, Academy of = Sciences, Bo\v{c}n\'{i} II, CZ-14131 Prague, Czech Republic \and Institut= f\"ur Theoretische Physik und Astrophysik, Universit\"at zu Kiel, 24098 = Kiel, Germany \and Steward Observatory, The University of Arizona, 933 N.= Cherry Ave. Tucson, AZ 85721, USA } \date{Received / Accepted } %%%%% % \abstract {The supermassive black hole at the Galactic center, Sgr~A*, shows frequent radiation outbursts, often called 'flares'. In the near-infrared some of these flares were reported as showing intrinsic quasi-periodicities. The flux peaks associated with the quasi-periodic behavior were found to be highly polarized.} {The aim of this work is to present new evidence to support previous findings of the properties of the polarized radiation from Sgr~A* and to again provide strong support for the quasi-p= eriodicity of $\sim$$18\pm 3$\,min reported earlier.} {Observations were carried out at the European Southern Observatory's Very Large Telescope on Paranal, Chile. We used the NAOS/CONICA adaptive optics/near-infrared camera instrument. By fitting the polarimetric lightcurves with a hot-spot model, we addressed the question of whether the data are consistent with this model. To fit the observed data we used a general relativistic ray-tracing code in combination with a simple hot-spot/ring model.} {We report on new polarization measurements of a K-band flare from the supermassive black hole at the Galactic center. The data provide very str= ong support for a quasi-periodicity of $15.5\pm2$\,min. The mean polarization of the flare is consistent with the direction of the electric field vector that was reported in previous observations. The data can be modeled successfully with a combined blob/ring model. The inc= lination $i$ of the blob orbit must be $i > 20\degr$ on a 3$\sigma$ level= , and the dimensionless spin parameter of the black hole is derived to be $a_\star > 0.5$. } {} \keywords{black hole physics -- infrared: accretion, accretion disks -- G= alaxy: center} %\titlerunning{Constraints on the orbiting spot model for NIR Sgr~A* flar= es} \maketitle \section{Introduction} The radio, infrared, and X-ray source Sagittarius~A* (Sgr~A*) at the center of the Milky Way is generally accepted to be related to emission by plasma in the immediate environment of a $3.7\times10^{6}$\,M$_{\odot}$ black hole (e.g. Schoedel et al.~\cite{rainer1}; Ghez et al.~\cite{ghez}; Eisenhauer= et al.~\cite{eisenhauer}). With Eddington luminosities of $L_{\rm Edd} =3D 10^{-9}-10^{-10}$, it is = the most extreme sub-Eddington source accessible to observations. A characteristic feature of Sgr~A* is the so-called 'flares', short bursts of increased radiation that last for about 60-100\,min. These flares were first discovered at X-ray wavelengths, where the flux of Sgr~A* may rise by factors up to $\sim$100 during such an event (e.g. Baganoff et al.~\cite{baganoff}; Porquet et al.~\cite{porquet}; Eck= art et al.~\cite{ecki3}). At near-infrared (NIR) wavelengths, the flares show very similar timescales, but the flux varies only by factors of $\leq10$ (Genzel et al.~\cite{genzel}). Although the exact cause of the flares is still unclear, it is generally accepted that they are caused by synchrotron and synchrotron self-Compton emission processes within $\la 10$\,Schwarzschild radii ($\mathrm R_{S}$) of the black hole (Eckart et al.~\cite{ecki1}; Gillessen et al.~\cite{gillessen}). The non-= thermal nature of the flares has recently been shown directly by detecting polarized NIR radiation from Sgr~A* (Eckart et al.~\cite{ecki2}). The most intriguing feature related to these flares is quasi-periodic oscillations (QPOs) with a period of 17-22\,min, which have been detected in several of these events (Genzel et al.~\cite{genzel}; Belange= r et al.~\cite{belanger}; Eckart et al.~\cite{ecki2}; Meyer et al.~\cite{ich})= =2E These periodicities may be related to the high-frequency quasi-periodic oscillations (HFQPO) observed in some black hole binaries. These HFQPOs scale inversely with the root of the mass and are thought to be related to plasma in a relativistic flow within a few Schwarzschild radii of the black hole. Although their mechanism has still not been clearly understood, they appear to be promising tools in probing the space time around black holes (for a review of black hole binaries and HFQPOs, see Nowak \& Lehr~\cite{nowak} ; McClintock \& Remillard~\cite{mcclintock}). The QPOs observed in Sgr~A* are similar to HFQPOs in the sense that they appear to fit into the mass-scaling relationship. However, the exact relation between the XRB HFQPOs and Sgr~A* QPOs is not clear yet. In particular, XRB HFQPOs are observed at X-ray wavelengths, arise in thin accretion disks, and show amplitude modulations of just a few percent. No stationary thin disk is thought to be present in Sgr~A*, the QPOs are observed at NIR wavelengths, and they show a modulation of $>10\%$ (up to 50\% as reported in this paper).=20 The QPOs may provide the possibility of measuring the spin of the black hole (see, e.g., Genzel et al.~\cite{genzel}; Broderick \& Loeb~\cite{bro= derick1}; Meyer et al.~\cite{ich}). However, these QPOs have only been observed unambiguously in a few cases, which has raised some doubts about their nature, particularly whether they may just be related to a red-noise-like process in the source. This aspect is discussed extensively in Meyer et al.~(\cite{ich}) for the flare that shows the cle= arest evidence of quasi-periodicities. They conclude that the $\sim$17\,min periodicity reported by Genzel et al.~(\cite{genzel}) is most probably not due to red noise. The discovery by Eckart et al.~(\cite{ecki2}) that periodicities can show up in NIR polarized light, while at the same time being hardly visible in the total flux, raises the possibility that such periodicities may be present in most flares. However, due to the difficulties in NIR polarization measurements (e.g. need for excellent seeing, need for rapid change of polarization angles due to intrinsic variability of Sgr~A*), this observing window has only been ope= ned recently. So far, only two flares have been reported in NIR polarized light (Eckart et al.~\cite{ecki2}). Here we report on the recent NIR polarimetric observation of a new flare from Sgr~A*. The flare was exceptionally bright and shows intrinsic variability on a level of $\geq50\%$. \section{Observation and data reduction} =20 Using the NIR camera CONICA and the adaptive optics (AO) module NAOS on ESO's Very Large Telescope UT4 on Paranal in Chile, we observed Sgr~A* in the K$_S$-band during the night between 31 May and 1 June 2006. To achieve good time resolution, a Wollaston prism was combined with a half-wave retarder plate. This allows the simultaneous measurement of two orthogonal directions of the electric field vector and a rapid change between different angles.The detector integration time was 30\,s. Including the overheads due to the need to turn the half-wave plate and telescope offsets, individual frames could be taken every 70-80\,s. During the observation, the optical seeing ranged between 0.6\arcsec and 1\arcsec and the AO correction was stable. Sky measurements were taken by observing a dark cloud a few arc-minutes to the north west of Sgr~A*. To minimize the effects of dead pixels, the observations were dithered. The data were reduced in a standard way, i.e. sky subtracted, flat-fielded, and corrected for bad pixels. For every individual image, the point spread function (PSF) was extracted with the code {\it StarFinder} by Diolaiti et al.~(\cite{diolaiti}). Each= exposure was deconvolved with a Lucy-Richard deconvolution and restored w= ith a Gaussian beam. The flux of Sgr~A* and other compact sources in the = field was obtained via aperture photometry on the diffraction-limited images. The background flux density was determined as the mean flux measured with apertures of the same size at five different positions in a field that shows no individual stars. Photometric calibration was done relative to stars in the field with a known flux. For the extinction correction we assumed $A_K=3D2.8$\,mag. Estimates of uncertainties were obtained from the standard deviation of fluxes of nearby constant sources. The calibration was performed using the overall interstellar polarization of all sources in the field, which is 4\% at $25\deg$ (Eckart et al.~\cite{ecki95}; Ott et al.~\cite{ott}). Fig.~\ref{Fig:lightcurve} (top) shows the dereddened light curve of Sgr~A= * for all four measured polarization angles. Please note that the flux was calibrated relative to stars of known flux in the field-of-view for each angle separately. Therefore, the mean of the shown lightcurves is as high as the total flux of a source, i.e., actually the figure shows twice the flux for each angle (the same convention was used in Eckart et al.~\cite{ecki2}). \begin{figure} \centering=20 \includegraphics[angle=3D270,width=3D6.5cm]{pol2006_flux_calib_sgr.eps} \includegraphics[angle=3D270,width=3D6.5cm]{pol2006_flux_calib_comp.eps} \includegraphics[angle=3D270,width=3D6.5cm]{PA_31May2006.eps} \includegraphics[angle=3D270,width=3D6.5cm]{Poldeg_31May2006.eps} \caption{Dereddened flux of Sgr~A* (top) and of the two comparison stars W6 and S7 (second from top) at the different polarization angles. T= he comparison stars are located within $<1\arcsec$ of Sgr~A*. Due to the presence of two stellar sources at the position of Sgr~A* (see Fig.~1 in Eisenhauer et al.~\cite{eisenhauer}), its lightcurve stays at a constant level of about 5\,mJy after the flare. The light curves of the channels have been calibrated to an overall polarization of $4\%$ at an angle $25^\circ$ east of north (Eckart et al.~\cite{ecki95}; Ott et al.~\cite{ott}). Also, the curves ar= e shifted to the \emph{total} flux of the sources, i.e. the flux per channel is only half of the flux shown in the plots. The inferred polarization angle and = the degree of linear polarization of Sgr~A* can be seen in the bottom pan= els. \label{Fig:lightcurve}} \end{figure} \section{Observed variability of Sgr~A*} The light curve shown in Fig.~\ref{Fig:lightcurve} shows that two peaks, i.e. sub-flares, can be clearly distinguished at all four polarization angles. In contrast to the data of 2005 (Eckart et al.~\cite= {ecki2}), these two sub-flares show up clearly in each polarization channel. \begin{figure} \centering \includegraphics[angle=3D270,width=3D6.5cm]{PeriodoSgrA.eps} \caption{Periodogram of the light curves of Sgr~A* for all four observed polarization angles. The periodogram has been oversampled by a factor of 2. \label{Fig:period}} \end{figure} Fig.~\ref{Fig:period} shows a periodogram of the emission from Sgr~A* for the first 50\,min of the flare. For clarity, the periodogram has been oversampled by a factor of two. A clear peak is present at a period of $15.5\pm2$\,min. There is no indication of red noise. This was also checked by plotting a log-log version of the periodogram, where red-noise would show up as a straight line with slope one. It is certainly statistically questionable to infer quasi-periodicity from just two peaks. However, considering that very similar periodicities have already been reported fo= r several NIR flares clearly changes the picture. The probability of this happening in the case of pure red noise is extremely low (see discussion in Meyer et al.~\cite{ich}). The Stokes parameters $I$, $Q$, and $U$ were obtained by measuring the flux at position angles (PA) of the electric field vector of $0\degr$, $45\degr$, $90\degr$, and $135\degr$ (E of N). The total flux, the polarization angle, and polarization degree can be inferred from the sing= le polarization channels and are also shown in Fig.~\ref{Fig:lightcurve} (lower two panel= s). The PA of $80\degr \pm 10\degr$ during the sub-flares agrees very well with the value of $60\degr \pm 20\degr$ reported by Eckart et al.~(\cite{ecki2}). = This is a strong indication of a stable arrangement of the accretion flow with respect to the spin axis of the MBH, which may point to a permanent accretion ring with a radial extent of $\sim$\,2\,$R_S$ (see also Meyer et al.~\cite{ich}; Moscibrodska et al.~\cite{moscibrodzka}). Therefore the flow is probably not fully advective very close to the BH horizon. Since the accretion over a disk is more effective than that of an advective flow, solutions within radiatively inefficient accretion flows (RIAFs) might be preferred where $\dot{M}$ is small and the outflow is large. A striking feature is the large amplitude of the two sub-flares. It reaches about 50\% of the overall flare intensity. The observed frequencies of QPOs in X-ray binaries scale with the BH mass, which can be extrapolated to the mass of Sgr~A*. Therefore the large amplitude is remarkable since the amplitude of high-frequency QPOs observed for X-ray binaries shows variability amplitudes not larger than a few percent (see reviews by Nowak \& Lehr~\cite{nowak}; McClintock= \& Remillard~\cite{mcclintock}). The lightcurves show an interesting feature between $\sim$\,40\,--\,85\,m= in. The polarization degree rises sharply up to $\sim$\,30\% and the PA s= wings to 0\degr (see Fig.~\ref{Fig:lightcurve}). It is not clear whether= this is an effect intrinsic to Sgr~A*. The feature occurs after the brig= ht flare phase, when Sgr~A* is quiescent, i.e. in a low flux state. There= fore the polarization measurements are less certain. On the other hand, t= his feature shows some robustness, as it is visible before and after the = sky observations. Also, the FWHM of the PSFs that have been extracted fro= m each image shows no conspicuous behavior during that time, which means = that the AO correction is most probably not responsible for this property= of the lightcurves. It could be possible that this effect is a flare of = Sgr~A* that is mainly visible in polarization. A similar observation was = recently made by Eckart et al.~(\cite{ecki2}), who found that some sub-fl= ares may only show up in the polarized flux. \section{A plasma blob close to the BH horizon}=20 In this section we show that the observed polarimetric light curves are in excellent agreement with a combined hot spot/ring model. In this model the sub-flares are due to a blob on a relativistic orbit around the MBH, while an underlying ring accounts for the broad overall flare. Relativistic effects like beaming, lensing, and change of polarization angle imprint on the emitted intrinsic radiation (e.g. Dovciak et al.~\cite{dovciak}; Connors \& Stark~\cite{connors}; Hol= lywood \& Melia~\cite{hollywood2}; Broderick \& Loeb~\cite{broderick2}). = In our model we assume that the variability in the polarization angle and the polarization degree are only due to the= relativistic effects. As the emitted radiation of Sgr~A* is synchrotron radiation (emitted in the disk corona), we assumed two differ= ent magnetic field configurations to fit the light curves with our model. The first is analogous to a sunspot and results in a constant $E$-vector perpendicular to the disk. The second configuration is a global azimuthal magnetic field that leads to a rotation of the $E$-vector along the orbit. More details on the model and the fitting procedure can be found in Meyer et al.~(\cite{ich}). \begin{figure}[t] \centering \resizebox{7cm}{!}{\includegraphics[angle=3D270]{1.0_58_2006.eps}} \resizebox{7cm}{!}{\includegraphics[angle=3D270]{angle_1.0_58_2006.eps}} = \resizebox{7cm}{!}{\includegraphics[angle=3D270]{poldeg_1.0_58_2006.eps}}= \caption{The best fit solution (in red) for the constant $E$-vector case.= Shown is the flux (top), the polarization angle (middle), and the degree= of linear polarization (bottom). The parameters of the model are $i =3D = 58\degr$, $a_\star \approx 1$. The spot is orbiting at a \mbox{radius $r=3D= 4\,GM/c^2$.} The disk/ring and the spot both have an intrinsic polarizati= on degree of $\sim$\,17\%.} \label{fits} \end{figure} The fit with the least reduced-$\chi^2$ value is shown in Fig.~\ref{fits}. A dimensionless spin parameter of $a_\star \approx 1$ and an inclination of $i \approx 58\degr$ give the best solution. Only the time interval $\leq 30$\,min was fitted because the spot emission disappears afterwards. The magnetic field corresponds to the constant $E$-vector scenario, which gives better fits than the azimuthal-field case. It is also interesting that the best-fit values for the intrinsic polarization degree of the disk/rin= g and the spot are the same ($\sim$\,17\%). This is a profound difference= to the data presented by Eckart et al.~(\cite{ecki2}) where the spot was= intrinsically highly polarized ($\sim$\,50\%), while the disk was unpola= rized ($\sim$\,5\%). =20 \begin{figure}[t] \centering \resizebox{7cm}{!}{\includegraphics{Contours.eps}} \caption{Confidence contours for the constant $E$-Vector case (top) and t= he azimuthal magnetic field (bottom). The red (green) lines are chosen su= ch that the projection onto one of the parameter axes gives the 1$\sigma$= (3$\sigma$) limit for this parameter. The blue dashed lines indicate the= 3$\sigma$ contour for the 2005 data, analyzed by Meyer et al.~(\cite{ich= }). The $\chi^2$-minimum for the 2006 data is marked by the big cross. Th= e $\chi^2$-minimum of the 2005 epoch lies at $a_\star =3D 1$, $i=3D70\deg= r$ (top) and $a_\star =3D 0.5$, $i=3D70\degr$ (bottom). Our analysis is l= imited to $i \lessapprox 70^\circ $, see Meyer et al.~(\cite{ich}).} \label{conf} \end{figure} As noted by Meyer et al.~(\cite{ich}), a property of the model is a relatively weak dependence on the spin parameter. Figure~\ref{= conf} (top) shows the confidence contours for the constant $E$-Vector cas= e within the $a_\star$-$i$-plane. The spin parameter can only be constrai= ned to the region $a_\star \ga 0.5$ on a 3$\sigma$ level. Note that the o= bserved timescale of roughly 15\,min means that the spot is inside the le= ast stable orbit, i.e. freely falling, for $a_\star \la 0.6$. The inclina= tion is $i > 20\degr$ on a 3$\sigma$ level. The confidence contours for t= he azimuthal magnetic field are shown in Fig.~\ref{conf} (bottom). The mi= nimum $\chi^2$ value here is $1.2$ higher than in the upper case, indicat= ing a worse fit. The inclination can be constrained to $i \geq 55\degr$ o= n a $3\sigma$ level. Our results agree very well with Eckart et al.~(\cite{ecki2}) and Meyer et al.~(\cite{ich}) who analyzed polarimetric data from 2005 and found least $\chi^2$-values for high spin parameters ($a_\star \approx 1$) and high inclinations ($i \approx 70\degr$), but with the same characteristic of a weak dependence, see blue dashed lines in Fig.~\ref{conf}.=20 To progress in the descritpion of the Sgr~A* system, bright, strongly pol= arized sub-flares and a faint, low-polarized disk emission have to be obs= erved. Accurate data of this type not only could give tighter constraints= on the inclination and the spin parameter but also test the Kerr metric = qualitatively. Due to slightly different observed frequencies of the diff= erent epochs, a hot spot has to orbit on a slightly different orbit. But this should lead to the same spin parameter, as the mass of the BH is not expected to change significantly. Although it would actually be difficult to explain why a single blob survives that long in the place where shearing is enormous, the repeated observation of 16--20 min separation among individual sub-flares justifies our assumption that assigns the same confined region= to different peaks. This empirical indication can be taken as a constraint that needs to be imposed on theoretical models for the origin and confine= ment of blobs and the onset of flares in Sgr A*. { While the observation of QPOs seems to favor the orbiting spot model in= stead of an adiabatically expanding plasma blob, the model of relativisti= c plasma clouds expanding in a cone-jet geometry, in addition to suitable= instabilities within the jet, can account for the flares and sub-flares = of Sgr~A* as well (Yusef-Zadeh et al.~\cite{yusef}; Eckart et al.~\cite{e= cki1}). In fact, the inclusion of both models offers a possibility of lin= king the NIR/X-ray activity to the sub-mm/radio regime: a plasma blob tha= t is orbiting very close to the BH horizon (as described above) and then = adiabatically expanding along a short jet-like geometry or within its orb= it may explain the observed variability of Sgr~A* across all wavelengths.= } \begin{acknowledgements} We are grateful to C. Kiefer. This work was supported in part by the Deut= sche Forschungsgemeinschaft (DFG) via grant SFB 494. We want to thank all= members of the NAOS/CONICA and the ESO PARANAL team, especially N. Ageor= ges and M. Messineo for support in setting up the polarization measuremen= ts. \end{acknowledgements} %\bibliography{gc} \begin{thebibliography}{xxx}=20 %\bibitem[2004]{abramowicz} Abramowicz, M. A., Kluzniak, W., Stuchlik, Z.= , T\"or\"ok, G. 2004, in Proceedings of RAGtime %4/5 Workshops on black h= oles and neutron stars, edited by Hledik, S. ans Stuchlik, Z., Silesian U= niversity in Opava, p.~1 \bibitem[2001]{baganoff} Baganoff, F. K., Bautz, M. W., Brandt, W. N., et= al. 2001, Nature, 413, 45 %\bibitem[1972]{bardeen} Bardeen, J.~M., Press, W.~H., Teukolsky, S.~A. 1= 972, ApJ, 178, 347 \bibitem[2006]{belanger} Belanger, G., Terrier, R., De Jager, O., Goldwur= m, A., Melia, F. 2006, submitted to ApJL; astro-ph/0604337 %\bibitem[2001]{benlloch} Benlloch, S., Wilms, J., Edelson, R., Yaqoob, T= =2E, Staubert, R. 2001, ApJ, 562, L121 %\bibitem[2003]{bower} Bower, G. C., Wright, M. C. H., Falcke, H., Backer= , D. C., 2003, ApJ, 588, 331 %\bibitem[2004]{bozza} Bozza, V., Mancini, L. 2004, GReGr, 36, 435 \bibitem[2006]{broderick2} Broderick, A. E., Loeb, A. 2006, MNRAS, 367, 9= 05 \bibitem[2005]{broderick1} Broderick, A. E., Loeb, A. 2005, MNRAS, 363, 3= 53 %\bibitem[2001]{bromley} Bromley, B. C., Melia, F., Liu, S. 2001, ApJ, 55= 5L, 83B %\bibitem[2004]{bursa} Bursa, M., Abramowicz, M. A., Karas, V., Klu\'{z}n= iak, W., 2004, ApJ, L45 %\bibitem[1997]{coker} Coker, R. F., Melia, F. 1997, ApJ, 488L, 149C \bibitem[1977]{connors} Connors, P. A., Stark, R. F., 1977, Nature, 269, = 128 %\bibitem[1975]{cunningham} Cunningham, C. T., 1975, ApJ, 202, 788 %\bibitem[2003]{devilliers} De Villiers, J., Hawley, J. F., Krolik, J. H.= 2003, ApJ, 599, 1238 \bibitem[2000]{diolaiti} Diolaiti, E., Bendinelli, O., Bonaccini, D., et = al. 2000, A\&A Suppl., 147, 335 \bibitem[2004]{dovciak} Dovciak, M., Karas, V., Yaqoob, T. 2004, ApJS, 15= 3, 205 \bibitem[1995]{ecki95} Eckart, A., Genzel, R., Hofmann, R., Sams, B. J., = Tacconi-Garman, L. E. 1995, ApJ, 445L, 23 \bibitem[2004]{ecki3} Eckart, A., Baganoff, F. K., Morris, M., et al. 200= 4, A\&A, 427, 1 \bibitem[2006a]{ecki1} Eckart, A., Baganoff, F. K., Sch\"odel, R., et al. 2006a, A\&A, 450, 535 \bibitem[2006b]{ecki2} Eckart, A., Sch\"odel, R., Meyer, L., et al. 2006b, A\&A, 455, 1 \bibitem[2005]{eisenhauer} Eisenhauer, F., Genzel, R., Alexander, T., et = al. 2005, ApJ, 628, 246 %\bibitem[2000]{falcke} Falcke, H., Melia, F., Agol, E. 2000, ApJ, 528L, = 13F \bibitem[2003]{genzel} Genzel, R., Sch\"odel, R., Ott, T., et al. 2003, Nature, 425, 934 \bibitem[2005a]{ghez} Ghez, A.~M., Salim, S., Hornstein, S. D., et al. 2005a, ApJ, 620, 744 %\bibitem[2005b]{ghez2} Ghez, A. M., Hornstein, S. D., Lu, J. R., et al. = 2005b, ApJ, 635, 1087G \bibitem[2006]{gillessen} Gillessen, S., Eisenhauer, F., Quataert, E., et= al. 2006, ApJ, 640, L163 %\bibitem[2004]{hirose} Hirose, S., Krolik, J. H., DeVilliers, J.-P., Haw= ley, J. F., 2004, ApJ, 606, 1083 %\bibitem[1995]{hollywood} Hollywood, J. M., Melia, F., Close, L. M., McC= arthy, D. W. Jr., Dekeyser, T. A. 1995, ApJ, 448L, %21H \bibitem[1997]{hollywood2} Hollywood, J. M., Melia, F. 1997, ApJS, 112, 4= 23=20 %\bibitem[2006a]{horak1} Hor\'ak, J., Karas, V. 2006a, MNRAS, 365, 813 %\bibitem[2006b]{horak2} Hor\'ak, J., Karas, V. 2006b, PASJ, 58, 203 %\bibitem[2002]{krolik} Krolik, J. H., Hawley, J. F. 2002, ApJ 573, 754 = %\bibitem[2002]{liu} Liu, S., Melia, F. 2002, ApJL, 566, L77 %\bibitem[2006]{liu2} Liu, S., Melia, F., Petrosian, V. 2006, ApJ, 636, 7= 98 %\bibitem[2004]{lourakis} Lourakis, M. I. A. 2004, levmar:Levenberg-Marqu= ardt nonlinear least squares algorithms in C/C++, %webpage: www.ics.forth= =2Egr/$\sim$lourakis/levmar/ %\bibitem[1979]{luminet} Luminet, J.-P., 1979, A\&A, 75, 228 %\bibitem[2003]{machida} Machida, M., Matsumoto, R. 2003, ApJ, 585, 429 %\bibitem[2001]{markoff} Markoff, S., Falcke, H., Yuan, F., Biermann, P. = L. 2001, A\&A, 379, L13 %\bibitem[1973]{mashhoon} Mashhoon, B., 1973, Phys. Rev. D, 7, 2807 %\bibitem[2005]{mauerhan} Mauerhan, J. C., Morris, M., Walter, F., Bagano= ff, F. K. 2005, ApJ, 623, L25 \bibitem[2004]{mcclintock} McClintock, J. E., Remillard, R. A. 2004, Chap= ter 4 in "Compact Stellar X-Ray Sources", eds. Lewin, W. H. G., van der K= lis, M., Cambridge University Press. %\bibitem[1984]{meyer} Meyer, F., 1984, A\&A, 131, 303 \bibitem[2006]{ich} Meyer, L., Eckart, A., Sch\"odel, R., et al. 2006, A\= &A, in press=20 \bibitem[2006]{moscibrodzka} Moscibrodzka, M., Das, T. K., Czerny, B. 200= 6, MNRAS, 370, 219 \bibitem[1998]{nowak} Nowak, M., Lehr, D. 1998, in "Theory of Black Hole = Accretion Disks", eds. Abramowicz, M. A., Bjornsson, G., Pringle, J. E., = Cambridge University Press, p.233; eprint: astro-ph/9812004 \bibitem[1999]{ott} Ott, T., Eckart, A., Genzel, R., 1999, ApJ, 523, 248 %\bibitem[1981]{pineault} Pineault, S. 1981, ApJ, 246, 612 \bibitem[2003]{porquet} Porquet, D., Predehl, P., Aschenbach, B., et al. = 2003, A\&A, 407, L17 %\bibitem[1994]{rauch} Rauch, K. P., Blandford, R. D., 1994, ApJ, 381, 39= %\bibitem[2005]{schnittman} Schnittman, J. D., 2005, ApJ, 621, 940 %\bibitem[2006]{tagger} Tagger, M., Melia, F. 2006, ApJ, 636L, 33T %\bibitem[1995]{timmer} Timmer, J., K\"onig, M. 1995, A\&A, 300, 707 \bibitem[2002]{rainer1} Sch\"odel, R., Ott, T., Genzel, R., et al. 2002, Nature, 419, 694 %\bibitem[2003]{rainer2} % Sch\"odel, R., Genzel, R., Ott, T., et al. 2003, ApJ, 596, 1015 %\bibitem[1973]{shakura} Shakura, N. I., Sunyaev, R. A. 1973, A\&A, 24, 3= 37 %\bibitem[2005]{vaughan} Vaughan, S. 2005, A\&A, 431, 391 %\bibitem[1993]{viergutz} Viergutz, S. U., 1993, A\&A, 272, 355 %\bibitem[2003]{yuan1} Yuan, F., Quataert, E., Narayan, R. 2003, ApJ, 598= , 301 %\bibitem[2004]{yuan2} Yuan, F., Quataert, E., Narayan, R. 2004, ApJ, 606= , 894 \bibitem[2006]{yusef} Yusef-Zadeh, F., Roberts, D., Wardle, M., Heinke, C= =2E O., Bower, G. C., 2006, ApJ, in press, eprint: astro-ph/0603685 \end{thebibliography} \end{document} --------------010902000606030003020103--