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The Astrophysical Journal, in press Preprint typeset using LATEX style emulateapj v. 5/2/11
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arXiv:1701.00002v2 [astro-ph.HE] 4 Jan 2017
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HUBBLE SPACE TELESCOPE DETECTION OF THE MILLISECOND PULSAR J2124-3358 AND ITS FAR-ULTRAVIOLET BOW SHOCK NEBULA
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B. Rangelov1, G. G. Pavlov2, O. Kargaltsev1, A. Reisenegger3, S. Guillot3, M. van Kerkwijk4, and C. Reyes3
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The Astrophysical Journal, in press
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ABSTRACT
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We observed a nearby millisecond pulsar J21243358 with the Hubble Space Telescope in broad far-UV (FUV) and optical filters. The pulsar is detected in both bands with fluxes F (1250-2000 °A) = (2.5 ± 0.3) × 10-16 erg s-1 cm-2 and F (3800 - 6000 °A) = (6.4 ± 0.4) × 10-17 erg s-1 cm-2, which correspond to luminosities of 5.8 × 1027 and 1.4 × 1027 erg s-1, for d = 410 pc and E(B - V ) = 0.03. The optical-FUV spectrum can be described by a power-law model, f , with slope = 0.18 0.48 for a conservative range of color excess, E(B - V ) = 0.010.08. Since a spectral flux rising with frequency is unusual for pulsar magnetospheric emission in this frequency range, it is possible that the spectrum is predominantly magnetospheric (power law with < 0) in the optical while it is dominated by thermal emission from the neutron star surface in the FUV. For a neutron star radius of 12 km, the surface temperature would be between 0.5 × 105 and 2.1 × 105 K, for ranging from -1 to 0, E(B - V ) = 0.010.08, and d = 340500 pc. In addition to the pulsar, the FUV images reveal extended emission spatially coincident with the known H bow shock, making PSR J21243358 the second pulsar (after PSR J0437-4715) with a bow shock detected in FUV.
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Subject headings: pulsars: individual (PSR J2124-3358) -- shock waves -- ISM: jets and outflows -- ultraviolet: ISM, stars -- X-rays: individual (PSR J2124-3358)
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1. INTRODUCTION
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Although many rotation-powered pulsars have been detected in the radio, X-rays and -rays, only about a dozen of them have been detected in the UV-optical-IR (UVOIR) range (see Mignani 2011 for a review). Their optical spectra can be described by a power-law (PL) model, f , with slopes -1 0. The PL components of their X-ray spectra show a faster decrease with frequency, implying spectral break(s) between the optical and X-rays. This non-thermal emission is thought to be produced by relativistic electrons/positrons in the pulsar magnetosphere. In addition to the PL optical emission, several middle-aged (a few hundred kyr old) pulsars (e.g., PSR B0656+14 and Geminga) exhibit thermal (Rayleigh-Jeans) spectra, f 2, in the far-UV (FUV), originating from the surface of cooling neutron stars (NSs), with brightness temperatures of (28) × 105 K, usually somewhat lower than those inferred from thermal X-ray components (Kargaltsev & Pavlov 2007).
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As the temperature of a passively cooling NS sharply decreases at ages beyond about 1 Myr (Yakovlev & Pethick 2004), surfaces of old pulsars were expected to be very cold. However, our Hubble Space Telescope (HST) observations of the 7 Gyr old millisecond (recycled) pulsar J04374715 (J0437 hereafter), the only millisecond pulsar firmly detected in the UVOIR range5, have shown a thermal FUV spectrum emitted from the bulk NS sur-
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blagoy.rangelov@gmail.com 1 Department of Physics, The George Washington University,
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725 21st St, NW, Washington, DC 20052 2 Pennsylvania State University, 525 Davey Lab., University
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Park, PA 16802 3 Instituto de Astrofi´isica, Pontificia Universidad Cat´olica de
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Chile, Av. Vicun~a Mackenna 4860, Macul, Santiago, Chile 4 Department of Astronomy and Astrophysics, University of
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Toronto, 50 St. George Street, Toronto, ON M5S 3H4, Canada 5 Far-UV emission from the double pulsar J07373039, detected
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face with a temperature of about 2 × 105 K (Kargaltsev et al. 2004; Durant et al. 2012). This result suggests that some heating mechanism(s) operate throughout the life of NSs. To understand the nature of such mechanisms, we initiated an HST program to observe old pulsars in the FUV and optical bands. In this paper we report first results from this program, obtained from observations of PSR J21243358 (J2124 hereafter).
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J2124 is a solitary 4.93 ms pulsar with a spin-down energy loss rate E = 6.8 × 1033 erg s-1 and a characteristic age of 3.8 Gyr (Reardon et al. 2016). It was discovered during the Parkes 436 MHz survey of the southern sky (Bailes et al. 1997). J2124 has a parallax distance d = 410+-9700 pc and an accurately measured proper motion, µ cos = -14.14 ± 0.04 mas yr-1, µ = -50.08±0.09 mas yr-1(Reardon et al. 2016), corresponding to the transverse velocity V = 101.2±0.8 km s-1 (at d = 410 pc).
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X-ray pulsations from J2124 were found by Becker & Tru¨mper (1999) in ROSAT observations. XMM-Newton observations of J2124 have shown that a two-component model is required to fit its X-ray spectrum (Zavlin 2006). For example, a PL + H-atmosphere (polar cap) model with 1 - = 2.1 ± 0.7, Tpc = (1.3 ± 0.1) × 106 K, and Rpc = (0.74 ± 0.09)d410 km provides a reasonable description of the observed spectrum. Alternatively, a two-temperature H-atmosphere model (a hot polar cap "core" surrounded by a colder "rim"), with Tcore = (2.2± 0.5) × 106 K, Rcore = (0.17 ± 0.4)d410 km, Trim = (0.5 ± 0.1) × 106 K, Rrim = (2.9 ± 1.1)d410 km, describes the spectrum equally well (see also Bogdanov et al. 2008).
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J2124 was also detected by Fermi (see the 2PC LAT
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by Durant et al. (2014), likely comes from the millisecond pulsar J07373039A, but additional observations are needed to prove it.
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�2
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Rangelov et al. 2017
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catalog; Abdo et al. 2013). Its -ray spectrum can be characterized by a cut-off PL model with = 0.78 ± 0.13 and cut-off energy Ecut = 1.63 ± 0.19 GeV. The corresponding 0.1100 GeV energy flux is F = (3.68±0.16)× 10-11 erg s-1 cm-2. The best-fit is rather small for a pulsar (only 14% of pulsars in the 2PC LAT catalog have similar or smaller values).
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In the optical, J2124 was observed by the ESO Very Large Telescope (VLT) in 2001 using the FOcal Reducer and Spectrograph 1 (FORS1) camera. The pulsar was not detected, with limits of U 26, B 27.7, and V 27.8 (Mignani & Becker 2004).
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J2124 is among the 9 pulsars (including J0437) around which H bow-shock nebulae have been detected (Brownsberger & Romani 2014; Gaensler et al. 2002; see the H image in the bottom-right panel of Figure 1). H bow shocks are created by pulsars moving through the interstellar medium (ISM) at a speed exceeding the ISM sound speed, if there are enough neutral H atoms ahead of the pulsar. They are expected to be accompanied by cometary X-ray pulsar wind nebulae, which are produced by synchrotron radiation of the shocked pulsar wind confined by the ram pressure of oncoming medium (Kargaltsev & Pavlov 2008). A Chandra ACIS observation of J2124 revealed a puzzling faint X-ray nebula which looks like a one-sided, elongated structure projected within the interior of the H bow shock (Chatterjee et al. 2005; Hui & Becker 2006). This X-ray emission extends northwest of the pulsar by 0.5 (see the X-ray image in Figure 2), and its spectrum fits an absorbed PL with photon index = 2.2 ± 0.4 and luminosity L0.5-10 keV 2.4 × 1029d2410 erg s-1.
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In this paper we present an analysis of our HST observations of J2124 in optical and FUV bands (Section 2), resulting in detection of the pulsar in both bands (Section 2.2.1), and discovery of FUV emission from the bow shock (Section 2.2.2). We discuss the implications of our findings in Section 3.
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2. OBSERVATIONS AND RESULTS
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The HST observations of J2124 (program 13783, PI Pavlov; see Table 1) were carried out in three visits that occurred between 2014 November 15 and 2015 August 12. The data were taken with the Solar Blind Channel (SBC) detector of the Advanced Camera for Surveys (ACS; 34. 6×30. 8 field of view, 0. 034×0. 030 pixel scale) using long-pass filters F125LP and F140LP, and with the Wide Field Camera 3 (WFC3) Ultraviolet-Visible channel (UVIS; 162 × 162 field of view, 0. 04 pixel scale) in the very broad F475X (wide B) filter. The F125LP, F140LP and F475X filter pivot wavelengths are 1438, 1528, and 4939 °A, respectively. The throughputs of these filters are shown in Figure 3. The pulsar was placed close to the center of the SBC field-of-view for ACS observations and near the corner ( 11 away from the edges) of the UVIS2 chip in WFC3 observation. The chosen UVIS placement ensures that the pulsar is close to the readout, which minimizes the charge transfer efficiency (CTE) losses6. The FUV data were acquired during four orbits. The F125LP images were taken in the
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6 See Section 6.9 of the WFC3 Instrument Handbook; http://www.stsci.edu/hst/wfc3/documents/handbooks/ currentIHB/c06_uvis10.html.
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Table 1 HST observations of the J2124.
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Date
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2014-11-15 2015-07-14 2015-07-14 2015-08-12 2015-08-12
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Instrument
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WFC3/UVIS ACS/SBC ACS/SBC ACS/SBC ACS/SBC
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Filter
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F475X F125LP F140LP F125LP F140LP
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Exposure (s)
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2532 3688 1218 3688 1218
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Earth shadow, where the geocoronal FUV background is greatly reduced. The F140LP filter, which cuts off geocoronal emission shortward of 1400 °A, was used outside the shadow parts of the orbits. The UVIS/F475X exposure was taken during a single orbit. The data were downloaded from the Mikulski Archive for Space Telescopes (MAST7). Each MAST image is flat-field corrected using the PyRAF Multidrizzle task, which produces co-aligned images, corrected for geometrical distortion. We perform aperture photometry using the PHOT and POLYPHOT tasks in IRAF8.
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2.1. Astrometry
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To identify the pulsar in the HST images (see Figure 1), we had to check the astrometry of our data. We used stars from the Guide Star Catalog (GSC v.2.3) within the field of view of the WFC3/UVIS to improve the astrometry of the F475X image. Other catalogs with more precise coordinate measurements (e.g., 2MASS, UCAC4) had too few objects in the UVIS field of view. Moreover, most of these objects are bright stars, saturated in the UVIS image, which prevents accurate centroiding and renders them unsuitable for the astrometric correction. Prior to the correction, we found a systematic offset between the GSC v.2.3 and the UVIS stars to be 0. 4 (consistent with the typical HST pointing error9). We then selected 20 stars from the GSC with obvious UVIS counterparts suitable for accurate centroid determination. As these stars did not have proper motion measurements, we could not adjust their coordinates for the epoch of the HST observations. This can explain four outliers (i.e., UVIS stars having 3 times the mean offset from the catalog position), which we interpret as a proper motion effect. These stars were removed from our final sample of reference stars. We then used the IRAF task DAOFIND to find the detector coordinates of the centroids for the remaining 16 reference stars and supplied them to the IRAF task CCMAP10 to calculate new astrometric solution by matching these stars with their GSC counterparts. The refined astrometric solution has standard deviations = 0. 17 and = 0. 16 for the sample of 16 stars (at 68% confidence).
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In the SBC image only five sources are seen. Since none of them have counterparts in catalogs, we had to align the F125LP and F140LP images with the UVIS image. Three of the sources, seen in both the UVIS and SBC
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7 See http://archive.stsci.edu/. 8 IRAF is distributed by the National Optical Astronomy Ob-
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servatories, which are operated by the Association of Universities
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for Research in Astronomy, Inc., under cooperative agreement with
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the National Science Foundation. 9 See http://www.stsci.edu/institute/org/telescopes/
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Reports/Lallo_TIPS_19June08.pdf 10 See http://stsdas.stsci.edu/cgi-bin/gethelp.cgi?ccmap.
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�Optical-UV emission from pulsar J2124-3358
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3
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Figure 1. Smoothed HST F125LP (top left) and F140LP (top right) FUV images of the J2124 field (Gaussian smoothing with r = 0. 2 kernel). J2124 position is marked by small white circle. The bow shock (middle region, labeled as "S") and background (two outer regions, labeled as "B") extraction areas are shown in white in the top-right panel, while the pulsar motion is shown with a white arrow in the top-left panel. The SOAR H (bottom right) image (obtained from the SOAR archive and described in detail by Brownsberger & Romani 2014), smoothed with r = 1 kernel, shows the bow shock emission (J2124 position is marked by the white cross). The bow shock extraction region from the top-right panel is overploted. The bow shock is not visible in the F475X (bottom left) image. All images are to the same scale. North and east are shown in the equatorial coordinate system.
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images, were used in the alignment process. However, all three sources appear to be extended in both images (likely, they are background galaxies). This hinders accurate centroid determination leading to an uncertainty11 of 0. 1 in aligning the SBC images with the UVIS image.
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In the astrometry-corrected UVIS image we found a faint source located at = 21:24:43.841(16) and = -33:58:45.01(18). These coordinates are offset by cos = -0. 01 ± 0. 19 and = -0. 18 ± 0. 18 from the pulsar's radio coordinates ( = 21:24:43.841662(24) and = -33:58:45.1897(5)) expected at the epoch of the UVIS observation (MJD 56976). Since the offset is within the alignment uncertainty, we conclude that this
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is a very viable candidate for the pulsar counterpart12.
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2.2. Pulsar Photometry
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To find the optimal aperture for the photometry in SBC/F125LP image, we calculated the signal-to-noise (S/N ) ratio for a set of varying circular apertures centered on the source. The background was estimated from an annular region with rin = 20 and rout = 50 pixels (0. 64 and 1. 6, respectively) centered on the source. We found that the r = 5 pixels (0. 16) aperture provides a maximum S/N 9. This aperture corresponds to about 64% of the encircled energy, according to ACS Instru-
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11 Note that CCMAP calculates a "perfect" (no error) astrometric solution from three points (stars). The quoted uncertainty, 0. 1, was obtained by selecting different centroiding methods (brightness peak, weighted brightness center, brightest pixel), and selecting the mean and standard deviation as the true center and astrometric solution uncertainty, respectively.
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12 We attempted to improve the astrometry by matching GSC v.2.3 stars with UCAC4 stars within one degree from the pulsar. Using 370 matches for stars with magnitudes J 12, we found offsets 0. 012 ± 0. 111 and -0. 001 ± 0. 076 along R.A. and Decl., respectively. Since these offsets are statistically insignificant, the GSCUCAC4 matching does not improve the astrometry and does not change our conclusion.
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�4
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Rangelov et al. 2017
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Table 2 Pulsar and bow shock photometry.
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Filter
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F125LP F140LP F475X
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F125LP F140LP
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As arcsec2
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0.080 0.053 0.045
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52.1 52.1
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Ab arcsec2
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Ct cts s-1
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Pulsar 6.75 0.017 ± 0.002 6.75 0.008 ± 0.002 0.42 0.147 ± 0.008
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Bow shock 80.5 2.96 ± 0.02 80.5 2.99 ± 0.04
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Cb cts s-1
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0.213 ± 0.005 0.198 ± 0.009 0.061 ± 0.005
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3.70 ± 0.02 3.95 ± 0.04
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Cs cts s-1
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0.014 ± 0.002 0.007 ± 0.002 0.136 ± 0.008
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0.56 ± 0.02 0.43 ± 0.04
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Figure 2. Chandra ACIS-S smoothed (gaussian kernel r = 2 ) image of J2124. The FUV bow shock extraction region (labeled as `S' in Figure 1) is shown for comparison.
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0.30
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caused by the imperfect alignment.
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We repeated this procedure for the UVIS/F475X im-
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age, where the background was taken from an annulus
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with rin = 8 and rout = 12 pixels (0. 32 and 0. 48, respectively). We found the optimal extraction aperture
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of r = 3 pixels (0. 12), which corresponds to the encir-
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cled energy fraction of 78% and provides S/N 19.
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The net source count rate was calculated as Cs = Ct - Cb(As/Ab), where Ct is the total count rate in the source region of area As, and Cb is the background count rate in the region of area Ab. Correspondingly, the source count rate uncertainty was calculated as Cs = Ct + Cb(As/Ab)2 1/2 t-ex1p/2, where texp is the exposure time. The net count rates for the optimal apertures are
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given in Table 2.
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We then corrected the rates for the finite aperture sizes
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and followed standard photometry procedures to convert count rates to flux densities14. The observed mean flux
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densities for F125LP, F140LP, and F475X are 27 ± 4 nJy,
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25 ± 11 nJy, and 22 ± 2 nJy, respectively. For a plausible
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reddening E(B -V ) = 0.03 (see Section 2.3) these values
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correspond to dereddened flux densities of 35 ± 6 nJy,
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33 ± 15 nJy, and 24 ± 2 nJy, for F125LP, F140LP, and
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F475X, respectively.
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Throughput
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0.25
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0.20
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0.15
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0.10
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0.05
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1000 2000 3000 4000 5000 6000 7000 8000
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[Å]
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Figure 3. Throughputs of the F125LP, F140LP, and F475X filters (blue, red, and green lines, respectively).
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ment Handbook 13. Repeating the process for the F140LP image, we found an optimal aperture (S/N 3) of r = 4 pixels (0. 13) corresponding to the encircled energy fraction of 58%. The pulsar detection is less significant due to a factor of 6 smaller exposure time of the F140LP observations and a reduced throughput compared to F125LP. Note that the pulsar photometry was done on individual images to avoid additional broadening of the source
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13 See http://www.stsci.edu/hst/acs/documents/handbooks/ current/c05_imaging7.html#368448.
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2.3. Extinction
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To interpret the photometry results, we need to know the interstellar extinction toward J2124. The extinction coefficient A is proportional to the color excess E(B - V ), which, on average, is proportional to the hydrogen column density NH. Zavlin (2006) reported NH = (13) × 1020 cm-2 toward J2124 based on fits to the X-ray data. The dispersion measure, DM = 4.6 pc cm-3, leads to a similar NH = 1.4 × 1020 cm-2 (for an assumed 10% degree of ISM ionization). The relation NH = 2.2 × 1021RV E(B - V ) cm-2 (Gorenstein 1975; Gu¨ver & O¨ zel 2009), with the commonly assumed RV = 3.1, corresponds to E(B - V ) = 0.015 0.045. In our analysis below, we explore an even broader range of color excess, E(B - V ) = 0.010.08, to account for the additional uncertainty introduced by the NH-toE(B - V ) conversion. The upper bound on color excess, E(B - V ) = 0.08, in the direction to J2124 (l = 10. 9, b = -45. 4) is based on the Galactic extinction maps by Schlegel et al. (1998). To perform de-reddening, we use the extinction curves adopted from Clayton et al. (2003).
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2.4. Pulsar Spectral Fits
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14 See http://www.stsci.edu/hst/wfc3/phot_zp_lbn
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�Optical-UV emission from pulsar J2124-3358
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5
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Log(f) [nJy]
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2.5
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= 0. 28
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2.0 Ed =(B4-10Vp)c= 0. 03 U
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1.5
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VB
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F475X
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1.0
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F125LP
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0.154.4
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14.6
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14.8
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15.0
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15.2
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15.4
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Log() [Hz]
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Figure 4. Example of a single PL fit to the HST photometry results for the J2124 pulsar (the measurement in F140LP is not shown because its band is within the F125LP band). The blue dash-dot line shows the best-fit model spectrum at fixed d = 410 pc, reddened with E(B - V ) = 0.03. The downward arrows show the VLT limits reported by Mignani & Becker (2004). The errors for the F475X data point are comparable to the size of the dot. The black horizontal lines show the filter widths at half maximum.
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The photometric data in only 3 spectral bands (of which one, F140LP, is within the other, F125LP) can be fitted with many spectral models. We first fit the data with an absorbed PL model, f = f0 (/0) × 10-0.4A , which is often used to describe magnetospheric emission (Pavlov et al. 1997). We fit the PL slope and normalization f0 at 0 = 6.07 × 1014 Hz (corresponding to the pivot wavelength of the F475X filter) for 4 fixed values of color excess: E(B - V ) = [0.01, 0.03, 0.05, 0.08]. An example of such a fit is shown in Figure 4, and the PL parameters for the four E(B - V ) values are given in Figure 5. The slope and normalization values on the E(B - V ) grid are = [0.20 ± 0.02, 0.28 ± 0.02, 0.35 ± 0.02, 0.46 ± 0.02] and f0 = [22.6 ± 0.2, 24.1 ± 0.3, 25.7 ± 0.3, 28.4 ± 0.3] nJy (at 6.07 × 1014 Hz), respectively. Their dependences on color excess can be approximated by linear functions in this E(B - V ) range: 0.164+3.71 E(B-V ) and f0 21.6+82.9 E(B-V ) nJy. The corresponding de-reddened fluxes in the FUV and optical bands are F (12502000 °A) = [2.6 ± 0.3, 2.9 ± 0.3, 3.4 ± 0.4, 4.4 ± 0.5] × 10-16 and F (38006000 °A) = [6.6±0.4, 7.1±0.4, 7.6±0.4, 8.4±0.5]×10-17 erg s-1 cm-2.
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We then considered a single thermal (BB) model with a fixed radius R = 12 km, a typical radius of a NS as seen by a distant observer. We fit both the BB temperature T and color excess E(B - V ) for distances d = 340500 pc. Because the FUV band falls in the Rayleigh-Jeans regime for the obtained temperatures, we can express the final results as T = (3.6 ± 0.2) × 106d2410 K and E(B - V ) = 0.51 ± 0.01. Since this color excess is much larger than the Galactic value along the line-of-sight and the temperature is implausibly high for the entire NS surface (contradicts to the X-ray data), this model can be ruled out.
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Lastly, we fit a two-component BB+PL model. Given the small number of data points, we fit the BB temperature T and PL normalization f0 on a three-dimensional grid = [-1, 0], d = [340, 410, 500] pc, and E(B - V ) = [0.01, 0.03, 0.05, 0.08]. The resulting BB temperatures and PL normalizations are plotted in Figure 6. Examples
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29
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28
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0. 08
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27
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0. 05
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26
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25
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0. 03
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f0 [nJy]
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24
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23 E(B - V) = 0. 01
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202.15 0.20 0.25 0.30 0.35 0.40 0.45 0.50
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Figure 5. Normalization f0 at 0 = 6.07 × 1014 Hz as a function of slope for the single PL model fits at different values of E(B - V ).
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Figure 6. BB temperature (upper panel) and PL normalization at 0 = 6.07×1014 Hz (lower panel) in the BB+PL fits as functions of E(B - V ) for different values of d and . The blue, green, and red solid lines correspond to the models for d = [340, 410, 500] pc and = -1. The blue, green, and red dashed lines are for = 0 and the same values of distance.
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of best-fit model spectra at most plausible d = 410 pc,
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E(B - V ) = 0.03 are shown in Figure 7 for two values of
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PL slope, = 0 and -1.
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2.5. Bow shock
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�Log(f) [nJy] Log(f) [nJy]
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F125LP
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Figure 7. Examples of the BB+PL fit to the HST photometry results for the J2124 pulsar, for two values of the PL slope, = 0 and -1, at d = 410 pc and E(B - V ) = 0.03. The red dashed lines and blue dash-dot lines show the BB and PL components, respectively, while the black solid lines show their sums. The downward arrows are the VLT limits reported by Mignani & Becker (2004). The black horizontal lines show the filter widths at half maximum.
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A bow-shaped structure spatially coincident with the known H bow shock (see Gaensler et al. 2002; Brownsberger & Romani 2014) is clearly visible in the F125LP image shown in Figure 1 (top left). The FUV bow shock appears to be asymmetric, being thicker and brighter east of the pulsar. We measure the apex distance (from the pulsar to the leading edge of the bow shock) to be 2. 5, consistent with the Brownsberger & Romani (2014); Gaensler et al. (2002) measurements in H.
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To extract the bow shock flux, we define the source and two background regions, "inside" and "outside" of the bow shock, shown in Figure 1 (top right). The background regions were selected based on the F125LP image, in which the bow shock was most clearly detected. The regions are close to the bow shock extraction region to mitigate effects from the inhomogeneous detector background while excluding the pulsar. Due to the larger apparent thickness of the east side of the bow shock, more space was left between the bow shock extraction region and the background regions. We take into account the background variations by selecting background regions on both sides of the bow shock: one ?inside? and one ?outside? the bow shock. These regions were used for both F125LP and F140LP flux measurements. A combined background from the two regions was extracted. The net source count rate was calculated similarly to the pulsar, with the area Ab being the combined area of the "outside" and "inside" background regions. The F125LP and F140LP count rates and their uncertainties are given in Table 2. From the measured count rates we calculated the absorbed fluxes in the F125LP and F140LP wavelength ranges: F (1250 - 2000 °A) = (8.1 ± 0.4) × 10-15 erg s-1 cm-2 and F (1350 - 2000 °A) = (7.0 ± 0.7) × 10-15 erg s-1 cm-2, for a flat f spectrum. The unabsorbed luminosity can be estimated as L(1250 - 2000 °A) 1.9 × 1029 erg s-1, for E(B - V ) = 0.03, and d = 410 pc.
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The bow shock is not detected in the F475X images (see Figure 8). Because of the apparent non-uniformities in the background, which significantly exceed the statistical fluctuations, we chose to measure the upper limits by sampling the background counts from ten different regions in the vicinity of the bow shock and calculat-
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Figure 8. UVIS/F475X image with the bow shock extraction regions (the same as in Figure 1), used for the data analysis. The pulsar and the direction of its proper motion are shown with a circle and an arrow, respectively.
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ing the standard deviation from the mean value. The areas of the background regions were equal to that of the bow shock region used for FUV flux measurements. The standard deviation can be considered as a conservative 1 upper limit. The corresponding 3 upper limit on the bow shock flux in the area of 52 arcsec2 is F (3750 - 6000 °A) 2.9 × 10-15 erg s-1 cm-2, for a flat f spectrum and E(B - V ) = 0.03.
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Similar to our analysis of the FUV bow shock around J0437 (Rangelov et al. 2016), we measured the ratio of the count rates in F125LP and F140LP filters for the J2124 bow shock. We obtained a ratio of C125/C140 = 1.3 ± 0.2. It is smaller than C125/C140 = 1.63 ± 0.08 for the J0437 bow shock, but the associated uncertainty is large.
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3. DISCUSSION
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3.1. Spectrum of PSR J2124-3358
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The obtained photometric measurements can be used to constrain the optical-FUV spectral energy distribution (SED) for J2124 and to look for thermal emission, similar
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�Optical-UV emission from pulsar J2124-3358
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7
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to that of J0437. The slope 0.2 inferred from the nonthermal (single
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PL) fit is outside the typical range of -1 0 found for the optical-UV magnetospheric emission seen in other pulsars (Kargaltsev & Pavlov 2007; Mignani 2011). However, we cannot rule out the possibility that the FUVoptical emission of J2124 is entirely magnetospheric, with > 0, because virtually nothing is known about optical spectra of non-accreting recycled pulsars15. The PL fit implies the V-band luminosity LV 5 × 1026d2410 erg s-1, which corresponds to an optical efficiency16 V LV /E int 2 × 10-7, similar to the efficiencies of middle-aged pulsars (see Figure 4 in Danilenko et al. 2012).
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A thermal interpretation for combined FUV and optical emission (single BB fit) can be ruled out because it requires a color excess much larger than the Galactic value along this line-of-sight, as well as an implausibly high temperature, 3.6 × 106 K, of the entire NS surface, which would result in an X-ray luminosity much larger than observed.
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Finally, there remains a good possibility that the optical emission is predominantly nonthermal while the FUV emission is largely thermal, similar to what is observed for nearby middle-aged pulsars (Kargaltsev & Pavlov 2007). The optical efficiency in the PL+BB fit is similar to (slightly lower than) that of the single PL fit, because the thermal component contribution is very small in the optical (see Figure 7). It follows from Figure 6 that the NS surface temperature of J2124 is likely in the range T (0.52.1) × 105 K for the considered (conservative) range color excess values, E(B - V ) = 0.010.08, and distances d = 340500 pc. Thus, this interpetation of the J2124 spectrum yields the NS surface temperature similar to that of J0437 (Durant et al. 2012).
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Zavlin (2006) has shown that two components are required to fit the X-ray spectrum of J2124. However, various combinations of thermal and nonthermal components were found to be statistically acceptable (e.g., two-component H-atmosphere model, H-atmosphere + PL, BB+PL; see Section 1). Extrapolation of the thermal components, originating from small, hot areas on the NS surface (presumably polar caps), underpredicts the observed FUV fluxes by several orders of magnitude. Therefore, the X-ray-emitting heated regions cannot be responsible for the observed FUV emission from the J2124. The extrapolated best-fit X-ray PL components of the BB+PL and H-atmosphere + PL models overpredict the FUV-optical fluxes by a large margin, but this is not unusual for middle-aged pulsars, which often show a spectral break between the X-ray and optical bands. The extrapolated -ray spectrum is a few orders of magnitude below the optical-FUV fluxes, which means that the optical-FUV and -ray emission are pro-
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15 Optical emission from the J0437 pulsar is buried under the much brighter emission of the white dwarf companion (Durant et al. 2012).
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16 The observed spin-down energy loss rate, E , needs to be corrected for the Shklovskii effect (Shklovskii 1970). With the corrected period derivative, Pint = 2.06 × 10-20 s s-1, we obtain the intrinsic spin-down power E int = (2.4+-00..69) × 1033 erg s-1 (for the the moment of inertia of 1045 g cm2) and the characteristic pulsar age of 11+-63 Gyr, for d = 410+-9700 pc.
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duced by different mechanisms. If the two-component (thermal plus magnetospheric)
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nature of the optical-FUV spectrum of J2124 is confirmed in future observations, J2124 would be the second recycled pulsar, after J0437, with such a high temperature, T 105 K of the NS surface. It would firmly prove that a heating mechanism operates at least in millisecond pulsars and could distinguish between heating models.
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Heating mechanisms that may operate in the interiors of ancient NSs include the dissipation of rotational energy due to interactions between superfluid and normal components of the NS (vortex creep; Alpar et al. 1984; Shibazaki & Lamb 1989), release of strain energy stored by the solid crust due to spin-down deformation (Cheng et al. 1992), rotochemical heating (Reisenegger 1995; Fern´andez & Reisenegger 2005; Petrovich & Reisenegger 2010), rotation-induced deep crustal heating (a variant of rotochemical heating that operates in the crusts of pulsars; Gusakov et al. 2015), and decay or annihilation of dark matter particles, trapped in the NS interiors (de Lavallaz & Fairbairn 2010; Kouvaris & Tinyakov 2010). Among the internal heating mechanisms, the vortex creep, rotochemical heating, and deep crustal heating, all of which are driven by the spin-down of pulsars, are able to account for the high surface temperatures, 105 K, of millisecond pulsars (Gonzalez & Reisenegger 2010; Gusakov et al. 2015). Both J2124 and J0437 are much older than the standard NS cooling time, so they are expected to be in a quasi-stationary state in which any internal heating and photon cooling balance each other (e.g., Reisenegger 1995; Fern´andez & Reisenegger 2005). Thus the effective temperature should be a function of the spin-down parameters, 1/4 for vortex creep, ( )2/7 for rotochemical heating (assuming modified Urca reactions and neglecting superfluid corrections), and ( )1/4 for rotation-induced deep crustal heating, where is the NS rotation rate and is its time derivative. The spin-down parameters (corrected for the Shklovskii effect) of J2124 are quite similar to those of J0437, so the ratio of their effective temperatures is expected to be TJ2124/TJ0437 = 0.89, 0.95, 0.96, respectively, for the three heating mechanisms. Since, for a radius of 12 km (as assumed here), TJ0437 1.8 × 105 K (inferred from the results of Durant et al. 2012), the temperature expected for J2124 is only slightly lower, TJ2124 (1.6-1.7)×105 K, which is consistent with temperatures estimated in the PL+BB scenario. To confirm this scenario and estimate the temperature more accurately, the J2124 pulsar must be observed with several filters in the UVOIR range, and the distance to the pulsar should be measured more precisely.
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3.2. FUV bow shock
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J2124 is the second pulsar with a bow shock detected in FUV. The first FUV bow shock was discovered by Rangelov et al. (2016) around J0437. These authors tested two spectral models for FUV emission. A PL continuum model, with -3 -1 in the FUV range ( -1 if the PL spectrum extends to the optical range), could correspond to synchrotron radiation of relativistic electrons leaked from the X-ray PWN region and trapped at the forward bow shock. The other model, favored by Rangelov et al. (2016), was the spec-
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logf [erg/s/cm2/Å]
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Figure 9. The bow shock flux density in FUV (F125LP) and
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F475X 3 upper limit (see Section 2.5 for details) are shown to-
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gether with two spectral models. The horizontal black lines repre-
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sent the filter widths at the half-maximum. Absorbed flux densities for the PL ( = 0) and shocked plasma model (for vs = 110 km s-1 and n0 = 0.2 cm-3; see Rangelov et al. 2016 for details) are plotted as blue and red lines, respectively.
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trum emitted by the ISM matter heated and compressed in a collisionless shock (SHELLS model in Bykov et al. 2013); it was consistent with the measured bow shock fluxes at reasonable values of the shock (pulsar) velocity and upstream ISM density.
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The bow shock of J2124 is dimmer and has a lower S/N , which prevents us from performing a similarly detailed analysis. Nevertheless, we can compare general properties of the J2124 shock with those of the J0437 shock. The FUV bow shocks of both pulsars are spatially coincident with the H bow shocks (see Figure 1). In contrast to J0437, the J2124 bow shock shows a significant asymmetry of its shape with respect to the proper motion direction, which has been attributed to a local ISM density gradient perpendicular to the pulsar's direction of motion (Gaensler et al. 2002). Interestingly, there is also an asymmetry in shock brightness, opposite in the the H and FUV images (compare the top-left and bottom-right panels in Figure 1); the reason of this asymmetry remains unclear. In addition to the asymmetry, the head (apex region) of the FUV-H J2124 bow shock is "flatter" than the head of the J0437 bow shock. This could be caused by anisotropy of the pulsar wind, such that the wind is concentrated in the pulsar's equatorial plane that is nearly perpendicular to the pulsar's velocity (Gaensler et al. 2002; Brownsberger & Romani 2014).
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The FUV luminosity, L(12502000 °A) 1.9 × 1029d2410 erg s-1, extracted from the As = 52 arcsec2 area of the J2124 bow shock is a factor of 3.8d2410 higher than the FUV luminosity from the As = 32 arcsec2 area of the J0437 shock. However, the (distance-independent) mean specific intensity, I = L/(4d2As) 1.9 × 10-16 erg cm-2 s-1 arcsec-2 for the J2124 bow shock, is a factor of 2.8 lower than that of the J0437 shock. Such a difference could be partly due to the fact that the width of the extraction region of the J2124 shock was somewhat broader than the actual width of the bright shock area. In addition, the more distant J2124 shock was imaged at larger physical separations in units of length from the apex, where the shock becomes intrinsically dimmer.
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Therefore, it is likely that the specific intensities of the J2124 and J0437 shocks are close to each other at the same (physical) separations from the apices. Since in the ISM shock interpretation the emitted shock flux per unit emitting area is crudely proportional to the upstream density and only weakly depends on the pulsar velocity in the relevant range of parameters (see Figure 6 of Rangelov et al. 2016), it means that the ISM densities ahead of the J0437 and J2124 shocks are close to each other.
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For pulsar J0437, Rangelov et al. (2016) used the ratio of the F125LP and F140LP count rates, CF125/CF140 = 1.63±0.08, to estimate the slope of the J0437 spectrum in the FUV range, -3 -1 (see Figure 4 in Rangelov et al. 2016). Similarly, for J2124, we have CF125/CF140 = 1.3 ± 0.2, from which we infer -10 -4, i.e., a very steeply decreasing f spectrum. This result, however, suffers from the large uncertainty of the F140LP count rate. Such a steep spectrum cannot be extrapolated to the optical (F475X) band because the extrapolated spectral flux would greatly exceed the upper limit in that filter, which requires a FUV-optical slope 0 (see Figure 9), corresponding to CF125/CF140 1.85. Unless the count rate uncertainties are greatly underestimated due to unaccounted systematic errors, this discrepancy can be considered as an argument for a shock SED more complex than a simple PL.
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In the shocked ISM emission model the ratio of FUV and H fluxes depends on the model parameters. Brownsberger & Romani (2014) report the H photon flux FH = 5.3 × 10-3 photons s-1 cm-2, or energy flux FH = 1.6 × 10-15 erg s-1 cm-2. This corresponds to the ratio of F125LP to H energy fluxes of 6, although this value can be larger (by a factor of up to 2) because we do not know the exact apex areas used by Brownsberger & Romani (2014). For comparison, the flux ratio in the same filters for J0437 is FFUV/FH = 12 ± 4 (Figure 6 in Rangelov et al. 2016), i.e., generally consistent with J2124. The non-detection of the J2124 bow shock in the F475X image provides additional constraints on the spectral shape and, possibly, on the emission mechanism. Figure 9 shows a single PL model and a shocked ISM model (normalized to FUV flux measurement) compatible with the 3 F475X upper limit. The shocked ISM model appears to be able to describe the measurements; however, given the complexity of the model and the scarcity of the data, we do not attempt to fit it.
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The detection of the FUV bow shock around two pulsars allows one to assume that such shocks can be detected from many other pulsars, including those from which no H shock is seen because of a lack of neutral hydrogen atoms upstream of the shock. Such observations, currently possible only with the HST, would be very useful for studying the ISM properties and the physics of relativistic shocks.
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Support for program GO 13783 was provided by NASA through grant from the Space Telescope Science Institute, which is operated by by the Association of Universities for Research in Astronomy, Inc., under NASA contract NAS 5-26555. The authors acknowledge support from FONDECYT Regular Project 1150411, FONDECYT Postdoctoral Project 3150428, Center for Astron-
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�Optical-UV emission from pulsar J2124-3358
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9
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omy and Associated Technologies (CATA; PFB-06). We thank Denis Gonz´alez-Caniulef for valuable help with the preparation of the observing proposal.
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HST(ACS), HST(WFC3)
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