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Astron. Astrophys. 357, 169176 (2000)

ASTRONOMY AND ASTROPHYSICS

The dynamical evolution of the fragmented, bipolar dust shell around the carbon star IRC +10 216
Rapid changes of a PPN-like structure?
Ё R. Osterbart1 , Y.Y. Balega2 , T. Blocker1 , A.B. Men'shchikov1,3 , and G. Weigelt1
1 2 3

Ё Ё MaxPlanckInstitut fur Radioastronomie, Auf dem Hugel 69, 53121 Bonn, Germany (osterbart@mpifr-bonn.mpg.de; bloecker@mpifr-bonn.mpg.de; weigelt@mpifr-bonn.mpg.de) Special Astrophysical Observatory, Nizhnij Arkhyz, KarachaevoCherkesia, 357147, Russia (balega@sao.ru) Ё Stockholm Observatory, 133 36 Saltsjobaden, Sweden (sasha@astro.su.se)

Received 16 June 1999 / Accepted 26 January 2000

Abstract. We present highresolution J , H , and K band observations and the first H - K color image of the carbon star IRC +10 216. The images were reconstructed from 6 m telescope speckle interferograms using the bispectrum speckle interferometry method. The H and K images with resolutions between 70 mas and 92 mas consist of several compact components within a 0. 2 radius and a fainter asymmetric nebula. The brightest four components are denoted with A to D in the order of decreasing brightness in the 1996 image. A comparison of our images from 1995, 1996, 1997, and 1998 gives -- almost like a movie of five frames -- insight into the dynamical evolution of the inner nebula. For instance, the separation of the two brightest components A and B increased from 191 mas in 1995 to 265 mas in 1998. At the same time, component B is fading and the components C and D become brighter. The Xshaped bipolar structure of the nebula, most prominently present in the J band image, implies an asymmetric massloss. Such asymmetries are often present in protoplanetary nebulae but are unexpected for AGB stars. IRC +10 216 is thus likely to be very advanced in its AGB evolution, shortly before turning into a protoplanetary nebula. The cometary shapes of A in the H and J images and in the 0.79 µm and 1.06 µm HST images suggest that the core of A is not the central star, but the southern lobe of a bipolar structure. The position of the central star is probably at or near the position of component B, where the H - K color has a value of 4.2. If the star is at or near B, then the components A, C, and D are likely to be located at the inner boundary of the dust shell. Key words: techniques: image processing stars: carbon stars: circumstellar matter stars: individual: IRC +10 216 stars: mass-loss stars: AGB and post-AGB

1. Introduction IRC +10 216 (CW Leo) is the nearest and beststudied carbon star and one of the brightest infrared sources. It experiences a strong mass loss at a rate of M 2 - 5 в 10-5 M yr-1 (see e.g. Loup et al. 1993). The central star of IRC +10 216 is a longperiod variable star (LPV) with a period of approximately 649 days (Le Bertre 1992). Recent distance estimates of 110 pc to 135 pc (Groenewegen 1997) and 150 pc (Crosas & Menten 1997) were reported. IRC +10 216's initial mass can be expected to be close to 4 M (Guelin et al. 1995; Weigelt et al. 1998). The bipolar appearance of the nebula around this object was already reported by Christou et al. (1990) and Kastner & Weintraub (1994). The non-spherical structure is consistent with the conjecture that IRC +10 216 is in a phase immediately before entering the protoplanetary nebula stage. High resolution observations of this object and its circumstellar dust shell were reported by McCarthy et al. (1990), Christou et al. (1990), Dyck et al. (1991), Danchi et al. (1994), Osterbart et al. (1997), Weigelt et al. (1997, 1998, 1999), Skinner et al. (1998), and Haniff & Buscher (1998). The results of Dyck et al. (1991) and Haniff & Buscher (1998) showed that the structure of the dust shell of IRC +10 216 has been changing for some years. Detailed radiative transfer calculations for IRC +10 216 were reґ cently performed by Ivezic & Elitzur (1996), Crosas & Menten (1997), and Groenewegen (1997) using a large amount of spectroscopic and visibility data. The aim of this paper is to discuss the properties of the inner dust shell of IRC +10 216 on the basis of a series of highresolution observations. In a second paper (Men'shchikov et al., in prep.) we will present a detailed twodimensional radiative transfer model for this object. 2. Observational results The IRC +10 216 speckle interferograms were obtained with the 6 m telescope at the Special Astrophysical Observatory in Russia and our Nicmos 3 camera at four epochs and with our Hawaiiarray camera at one epoch (Nov. 1998). Table 1 lists the observational parameters.

Send offprint requests to: G. Weigelt based on observations performed with the 6 m telecope at the Special Astrophysical Observatory, Russia

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R. Osterbart et al.: The evolution of the dust shell of IRC +10 216 Table 1. Observations. The center wavelengths (c ) and FWHM bandwidths () of the filters are given in µm. NT and NR are the numbers of target speckle interferograms for IRC +10 216 and reference star speckle interferograms (SAO 116569, SAO 116569, HIP 51133, HIP 47959, HIP 51133, HIP 52689, HIP 52689, HIP 50792, HIP 49583 from top to bottom). T is the exposure time per frame in ms, S is the seeing, and p is the pixel size in mas. Date 8 Oct. 8 Oct. 2 Apr. 3 Apr. 3 Apr. 23 Jan. 23 Jan. 14 Jun. 3 Nov. 1995 1995 1996 1996 1996 1997 1997 1998 1998 Filter c / 2.17/0.02 2.12/0.02 1.24/0.28 2.17/0.02 2.17/0.33 1.64/0.31 2.19/0.41 2.17/0.33 2.20/0.20 NT 216 251 1196 1112 1403 1665 2165 800 1087 NR 253 266 981 1639 1363 2110 1539 571 842 T 100 100 200 100 70 100 50 50 40 1. 1. 1. 1. 2. 1. 0. 1. 1. S 5 5 2 6 5 5 9 6 3 p 31.5 31.5 14.6 30.6 14.6 19.8 30.6 30.6 27.2

2.1. J -, H -, and K -band reconstructions Figs. 1 and 2 show the K and H images, respectively, of the central region of IRC +10 216 for all epochs. The highresolution images were reconstructed from the speckle interferograms using the bispectrum speckle interferometry method (Weigelt 1977; Lohmann et al. 1983; Weigelt 1991). The achieved resolution of the images depends slightly on the data quality (seeing and number of recorded interferograms) and is indicated in the figure captions. The object power spectra were determined with the speckle interferometry method (Labeyrie 1970). The speckle transfer functions were derived from speckle interferograms of the unresolved stars mentioned in Table 1. We denote the resolved components in the center of the nebula as A, B, C, and D (see Figs. 1g and 2b) in the order of decreasing peak intensity (based on the K band results from 1996). In addition, Fig. 2b shows three fainter components denoted with E, F, and G. In Fig. 2c, cuts through the centers of components A and B of the H and K images from 1997 are shown to illustrate the differences in the relative intensities of A and B for different wavelengths. Fig. 3 shows images of the faint nebula around IRC +10 216, which seems to have a bipolar structure. The resolution of these images was reduced to 149 mas (J ) and 95 mas (H and K ) to increase the signaltonoise ratio in the outer parts of the nebula. The faint granular structure of the images ( 0.5% of the peak intensity) is partly caused by speckle noise. Note that the faint extended feature at position angle PA 340 in the J image corresponds quite well to a very faint component (denoted with E in Figs. 1g and 2b) visible in all images in Figs. 1 and 2 (assuming that the brightest component in the J image is roughly coinciding with component A in the H and K images). Two other faint features at PA 20 and PA 50 (F and G in Fig. 2b) are only visible in some of the images. 2.2. Polarimetry Fig. 4 shows the results of polarimetric observations with the HST Nicmos camera at a wavelength of 1.1 µm (raw data retrieved from the Hubble Data Archive, STScI). The data were obtained on April 30, 1997 at a photometric phase of = 0.76. Data for three polarization angles were available (0 , 120 , and 240 ). It has been carefully checked that the three images were correctly registered. The images have been obtained without new pointing of the telescope so that no correction was necessary (see Voit 1997). From the data the total intensity (contours in Fig. 4a and b), the polarized intensity (Fig. 4c), the degree and the position angle of the polarization have been derived (see e.g. Voit 1997; Fischer et al. 1994). Fig. 4b shows the derived polarization map superimposed on the contours of the total intensity. In Fig. 4a the two images were superimposed by centering the brightest peaks onto each other. Looking at the southern tails of A and at the northern arms this centering seems to be appropriate. The structure of the 1.1 µm HST image at the position of B is affected by the diffraction pattern of A. Nevertheless, the

J K H K K

contours indicate that a structure corresponding to B might be present in the 1.1 µm image. 2.3. The core structure and the faint nebula The multicomponent structure of the IRC +10 216 K band image (of the innermost 300 mas в 300 mas) has already been reported by Weigelt et al. (1998) and Haniff & Buscher (1998). This bright inner region is surrounded by a larger faint nebula (with 1% of the peak brightness of A; see Fig. 3b and c). Three arms of the nebula can be seen at position angles of 30 (NE), 340 (NW), and 210 (SW) with respect to component A. At 160 (counterside of the NW-arm) the nebula is much fainter. The direction from component A to component B (PA20 ) can be taken as the direction of the main axis (see also Kastner & Weintraub 1994). This direction fits well to the main axis of the H13 CN(J = 1 - 0) emission (Dayal & Bieging 1995) which is weakly elongated on a scale of about 10 . On larger scales asymmetries are not observed (Dayal & Bieging 1995; Groenewegen et al. 1997; Mauron & Huggins 1999). 2.4. The bipolar structure in J and at shorter wavelengths The J band image (Fig. 3a) and the 0.79 µm and 1.06 µm HST images (Haniff & Buscher 1998; Skinner et al. 1998, see also Fig. 4a for the total intensity of the HST 1.1 µm polarization data) show a bipolar shape of the nebula. The southern lobe has a cometary or fanshaped structure whereas the northern area of the images shows two arms reminiscent to (but weaker than) the northern Xshaped structure of the Red Rectangle (see, e.g., Men'shchikov et al. 1998). However, the fact that even in the polarized intensity the nebula is very faint on the southeastern side suggests the main axis to be at PA20 to 30 . 2.5. H - K color image For the January 1997 data, the integral intensities in the full fields of view of our camera (5. 1in H and 7. 8in K ) were compared

R. Osterbart et al.: The evolution of the dust shell of IRC +10 216
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Fig. 1. a to e: Highresolution bispectrum speckle interferometry images of IRC +10 216. North is up and east to the left. The figures represent a time series showing the evolution of the subarcsecond structure of IRC +10 216 from 1995 (top) to 1998 (bottom). In all figures the same gray level corresponds to the same relative intensity measured with respect to the peak. f to j: Same as a to e but as contour representation (contours at every 0m 3 down to 4m 8 relative to the respective peak). The resolu. . tions of the images are 92 mas (a, f), 82 mas (b, g), 87 mas (c, h), 87 mas (d, i), and 75 mas (e, j). In panel g the denotation for the components A to E is shown. In all figures the epoch of the observation, the filter wavelength and the photometric phase are indicated. k Cuts through the images a to e along the axis from component A to B (position angle 20 )

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Fig. 2. a 70 mas resolution bispectrum speckle interferometry image of IRC +10 216 in the H band. North is up and east to the left. b Same as a as a contour image with denotations (A to G) of compact structures. Contours are at 5m 0 to 0m 2 relative to the peak in steps of 0m 2. c . . . Normalized cuts through the H band image a and the K band image of the same epoch (Fig. 1c) in the direction of the components A and B (position angle 20 ) illustrating the differences in the relative intensities of A and B for the different wavelengths
a b c

0.5"

J 4/96

0.5"

H 1/97

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Fig. 3. a J band speckle reconstruction of IRC +10 216 with 149 mas resolution showing the bipolar structure of the nebula. b H band speckle reconstruction of IRC +10 216 with reduced resolution of 95 mas to increase the signaltonoise ratio in the faint parts of the nebula. c Same as b for the K band

to those of the photometric standard stars HIP 71284 (BS 5447) and HD 106965 (cf. Elias et al. 1982). The resulting IRC +10 216 magnitudes are K = 2.3 and H = 5.4. According to an extrapolation of the fitted light curve of Le Bertre (1992), IRC +10 216 was very close to its light minimum in January 1997. Our magnitudes are in good agreement with this prediction. In a square aperture of 1. 6 the magnitudes can be determined to be K = 2.5 ± 0.1 and H = 5.7 ± 0.1. The integral color in this field is thus H - K 3.2. The resolved twodimensional H - K color image is shown in Fig. 5 together with the contours of the H band image. The H and K images used for the determination of the H - K color were reconstructed with a common resolution of 95 mas which is also the resolution of the color image. The dependence of the H - K color image on relative shifts between the two images was investigated because it is not

a priori known whether the positions of the intensity maxima in H and K coincide. The relative position of the components A and B is very similar in the H and K images from 1997 so that a solution could be found where both components A and B are almost coinciding (within a few mas) for the two images. We found that the color image is not very sensitive to relative shifts within the realistic uncertainties of some milliarcseconds. 2.6. Separation of components A and B Fig. 6 shows the separation of the components A and B in the K band images for different epochs. Phase 0 in Fig. 6 corresponds to JD=2449430. This date of the photometric maximum was derived from the results of Le Bertre (1992). The separations are: 191 mas, 201 mas, 214 mas, 245 mas, and 265 mas, for

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250 mas

H image 1.1µm contours

250 mas

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250 mas

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Fig. 4. a Superposition of the total intensity at 1.1 µm (contours are at 5m 0, 4m 2, 3m 4, 1m 8, and 1m 0 relative to the peak) derived from the . . . . . archival HST polarization data and the negative H speckle image. b 1.1 µm polarization map. The same contours as in frame a are shown. c Polarized intensity at 1.1 µm. The contours are plotted from 2m 4to6m 0 difference relative to the peak of the total intensity in steps of 0m 6 . . . Table 2. Apparent velocities of components A, B, C, D, and E with respect to A, B, the center between A and B, and the center between A, B, C, and D, respectively. A B AB A B C D E 23 8 21 39 23 7 7 25 (14) (5) (5) (15) center center ABCD 11 11 -2 9 31 (7) (7) (-1) (5) (19) 14 10 0 6 31 (9) (6) (0) (4) (19)

mas/yr (km/s at D = 130 pc) (14) (5) (13) (24)

the 5 epochs from 1995 to 1998 shown in Fig. 1. The linear regression fit gives a value of 23 mas/yr for the average increase in the apparent separation of the components. Interpreting this increase as a real motion would lead to 14 km/s within the plane of the sky (for a distance of D = 130 pc). The apparent relative motion of the nebula components is obviously not simply related to the stellar variability which has a period of approximately 649 days (Le Bertre 1992). It may thus be related to either an overall expansion of an inhomogeneous circumstellar dust medium or a variability of the dust shell with a period significantly larger than the stellar pulsation period (cf. Fleischer et al. 1992; Winters et al. 1994, 1995). Table 2 lists the apparent relative velocities within the plane of the sky of the components A to E with respect to either A or B or the center positions defined by A and B or by A, B, C, and D. The values were determined from linear regression fits. 2.7. Structural changes within the nebula The images by Haniff & Buscher (1998) taken in 1989 and 1997, as well as the onedimensional data collected by Dyck et al. (1991) covering a larger range of epochs, already show that the structure of the envelope changes on time scales of some years.

H-K 100 mas

Fig. 5. H - K color image of the central region of IRC +10 216 in January 1997. Darkest gray corresponds to H - K = 4.6 and white corresponds to H - K = 2.1. The color at the position of the brightest component (A) is H - K = 3.2. The contours are those of the H band image with a spacing of 0m 5 .

Our K band observations now allow us to study the changes within approximately 2 stellar pulsation cycles in more detail. Besides the apparent motion of the components, Fig. 1 shows that these components change their shapes and relative fluxes. The brightest component A appears to be rather symmetric in 1995. At the later epochs it approximately keeps its size perpendicular to the axis AB (20 ) but becomes narrower along this axis. The peaktopeak intensity ratio of B and A is approximately constant from 1995 to 1997. Thereafter the component B started fading. At the same time the other components become brighter and detached from A. Note that the photometric

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does not coincide with A but is located significantly north of it, supports our interpretation that A is not the star. 3.2. Is the star at or near the position of B? In the following (a to d) we will argue that the assumption that the star is at or near the position of B is consistent with the observations. (a) The cometary shapes of A in the H and the J images and the 0.79 µm and 1.06 µm HST images (Haniff & Buscher 1998), as well as the polarization data strongly suggest that A is part of a scattering lobe within a bipolar structure. Consistently, A and its southern tails are relatively blue (H - K ranging from 2 to 3.2 in Fig. 5) compared to the integral color. (b) The northern components B, C, and D are, on the other hand, rather red (H - K 4.2) in comparison with the integral color. This suggests that these structures are strongly obscured and reddened by circumstellar dust. (c) The brightest northern component in the J image (Fig. 3a) can hardly be seen in the H image and is thus very blue. It has a separation of 500 mas from A at a position angle of 27 . In the K band image from the same epoch (Fig. 1b) component B is at a separation of 200 mas and at a position angle of 21 . This means that B is almost in the center between the northern Xshaped J -band component and the southern cometary component A (see Sect. 2.4). This morphology suggests that the latter components are the opposite lobes of a bipolar structure around a central star approximately located at the position of B. (d) The polarization map (Fig. 4b) fits well with the picture that the star is at B. The region between the two J band lobes is only weakly polarized with polarization null points in the east and northwest. Such null points indicate a transition from an optically thick region with multiple scattering to a region with predominantly single scattering of photons (Piirola et al. 1994; Fischer et al. 1994, 1996). The center of the centrosymmetric polarization pattern is located between the two lobes. Because of the scatter in the direction of the polarization vectors it is not possible to determine very precisely if the center coincides with B, but the polarization pattern is consistent with this assumption. We note that at the position of B the polarized intensity (Fig. 4c) may be slightly contaminated by the wings of the HST diffraction pattern associated with the dominant component A. The polarimetry of A itself, however, is not affected. Since the polarimetric features discussed above and in Sect. 3.1 are only slightly influenced by this contamination, the conclusions drawn so far do not change. Changes in the mass loss rate. The change of the shape of component A and the fading of B can be attributed to an increasing mass loss which is accompanied by a gradual increase of the optical depth of the dust shell. This is most obvious for the later observation epochs, suggesting an enhanced mass loss since 1997. A strongly variable mass loss has, in fact, been predicted by theoretical models treating the dust formation mechanism in the envelopes of longperiod variable carbon stars (Fleischer et al. 1992; Winters et al. 1994, 1995). Periods of this mecha-

Fig. 6. Separation of the components A and B (see Sect. 2.6) as a function of time and photometric phase

phases of IRC +10 216 in January 1997 and November 1998 are almost identical. In fact, the integral K magnitudes were the same (K = 2.3). Again we find that the time scale for the changes seen in our images is significantly different from the period of the stellar pulsation. 3. Discussion The observations presented in the previous section as well as other highresolution observations (e.g. Haniff & Buscher 1998) provide detailed information on the variable structure in IRC +10 216. The question of where, behind all the dust, the central star is located, is of specific interest to understand the physical properties of the nebula. At short wavelengths the nebula shows a bipolar structure. A comparison of the observed structure with other bipolar nebulae like the Red Rectangle (Men'shchikov et al. 1998) suggests that the Xlike arms originate mainly from scattering of stellar light on the surfaces of cavities. The star is then at least partially obscured by an optically thick dust shell or torus. Haniff & Buscher (1998) argued convincingly that the main axis of the object is tilted with its southern side towards the observer. 3.1. Is component A the star? Motion of the components. From molecular line observations the terminal velocity of the expansion of the circumstellar envelope was found to be 14 to 15 km/s (Dayal & Bieging 1995; Gensheimer & Snyder 1997). The velocities of B and D (14 km/s and 13 km/s, resp.) with respect to A can, therefore, only be understood if the direction of motion is approximately within the plane of the sky. However, the structure of the bipolar nebula at short wavelengths shows that we are looking neither poleon nor edgeon at the nebula but at an intermediate viewing angle (e.g. 50 to 60 ). The assumption that A is the star is thus not satisfactorily consistent with our observation. Polarimetry. The synthetic polarization maps of Fischer et al. (1996) show that a significant polarization at the position of the star is only present for nearly edgeon configurations. The high degree of polarization of A ( 14%) is thus not in agreement with A being the star. At larger separations from A the polarization pattern is centrosymmetric. The center of such a pattern is thought to be at the position of the illuminating source (Fischer et al. 1994, 1996). The fact that in Fig. 4b this center

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nism may be significantly longer than the stellar pulsation period (Winters et al. 1995). An increasing optical depth of the inner dust shell also results in an increasing apparent separation of the dust shell structures. The apparent motion of the components is thus not solely determined by the velocity of the dust particles but also by the changes of the optical properties of the circumstellar dust. Alternative model: the star between A and B. From the present observational data it is not possible to exclude the possibility that the star may be located between A and B, close to B, or in the center of A, B, C, and D. In particular, the precision of the polarization map is not sufficient to conclude whether the star is at the position of B or only close to it. Radiative transfer modeling. An answer to the question of where the star is located requires radiative transfer calculations. In a second paper (Men'shchikov et al., in preparation), we will present the results of our twodimensional radiative transfer modeling showing that the shapes of A and B cannot be reproduced when assuming a position of the star between A and B. On the other hand, it was possible to reproduce these shapes and the intensity ratio of A and B in the case where the star is assumed to be at the position of B. Clear preference is thus given to the latter model. 3.3. Stellar evolution and bipolar structure IRC +10 216 is without doubt in a very advanced stage of its AGB evolution due to its long pulsational period, high mass-loss rate, and carbon-rich dust-shell chemistry indicating that a significant number of thermal pulses have already taken place. The star's initial mass can be estimated to be 4M ± 1M due to the observed isotopic ratios of C, N and O in the dust shell (Guelin et al. 1995) and the luminosity of the central star (Weigelt et al. 1998). Accordingly, the core mass should be 0.7 to 0.8M with corresponding thermal-pulse cycle times of 1 - 3104 yr Ё (Blocker 1995). Introducing the mean observed mass-loss rate to these thermal-pulse periods shows that the present stellar wind leads to a very effective erosion of the envelope per thermal pulse cycle, possibly as high as 1M /cycle. Consequently, the whole envelope may be lost during the next few thermal pulses leading to the termination of the AGB evolution. Thus, it is not unlikely to assume that IRC +10 216 has entered a phase immediately before moving off the AGB. This is strongly supported by the non-spherical appearence of its dust shell showing even bipolar structures. Unlike AGB stars, post-AGB objects as protoplanetary nebulae often expose prominent features of asphericities, in particular in axisymmetric geometry (e.g. Olofsson 1993, 1996). Accordingly, IRC +10 216 can be thought to be an object in transition. It is noteworthy that the establishment of bipolar structures, i.e. the metamorphosis into a protoplanetary nebulae, obviously already begins during the (very end of) AGB evolution. The clumpiness within the bipolar shape is probably due to small scale fluctuations of the dust condensation radius which, in turn, might be influenced by, e.g., giant surface convection cells (Schwarzschild 1975). The formation of giant

convection cells can be assumed to be a common phenomenon in red giants. The shaping of planetary nebulae can successfully be described by interacting stellar wind models (Kwok et al. 1978; Kahn & West 1985). Within this scenario a fast (spherical) wind from the central star interacts with the slow wind of the preceding AGB evolution. The slow AGB wind is asssumed to be non-spherical (axisymmetric) which leads to the observed morphology of planetary nebulae (Mellema 1996). The cause of an aspherical AGB mass loss is still a matter of debate. Different mechanisms to provide the required equatorial density enhancements are discussed (cf. Livio 1993). Among these, binarity is one channel including common envelope evolution and spin up of the AGB star due to the interaction with its companion (Morris 1981; Bond & Livio 1990). Not only stellar companions are found to be able to spin up the AGB star but also substellar ones as brown dwarfs and planets, most effectively by evaporation in the AGB star's envelope (Harpaz & Soker 1994; Soker 1997). Currently there is no observational evidence for a possible binary nature of IRC +10 216. The fact that the polarization pattern in the southeastern part of the nebula at 1.1 µm has a different orientation than in the rest of the nebula might be an indication of a second illuminating source. Mechanisms inherent to the star include rotation (Dorfi & Ё Hofner 1996; Garcia-Segura et al. 1999), non-radial pulsations (Soker & Harpaz 1992) and magnetic fields (Pacoli et al. 1992; Garcia-Segura et al. 1999). Both non-radial p-modes and magnetic fields appear to only be important for significant rotation rates. Often spin-up agents due to binarity are assumed. For instance, Groenewegen (1996) favours non-radial pulsation or an as yet unidentified companion which spun up the central star as the most likely explanation for the non-spherical shape of the dust shell of IRC +10 216. AGB stars are known to be slow rotators. Stars with initial masses below 1.3M can be expected to lose almost their entire angular momentum during the main sequence phase due to magnetic braking operating in their convective envelopes. Consequently, they are not believed to devolop non-spherical mass-loss due to rotation. Stars with larger initial masses are spun down due to expansion and mass loss in the course of evolution, but may achieve sufficiently high rotation rates at the end of their AGB stage (Garcia-Segura et al. 1999). Even small rotation rates influence dust-driven winds considerably, yielding a mass loss preferentially driven in the equatorial plane Ё (Dorfi & Hofner 1996). Furthermore, for supergiants leaving the Hayashi line, Heger & Langer (1998) found that significant spin up of the surface layers may take place. Thus, on second glance, inherent rotation might be able to support axisymmetric mass loss during the transition to the proto-planetary nebula phase for more massive AGB stars as IRC +10 216. 4. Conclusions We have presented high-resolution J , H , and K band observations of IRC +10 216 with the highest resolution so far at H of 70 mas. A series of K band images from five epochs between

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October 1995 and November 1998 shows that the inner nebula is non-stationary. The separations of the four dominant resolved components increased within the 3 years by up to 35%. For the two brightest components a relative velocity within the plane of the sky of about 23 mas/yr or 14 km/s was found. Within these 3 years the rather faint components C and D became brighter whereas component B faded. The general geometry of the nebula seems to be bipolar. We find that the most promising model to explain the structures and changes in the inner nebula is to assume that the star is at or near the position of component B. The star is then strongly but not totally obscured at H and K . Consistently component B is very red in the H - K color while A and the northern J band components are relatively blue. The polarization pattern with strong polarization in the northern arms and also a significant polarization in the peak supports this model. The inner nebula and the apparent motions seem to be rather symmetric around this position and the observed changes are consistent with the assumption of an enhanced mass loss becoming apparent at least in 1997. IRC +10 216 is without doubt in a very advanced stage of its AGB evolution. The observed bipolarity of its dust shell even reveals that it has possibly entered the phase of transformation into a protoplanetary nebula.
Acknowledgements. We thank the referee for valuable comments. This research has made use of the SIMBAD database, operated at CDS, Strasbourg, France. The HST images for the polarization analysis have been retrieved from the Hubble Data Archive operated at the STScI, Baltimore, USA.

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