The first X-ray polarimetric observation of the black hole binary LMC X-1

ABSTRACT

1 INTRODUCTION

LMC X-1 is the first discovered extragalactic black hole (BH) X-ray binary system (Mark et al. 1969). Being located in the Large Magellanic Cloud, the source has a well-determined distance of 50 ± 1 kpc (Pietrzyński et al. 2013). LMC X-1 is persistent and bright; hence, it has been studied extensively since its discovery. X-ray binary systems typically exhibit two distinct spectral states in the X-ray band: the ‘high/soft state’ in which the thermal emission from a multitemperature blackbody accretion disc (Novikov & Thorne 1973; Shakura & Sunyaev 2009) is dominant, and the ‘low/hard state’ in which a power-law component is dominant (Zdziarski & Gierliński 2004; Remillard & McClintock 2006). While many X-ray binary systems change their spectral state over time, LMC X-1 has always been observed in the soft state with L_X ∼ 2 × 10³⁸ erg s⁻¹ (Nowak et al. 2001; Wilms et al. 2001). Typically more than 80 per cent of the X-ray flux can be attributed to the thermal/disc component (see e.g. Nowak et al. 2001; Steiner et al. 2012; Bhuvana et al. 2021; Jana et al. 2021; Bhuvana, Radhika & Nandi 2022). The remainder of the X-ray flux can be decomposed into coronal power-law emission (Sunyaev & Titarchuk 1980), a broad Fe line from the relativistic disc (Fabian et al. 1989), and a narrow Fe line that most likely originates from scattering off highly ionized wind from the stellar companion (Steiner et al. 2012).

Optical and near-infrared observations reveal an O7/O9 giant donor with a mass of M₂ = 31.8 ± 3.5 M_⊙ (Orosz et al. 2009). The same dynamical study confirms a BH accretor with a mass of M_BH = 10.9 ± 1.4 M_⊙ and an orbital inclination i = 36|${_{.}^{\circ}}$|4 ± 1|${_{.}^{\circ}}$|9. The measured orbital period of LMC X-1 is 3.90917 ± 0.00005 d (Orosz et al. 2009), based on high-resolution optical spectroscopy. Over an orbit, the X-ray flux exhibits achromatic sinusoidal amplitude modulations of 7 per cent associated with the inferior/superior conjunctions and Thomson scattering and absorption by the stellar wind (Nowak et al. 2001; Orosz et al. 2009; Hanke et al. 2010). Strong red noise variability is observed on time-scales shorter than the orbital period (Schmidtke, Ponder & Cowley 1999; Nowak et al. 2001; Bhuvana, Radhika & Nandi 2022). Also, low-frequency quasi-periodic oscillations (QPOs) were observed on several occasions (Ebisawa, Mitsuda & Inoue 1989; Alam et al. 2014), which do not fit well within the standard low-frequency QPO ABC classification (Casella, Belloni & Stella 2005).

Measurement of the BH spin in LMC X-1 is of great interest. The system is a high-mass X-ray binary, and estimation of the BH spin is useful for stellar evolution and cosmological studies (see e.g. Qin et al. 2019; Mehta et al. 2021). The donor star is 5 Myr past the zero-age main sequence and believed to be filling 90 per cent of its Roche lobe. This, and the inferred dynamical parameters of the system, suggests that LMC X-1 is likely a precursor of an unstable mass transfer phase and a common-envelope merger (Podsiadlowski, Rappaport & Han 2003; Orosz et al. 2009; Belczynski, Bulik & Fryer 2012). Such systems are of potential interest for gravitational wave studies, especially regarding the spin of the BH (Belczynski et al. 2021; Fishbach & Kalogera 2022; Shao & Li 2022). Many spectroscopic studies have estimated the spin of the BH in LMC X-1, using the continuum and relativistic line fitting techniques in Kerr space–time, assuming the spin is aligned with the system axis of symmetry (see Tripathi et al. 2020, for LMC X-1 studies beyond the Kerr metric). They infer remarkably high spin values: 0.85 ≲ a ≲ 0.95 (continuum method; Gou et al. 2009; Mudambi et al. 2020; Jana et al. 2021; Bhuvana, Radhika & Nandi 2022) and 0.93 ≲ a ≲ 0.97 (Fe-line method; Steiner et al. 2012; Bhuvana, Radhika & Nandi 2022). Along with the high spin, high accretion rates of |$0.07 \lesssim \dot{M}/\dot{M}_{\textrm {Edd}} \lesssim 0.24$| and luminosities 0.1 ≲ L_X/L_Edd ≲ 0.16 are estimated (the quantities are defined in Bhuvana, Radhika & Nandi 2022). The power-law index tends to be steep 2 ≲ Γ ≲ 4 (Nowak et al. 2001; Gou et al. 2009; Jana et al. 2021; Bhuvana, Radhika & Nandi 2022). A counterargument to the high spin of LMC X-1 through X-ray spectroscopy was given by Koyama et al. (2015) that introduced a double Compton component model to fit the data, which allows a larger disc inner radius, leading to a lower spin estimate.

X-ray polarimetry can constrain the geometry of the unresolved inner accretion flow and the inclination of the accretion disc with respect to the observer. It can also independently constrain the spin of the BH (Connors & Stark 1977; Stark & Connors 1977; Connors, Piran & Stark 1980; Dovčiak, Karas & Matt 2004; Dovčiak et al. 2008; Li, Narayan & McClintock 2009; Schnittman & Krolik 2009, 2010; Cheng et al. 2016; Taverna et al. 2020, 2021; Krawczynski & Beheshtipour 2022), especially in the high/soft state when the accretion disc is widely believed to extend to the innermost stable circular orbit.

We present the first X-ray polarimetric measurement of LMC X-1, which serves as an example of an accreting BH caught in the thermal state. The Imaging X-ray Polarimetry Explorer (IXPE; Weisskopf et al. 2022) observed LMC X-1 in the 2–8 keV band in which the disc emission dominates during 2022 October. Simultaneous X-ray observations were performed with the Neutron Star Interior Composition Explorer (NICER; Gendreau, Arzoumanian & Okajima 2012), Nuclear Spectroscopic Telescope Array (NuSTAR; Harrison et al. 2013), and Spectrum-Rontgen-Gamma (SRG)/Astronomical Roentgen Telescope – X-ray Concentrator (ART-XC; Pavlinsky et al. 2021) instruments to better characterize the source spectrum. The IXPE observation of LMC X-1 helps fill out the sample of accreting BHs with X-ray polarization measurements that includes the accreting stellar-mass BHs in Cyg X-1 (Krawczynski et al. 2022) and Cyg X-3 (in the low/hard or intermediate states; Veledina et al. 2023), and the supermassive BHs in MCG-05-23-16 (Marinucci et al. 2022) and the Circinus galaxy (Ursini et al. 2023). We obtained a low upper limit on the 2–8 keV polarization of LMC X-1 in the thermal state. Our careful spectropolarimetric analysis leads to constraints on the polarization of the distinct X-ray spectral components and validates long-standing theoretical predictions for X-ray properties of the innermost regions of accreting BHs.

Independent constraints on the accretion disc orientation are important when interpreting the X-ray polarization results. A ∼15 pc parabolic structure in the form of a surrounding nebula (wind or jet powered) was detected in both optical and radio observations (Pakull & Angebault 1986; Cooke et al. 2008; Hyde et al. 2017). The nebula is aligned with an inner ∼3.3 pc ionization cone of 50° projected full opening angle seen in He ii and [O iii] lines, which is believed to be directly related to the BH accreting structure (Cooke et al. 2007, 2008). We use this large-scale measurement of the disc orientation to assess the X-ray polarization position angle measured by IXPE at sub-pc scales; this is similar to comparison made for Cyg X-1 (Krawczynski et al. 2022). The jet of LMC X-1 has not been detected yet (Fender 2006; Hughes et al. 2007; Hyde et al. 2017) and is likely to be switched-off since the binary is persistently in the thermal state (Cooke et al. 2007).

The paper is organized as follows. Section 2 describes the observations and the data reduction techniques. Our spectral and polarimetric results are presented in Section 3. Section 4 provides a summary.

2 OBSERVATIONS AND DATA REDUCTION

IXPE (Weisskopf et al. 2022) observed LMC X-1 between 2022 October 19 15:01:48 utc and 2022 October 28 04:39:09 utc, under the observation ID 02001901 and for a total livetime of ∼562 ks for each of its three telescopes. Processed, Level 2, data already suitable for scientific data analysis were downloaded from the IXPE High-Energy Astrophysics Science Archive Research Center (HEASARC) archive.¹ Source and background regions were spatially selected in the IXPE field of view defining different concentric regions, both centred on the image barycentre. The source region is defined as a circle with radius 1.5 arcmin, while the background region is an annulus with inner and outer radii of 2.5 and 4 arcmin, respectively. We show these regions on top of the IXPE count maps in Appendix  A.

Two different approaches were used to estimate the X-ray polarization. The first relies on the use of forward-folding fitting software (we used xspec version 12.13.0; Arnaud 1996) to model Stokes spectra I, Q, and U. This allows us to model the spectrum of the source I with different components, associating to each of them a polarization model that is constrained using the Q and U spectra. An alternative approach makes use of the ixpeobssim package (Baldini et al. 2022), which provides tools for IXPE data analysis including the PCUBE algorithm of the xpbin function, which calculates the polarization degree and angle from the Stokes parameters without making any assumption on the emission spectrum. For xspec analysis, we used the formalism from Strohmayer (2017) and used the weighted analysis method presented in Di Marco et al. (2022), parameter Stokes = Neff in xselect.

The polarization cubes (PCUBEs) for both the source and background regions generated with ixpeobssim combine the observations from each detector unit (DU), and return the total polarization degree and angle and the minimum detectable polarization (MDP) at 99 per cent confidence level. Using xpbin with the PHA1, PHA1Q, PHA1U algorithms, we created spectral files of Stokes I, Q, and U parameters, respectively. These files are produced in the OGIP, type 1 PHA format, which is convenient for spectral, polarimetric, and joint analysis within xspec.

Appendix  A contains a full description of the NICER, NuSTAR, and ART-XC observations and the data reduction. This includes discussion of our use of the cross-calibration model MBPO employed to reconcile discrepancies between the instruments and of level of the systematic uncertainties of the instruments.

3 DATA ANALYSIS

3.1 Spectral and timing analysis

Daily monitoring by the Gas Slit Camera (GSC) onboard of the Monitor of All-sky X-ray Image (MAXI; Matsuoka et al. 2009) confirmed that during our observations there were no outbursts or long-term flux variations that would suggest that the source departed from the high/soft state. In this study, we analysed in more detail the flux variability of LMC X-1 during the IXPE observation, using light curves from the simultaneous observations by NICER, NuSTAR, and ART-XC (see Fig. 1). We used the following energy ranges for the light curves: 0.3–12 keV, 3–20 keV, and 4–12 keV, respectively for NICER, NuSTAR, and ART-XC. Despite ART-XC registers useful signal up to 35 keV, we used shorter energy band for the timing analysis due to the sharp decrease of the mirror systems effective area above the nickel edge at ≈12 keV. The corresponding time bins were 920 s for NICER, 400 s for NuSTAR and ART-XC, and 1000 s for IXPE.

Figure 1.

X-ray light curves of LMC X-1. Top panel: ART-XC light curve for the energy range 4–12 keV. Second panel: NuSTAR light curve for the energy range 3–20 keV from the Instrument A of NuSTAR. Third panel: NICER light curve for the energy range 0.3–12 keV with a sinusoidal curve showing the expected orbital modulations of the X-ray flux based on previous RXTE monitoring of the source. Bottom panel: IXPE light curve for the energy range 2–8 keV. The dashed horizontal lines are the average count rate for each light curve.

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The IXPE and NICER observations cover a period of 10 d, while NuSTAR and ART-XC complement these observations with snapshots in the hard X-ray band. Our IXPE and NICER observations thus include about two and half orbits of the BH and companion star. Orosz et al. (2009) measured orbital modulations of the X-ray flux to be consistent with the periodicity measured from optical data. The X-ray orbital modulation was revealed via a set of the Rossi X-ray Timing Explorer (RXTE)/All-Sky Monitor (ASM; Levine et al. 1996) data from over 12 yr monitoring, and it was attributed to the electron scattering and absorption in the stellar wind from the companion star (Orosz et al. 2009; Levine et al. 2011). To estimate the X-ray flux orbital modulations in the current observations, we took the orbital ephemeris from the ‘adopted’ model in table 3 of Orosz et al. (2009); in particular, we assumed the orbital period of 3.90917 d and the time of the superior conjunction of 53390.8436 MJD (Modified Julian Date). We took the parameters of the best-fitting sinusoidal curve from their table 1 for the 1.5–12 keV energy band, where they reported parameters averaged over the 12 yr observation with RXTE, and we rescaled to the NICER count rate. The NICER count rate versus orbital phase is then f(ϕ) = a₀ − a₁cos (2|$\pi$|ϕ), where, once rescaled, the parameters are a₀ = 201.69 and |$a_1=a_{1, \rm {RXTE}} \times \frac{a_0}{a_{0, \rm {RXTE}}}=6.51$| and ϕ is the phase. The curve is shown along with the NICER data in the third panel of Fig. 1.

Comparison of the curve and the data indicates that the X-ray variations in the NICER light curve can be well explained by the expected orbital modulations. The amplitude of the NICER data modulation is higher than the amplitude from the RXTE/ASM analysis. This is most likely due to a different sensitivity of the instruments, the NICER camera being more sensitive in the low energies where most counts are detected and affected by the circumstellar absorption, and thus the amplitude of the modulation might be larger. Any stochastic variations, which can also contribute to the single observation, are smeared out in the averaging over 12 yr of monitoring with RXTE. Similar modulations are apparent in the IXPE light curve. The X-ray flux minima correspond to superior conjunctions of the BH that are associated with the enhanced absorption and reduced scattered emission due to the wind from the companion.

In the light curves acquired in the hard X-ray band (ART-XC and NuSTAR), stochastic noise dominates over the orbital modulations. Similar to previous research (see Koyama et al. 2015), we observe an increase in stochastic red noise variability with energy. The power spectrum in the hard band can be described with a power law with index ≈−1 and normalization consistent with the previous measurements (see e.g. Bhuvana et al. 2021). No obvious QPOs were observed in the power spectrum. It should be noted that low-frequency QPOs were previously observed in this system during short episodes of spectral hardening within the soft state (Ebisawa, Mitsuda & Inoue 1989; Alam et al. 2014).

Using the NICER and NuSTAR spectral data, we calculated the hardness ratio defined as the ratio between the flux in the hard band and the total flux. We defined the soft versus hard bands to be 0.3–3 keV versus 3–12 keV for NICER, and 3–8 keV versus 8–20 keV for NuSTAR. In Fig. 2, we show the evolution of the hardness ratio for the NICER and NuSTAR data. The NICER hardness ratio is consistent with being constant with an average hardness of 0.0059 within the measurement uncertainties. The low hardness indicates that the source is in the soft state when the accretion disc thermal emission clearly dominates in the X-ray spectrum. The average NuSTAR hardness ratio is 0.025 for the simultaneous observation with IXPE.

Figure 2.

Time variation of X-ray hardness ratios. The dashed lines are the average values of the hardness ratios. Top panel: ratio of the NICER count rates in the hard band (3–12 keV) over the total flux (0.3–12 keV). Bottom panel: ratio of the NuSTAR count rates in the hard band (8–20 keV) over the total flux (3–20 keV).

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Because the spectral hardness appears constant over the observations, and given the stability in flux, we used NICER, NuSTAR, and IXPE time-averaged spectra for the spectral fitting. We fit each of the 10 NICER, two NuSTAR, and three IXPE spectra individually, as a joint fit. We used the NuSTAR spectra up to 20 keV as the background signal becomes comparable to that of the source at higher energies. The ART-XC data were not used for detailed spectral analysis, because of too high noise. We used the xspec package and employed the following model (1) for the time-averaged analysis:

We used KERRBB (Li et al. 2005) to model general relativistic accretion disc emission from a multitemperature blackbody and NTHCOMP (Zdziarski, Johnson & Magdziarz 1996; Życki, Done & Smith 1999) for the thermally Comptonized continuum. For the KERRBB model, we kept the BH mass and distance fixed at the values reported for the source (M_BH = 10.9 M_⊙, d = 50 kpc) and assumed the disc axis to be aligned with the binary system orbital inclination (i = 36|${_{.}^{\circ}}$|4), i.e. the disc is not warped. We fixed the dimensionless spin parameter of the BH to the best-fitting value of 0.92 found with the continuum fitting method by Gou et al. (2009). We also kept the spectral hardening factor fixed at 1.7, and assumed no torque at the inner disc edge.

The blackbody seed photon temperature kT_bb of the NTHCOMP model was allowed to vary in the range 0.4–1.0 keV. The lower limit was obtained from prior modelling where kT_bb was tied to the kT_in of the multiblackbody model DISKBB to calculate the temperature of the inner edge of the accretion disc and the Compton upscattering of seed photons at this temperature. The upper limit is set to the maximum kT_in fitted to archival data reported in Gou et al. (2009). The blackbody seed photon temperature was 0.888 ± 0.005 keV, consistent with values reported in Gierliński, Maciołek-Niedźwiecki & Ebisawa (2001) and Kubota et al. (2005). We find a photon index of 2.60 ± 0.02, well within previously reported ranges employing the NTHCOMP (Jana et al. 2021) and POWERLAW (Jana et al. 2021) models. The int_type parameter of NTHCOMP is set to 0 for blackbody seed photons.

A GAUSSIAN component was added at 0.88 keV with a line width of 0.25 keV to account for an emission feature that resembles the first-order scattering of anisotropic photons onto isotropic electrons like that in Zhang, Dovčiak & Bursa (2019, fig. 8). The Observation 3 of NICER presented a more pronounced GAUSSIAN component that required different line energy and normalization parameter values with the line width consistent to other NICER observations within the 90 per cent confidence interval. GABS was used to model a broad Gaussian-like absorption artefact at 9.66 keV detected with NuSTAR that may be due to Comptonization in the upper layers of the disc not being modelled properly, an inhomogeneous corona, a broad instrumental absorption feature, or an unmodelled weak reflection component. The line energies for both of the identified emission and absorption-like features, E_l in GAUSSIAN and GABS respectively, are left frozen while their line widths and normalization/depth are allowed to vary freely.

TBFEO (Wilms, Allen & McCray 2000) was used to account for the X-ray absorption by hydrogen, oxygen, and iron. The fitted equivalent hydrogen column that accounts for absorption in our Galaxy, in the Large Magellanic Cloud, and in the binary system was (0.938 ± 0.001) × 10²² cm⁻². We note that while this value is smaller than the (1.0–1.3) × 10²² cm⁻² reported in Hanke et al. (2010), these higher values worsen the fit. Although the metallicity should vary along the line of sight, we use a single absorber for simplicity. The iron and oxygen abundances relative to solar are allowed to vary freely.

We find the best-fitting model has χ²/dof = 3497.83/2571. We estimate a BH accretion rate of |$\dot {M}=(1.756 \pm 0.002)\times 10^{18}$| g s⁻¹, consistent with values reported for the source in Zdziarski et al. (2023). The flux in the 2–8 keV energy range is dominated by the accretion disc emission with KERRBB contributing 94 per cent, while the coronal emission (NTHCOMP) contributes 6 per cent. Fig. 3 shows the unfolded spectra and the best-fitting parameters as reported in Table 1.

Figure 3.

X-ray spectra of LMC X-1. Top panel: NICER (red), NuSTAR (blue), and IXPE (cyan) spectra unfolded around the best-fitting model described by model (1) in EF(E) space. The total model for each data set is shown in black with individual GAUSSIAN, KERRBB, and NTHCOMP contributions in light grey, orange, and green, respectively. Bottom panel: model-data deviations (residuals) in σ.

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The obtained χ²/dof for the best-fitting model is greater than 1, despite the addition of systematic errors (see Appendix  A). This may be due to several reasons: cross-calibration uncertainties between the different instruments, short-term source variability, different exposure intervals of the various satellites, and complexity of the X-ray spectra of Galactic BHs that may be not fully captured by the model. However, as a detailed spectral analysis is beyond the scope of the paper and a visual inspection of the residuals seems to indicate that the global fit is not obviously incorrect, we used the best-fitting model to derive the polarization properties of the various spectral components.

3.2 Polarimetric analysis with PCUBEs

We show in Fig. 4 the normalized Stokes parameters (Q/I and U/I) for a single energy bin 2–8 keV, for each DU separately, and summed. The polarization angle measured by IXPE using the sum of all three DUs is 51|${_{.}^{\circ}}$|6 ± 11|${_{.}^{\circ}}$|8 in the north-east direction and the polarization degree is 1.0 ± 0.4 per cent. Given this measurement, we have a 3σ upper limit on polarization degree of 2.2 per cent. The polarization angle value is roughly aligned with the ionization cone structure detected in He ii λ4686/Hβ and [O iii] λ5007/Hβ line ratio maps at 225° north-east (with a projected full opening angle 50°; Cooke et al. 2007, 2008), because the polarization angle is defined modulo 180°. The obtained low value of the upper limit on the polarization degree is consistent with the classical results of Chandrasekhar (1960) and Sobolev (1963), approximated by equation (41) of Viironen & Poutanen (2004), for scattering-induced polarization of pure thermal emission in semi-infinite disc atmospheres seen at inclination below ∼60°. However, see Section 3.3 for a careful discussion of the polarization result with respect to the two observed spectral components. The MDP at 99 per cent confidence level in 2–8 keV is 1.1 per cent, which means the obtained polarization result is not statistically significant. Reducing the energy range does not improve the statistical significance.

Figure 4.

Normalized Q/I and U/I Stokes parameters and corresponding polarization degree and angle for DU1 (red), DU2 (green), DU3 (blue), and a sum of the three units (black). The (light green) circle represents the MDP value at the 99 per cent confidence level, and the cyan-shaded area represents the direction and projected full opening angle of the ionization cone. The data are obtained using a single energy bin in the 2–8 keV energy band. We report the uncertainties at 1σ level, i.e. at the 68.3 per cent confidence.

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Although no average polarization is observed, a time-dependent signal may still be present in the IXPE observation. To check for this possibility, we adopted the dedicated ixpeobssim function to calculate the normalized Stokes parameters Q/I and U/I in time bins of 30 ks (see Fig. 5). These can be considered independent normal variables (Kislat et al. 2015) and we fit their values as a function of time with a constant line. The fit null probability, which expresses the probability that the observed variations around the model are due to chance alone, is ≈50 per cent for both Q/I and U/I for the value of the χ² found and the number of degrees of freedom of the fit. Then, we derived that any observed variability of polarization is compatible with statistical fluctuations only.

Figure 5.

Counting rate (top) and normalized Stokes Q and U parameters (middle and bottom, respectively) measured by IXPE as a function of time. Time bin is 2 ks for counting rate and 30 ks for Q and U. Horizontal, dashed lines are the best fit with a constant line: the obtained χ², the number of degrees of freedom and the corresponding null probability are indicated. The grey-shaded and white regions identify subsequent orbits of LMC X-1.

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We repeated a similar procedure to investigate possible dependence of polarization on the orbital phase. We first derived the phase of each event from its arrival time using the orbital ephemeris described in Section 3.1. Then, we folded the events into seven phase bins. Variations of the normalized Stokes parameters in the entire 2–8 keV IXPE energy band are compatible with statistical fluctuations: summing the χ² values obtained for the fit of both the Stokes parameters and, correspondingly, their degrees of freedom, the null probability of the combined fit is 1.1 per cent. However, selecting only the events in the 2–4 keV energy range (see Fig. 6), the null probability is reduced to 0.0057 per cent. This further supports the fact that the emission from LMC X-1 may indeed be polarized at a few per cent, but its polarization angle, degree, or both, could depend on the orbital phase. When summing over time-scales comparable to the orbital period, an orbital-phase-dependent polarization would be averaged to a low value that would be undetected in the phase-average analysis. However, IXPE observed only two complete orbits of LMC X-1 (see Fig. 5); therefore further observations would be needed to detect orbital-phase-dependent polarization with high statistical confidence.

Figure 6.

Variation of the normalized Stokes parameters Q (top) and U (middle), calculated with ixpeobssim, as a function of the orbital phase of LMC X-1. As in Fig. 5, horizontal, dashed lines are the best fit with a constant line, and the χ², the number of degrees of freedom and the corresponding null probability of the fit are indicated. The corresponding flux from IXPE, normalized to its maximum observed value (bottom), as a function of the orbital phase is added for comparison.

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3.3 Polarimetric analysis with xspec

For the polarimetric fit of our data, we removed the NICER and NuSTAR spectra and included the IXPE Q and U spectra. Since our aim here was to explore the polarimetric properties of the source with the simplest possible model, we removed both GAUSSand GABS component from model (1) and we convolved the thermal and the Comptonized components with the polarization model POLCONST; this is characterized by two parameters, the polarization degree Π and angle Ψ, both constant with energy. Thus we employed model (2) in the fitting procedure defined as follows:

We maintained the spectral parameters frozen at the values shown in Table 1, while allowing both components’ polarization degree and angle to vary freely during the fitting procedure. As a result, we obtained a best-fitting χ²/dof = 842.5/894, with the polarization parameters values listed in Table 2.

Because we obtained only an upper limit on the polarization degree, we were not able to constrain the polarization properties of both spectral components at the same time. Thus we decided to further analyse the polarimetric data by tying the two components’ polarization angles. In particular the polarization degree and angle associated with the accretion disc thermal emission were left free to vary, while we linked the polarization angle of the coronal emission to that of the thermal emission. Because of the symmetry of the system, the polarization vector of the thermal emission is expected to be either parallel or perpendicular to the disc symmetry axis. However, the Chandrasekhar–Sobolev result and many simulation studies suggest that the thermal emission is locally likely to be polarized perpendicular to the disc symmetry axis. This is especially true when considering optically thick disc atmospheres with large optical depth (Dovčiak et al. 2008; Taverna et al. 2020), or when accounting for absorption processes alongside scattering ones (Taverna et al. 2021). The coronal emission polarization vector can be either parallel or perpendicular to the disc axis, depending on the corona geometry, its location, and velocity (see e.g. Zhang et al. 2022). Nevertheless, the recent observation of Cyg X-1 (Krawczynski et al. 2022) and theoretical predictions for a flat corona sandwiching the disc (see e.g. Poutanen & Svensson 1996; Schnittman & Krolik 2010; Krawczynski & Beheshtipour 2022) suggest that this component is polarized in the same direction as the disc axis. Hence, we forced the polarization vectors of the two components to be perpendicular to each other. In this configuration, the total polarization degree of the model is given by the difference between the two components’ contribution, effectively allowing for two unphysically large polarization degree values at the same time. To avoid this, we restricted our analysis to three reasonable values for the coronal emission polarization degree: 0 per cent, 4 per cent (the best-fitting value for coronal emission polarization degree found for Cyg X-1 in Krawczynski et al. 2022), and 10 per cent. The resulting contour plots for the polarization degree and angle of the thermal emission are shown in Fig. 7. The ionization cone orientation of ∼45° suggests that the projected accretion disc plane is perpendicular to the projected jet-remnant direction (see e.g. Krawczynski et al. 2022), i.e. approximately −45° ± 25° in our plots, which is marked by the yellow-shaded region in Fig. 7, taking into account the observed projected full opening angle of the ionization cone. Thus the thermal component is expected to be polarized in this direction.

Figure 7.

Contour plots of the polarization degree Π and angle Ψ associated with the accretion disc thermal emission. Blue, red, and green lines indicate 68, 90, and 99 per cent confidence levels for two parameters of interest, respectively. The black cross indicates the best-fitting parameters for the χ²/dof value shown in the label. The coronal emission is assumed to be polarized perpendicularly to the thermal component, and its polarization degree is fixed at 0 per cent (top), 4 per cent (middle), and 10 per cent (bottom). The yellow-shaded region indicates the projected accretion disc plane, perpendicular to the projected ionization cone. The orange dots represent the 3σ upper limit of thermal emission polarization degree, assuming that this component is polarized in the same direction as the projected accretion disc plane, i.e. perpendicularly to the observed projected ionization cone direction. The accretion disc is assumed to be aligned with the orbital inclination i = 36|${_{.}^{\circ}}$|4.

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When assuming the coronal emission to be unpolarized, we found an upper limit of 2.5 per cent on the thermal emission polarization degree, while forcing the polarization angle to be directed as the projected accretion plane this value reduces to 1.0 per cent, which is marked by the orange dot in top panel of Fig. 7. When taking into account the coronal emission polarization, the contour plots show two minima, representing two allowed configurations. In one case the thermal component is polarized in the same direction as the projected accretion plane with a low polarization degree, while in the other it is polarized perpendicularly to it, but with a larger polarization degree. In both cases, the polarization degree upper limits tend to increase, becoming as high as Π = 2.4 and 2.2 per cent when the Comptonized component polarization degree is fixed at 4 and 10 per cent, respectively; and Π = 0.9 and 0.9 per cent, if we further assume the suggested system orientation, which is marked by the orange dots in middle and bottom panels of Fig. 7. These polarization degree values are all well within the Chandrasekhar estimates for the polarization of thermal radiation. The polarization angle value is unconstrained at the 99 per cent confidence level in all cases (see Fig. 7).

We also attempted for a joint spectropolarimetric fit in xspec, using a physical model of thermal emission KYNBBRR (Taverna et al. 2020; Mikusincova et al. 2023), while keeping the phenomenological constant polarization prescription to the power-law component. The KYNBBRR model is an extension of the relativistic package kyn (Dovčiak, Karas & Matt 2004; Dovčiak et al. 2008), developed to include the contribution of returning radiation, i.e. photons that are bent by strong gravity effects and forced to return to the disc surface, where they can be reflected before eventually reaching the observer (Schnittman & Krolik 2009; Taverna et al. 2020). Although this approach in theory allows to put constraints on the polarization of the Comptonization component, the BH spin, and the accretion disc inclination, we could not obtain any reasonable restrictions on these parameters, given our spectral and polarization data.

3.4 Physical polarization model of Comptonized and thermal emission

In addition, we performed simulations of a slab coronal geometry with a cold disc and a hot Comptonization medium above it using a radiative transfer code that splits the radiation field produced by Compton scattering in different orders and computes their intensities, source functions, and polarization (Veledina & Poutanen 2022; Poutanen, Veledina & Beloborodov 2023). The code follows the procedures described in Poutanen & Svensson (1996). For consistency with the spectral data, we performed additional spectral fit with this model that is described in Appendix  B. The obtained values served as referential for the polarization modelling. We assumed the slab is illuminated by the accretion disc whose radiation is described by the multitemperature blackbody kT_bb = 0.81 keV and angular distribution and polarization follow the Chandrasekhar–Sobolev profile (Chandrasekhar 1960; Sobolev 1963). The temperature of the medium is assumed to be kT_e = 10 keV and the Thomson optical depth to be τ_T = 1.26. We plot the resulting spectra for different inclinations (i = 30°, 45°, 60°, and 75°) in Fig. 8(a). In Fig. 8(b), we show the polarization degree corresponding to this geometry. Positive(/negative) values correspond to polarization parallel(/orthogonal) to the disc axis.

Figure 8.

Spectral energy distribution (a) and polarization degree (b) obtained for the slab corona model. Lines correspond to different inclinations: i = 30° (black solid), 45° (green dotted), 60° (blue dashed), and 75° (red dot–dashed).

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The change of polarization sign at ∼5 keV is a known feature of the slab corona geometry (see e.g. Poutanen & Svensson 1996), as the sign of each Compton scattering order is controlled by the angular distribution of the incoming (seed) photons. We find that, for the considered parameters, the switch between negative and positive polarization degree occurs in the middle of IXPE range. This might be the reason for the low net polarization degree averaged over the entire 2–8 keV band, and can plausibly serve as a mechanism for switching between the positive and negative polarization degrees seen in Fig. 6: variations of the parameters lead to variations of the characteristic energy of zero polarization. In this case, the variations likely have a stochastic rather than periodic (e.g. at orbital period) origin.

4 CONCLUSIONS

We performed a broad-band X-ray spectropolarimetric observational campaign of the BH binary system LMC X-1 simultaneously with the IXPE, NICER, NuSTAR, and ART-XC missions. The spectral data are consistent with previous studies of LMC X-1. We report that the source is in the high/soft state with a dominant thermal component in the X-ray band, a power-law Comptonization component that begins to prevail around ∼10 keV, and a negligible reflection contribution. The spectra do not show significant time variability. The first X-ray polarimetric observation of LMC X-1 by IXPE constrains the polarization degree to be below the MDP of 1.1 per cent at the 99 per cent confidence level for the time-averaged emission in the 2–8 keV band. This is consistent with theoretical predictions for pure thermal emission from a geometrically thin and optically thick disc with a Novikov–Thorne profile, assuming Chandrasekhar’s prescription for polarization due to scattering in semi-infinite atmospheres. Spectropolarimetric fitting leads to upper limit (at 99 per cent confidence level) on the polarization degree of the thermal radiation to be 1.0, 0.9, or 0.9 per cent when the polarization of power-law component is fixed to 0, 4, or 10 per cent, respectively, if the two components are polarized perpendicular to each other and if we assume a preferred system orientation given by the optical data from literature. The new X-ray polarimetric data show hints of non-zero polarization with the polarization angle aligned with the projected ionization cone and weak evidence for time variability of the polarization that could be attributed to a stochastic origin in a slab corona scenario sandwiching a thermally radiating accretion disc. The 562 ks observation by IXPE did not allow statistically significant constraints on the BH spin nor the disc inclination.

ACKNOWLEDGEMENTS

The Imaging X-ray Polarimetry Explorer (IXPE) is a joint US and Italian mission. The US contribution is supported by the National Aeronautics and Space Administration (NASA) and led and managed by its Marshall Space Flight Center (MSFC), with industry partner Ball Aerospace (contract NNM15AA18C). The Italian contribution is supported by the Italian Space Agency (Agenzia Spaziale Italiana, ASI) through contract ASI-OHBI-2017-12-I.0, agreements ASI-INAF-2017-12-H0 and ASI-INFN-2017.13-H0, and its Space Science Data Center (SSDC) with agreements ASI-INAF-2022-14-HH.0 and ASI-INFN 2021-43-HH.0, and by the Istituto Nazionale di Astrofisica (INAF) and the Istituto Nazionale di Fisica Nucleare (INFN) in Italy. This research used data products provided by the IXPE Team (MSFC, SSDC, INAF, and INFN) and distributed with additional software tools by the High-Energy Astrophysics Science Archive Research Center (HEASARC), at NASA Goddard Space Flight Center (GSFC).

The authors thank the referee, Andrzej Zdziarski, for very detailed and useful comments. JPod, MD, JS, and VK thank for the support from the GACR project 21–06825X and the institutional support from RVO:67985815. AV acknowledges support from the Academy of Finland grants 347003 and 355672. HK and NRC acknowledge NASA support under grants 80NSSC18K0264, 80NSSC22K1291, 80NSSC21K1817, and NNX16AC42G. P-OP acknowledges financial support from the French High Energy Program (PNHE/CNRS) and from the French Space Agency (CNES). AI acknowledges support from the Royal Society.

DATA AVAILABILITY

The IXPE data used in this paper are publicly available in the HEASARC data base (https://heasarc.gsfc.nasa.gov/docs/ixpe/archive/). The analysis and simulation software ixpeobssim developed by IXPE collaboration and its documentation is available publicly through the webpage https://ixpeobssim.readthedocs.io/en/latest/?badge = latest.494. The NICER and NuSTAR data underlying this paper are publicly available from the NuSTAR (https://heasarc.gsfc.nasa.gov/docs/nustar/archive/nustar_archive.html) and NICER (https://heasarc.gsfc.nasa.gov/docs/nicer/nicer_archive.html) archives. The ART-XC data used in this paper publicly available at ftp://hea.iki.rssi.ru/public/SRG/ART-XC/data/LMC_X-1/lmc_x_1_barycen.fits.gz. The xspec software is publicly available in the HEASARC data base (https://heasarc.gsfc.nasa.gov/xanadu/xspec/). The corresponding xspec packages used for this work can be found in the references stated in this paper or shared on reasonable request.

Footnotes

References

APPENDIX A: OBSERVATIONS AND DATA REDUCTION OF NICER, NuSTAR, AND ART-XC

In Section 2, we already described in detail the IXPE data reduction. For completeness, we also show in Fig. A1 the IXPE count maps indicating the regions chosen to select the source and the background in the field of view.

Figure A1.

Count maps of the three IXPE telescopes. The scale of the colour bar is logarithmic to make visible, in addition to the source, also the much fainter background. The regions used to angularly select the source and background in the field of view are the green solid circle and the dashed orange annulus, respectively.

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We now return to the other three instruments forming the observational campaign. NICER (Gendreau, Arzoumanian & Okajima 2012) is a soft X-ray spectral-timing instrument aboard the International Space Station, sensitive within ∼0.2–12 keV band. It is non-imaging, and composed of 56 silicon-drift detectors, each of which is paired with a concentrator optic, commonly aligned to a single field approximately 3 arcmin in radius. 52 detectors have been active since launch, although in any given observation, some detectors may be temporarily disabled. NICER observed LMC X-1 during the course of the IXPE observational campaign, for a total of 13.5 ks useful time among 10 ObsIDs from 2022 October 19–28.

NICER data were reduced using nicerl2 with unrestricted undershoot and overshoot rates. The background was computed using the ‘3C50’ model (Remillard et al. 2022). Subsequently, the data were filtered to remove intervals with background count rates more than 1 per cent the source rate, and any short GTI intervals <60 s were removed. For each observation, the detectors were screened for outliers in overshoot or undershoot event rates that are generated by particle background and optical-loading events, respectively. For both fields, each detector was compared to the detector distribution, and those more than 10σ equivalent from the median were filtered out. NICER spectra were rebinned in order to oversample the instrumental energy resolution by a factor of ∼3. NICER observations were found to be relatively constant in flux and consistent in spectral properties over the IXPE campaign, and with low power-density rms noise.

The NuSTAR spacecraft (Harrison et al. 2013) acquired a total of 19 ks of data on 2022 October 24 under observation ID 90801324002. The NuSTAR data were processed with the NuSTARDAS software (version 2.1.1) of the HEAsoft package (version 6.29) [NASA High Energy Astrophysics Science Archive Research Center (HEASARC) 2014]. Source and background events were selected with a circular region of ∼67 arcsec radii for both focal plane modules (FPMA/FPMB). FTGROUPPHA was used to rebin the spectra implementing the Kaastra & Bleeker (2016) optimal binning scheme.

We note that we used the cross-calibration model MBPO employed in Krawczynski et al. (2022) to reconcile discrepancies between the instruments when performing the joint fits in Sections 3.1 and 3.3 with the NICER, NuSTAR, and IXPE spectra. Since the KERRBB normalization is frozen to unity (as should physically be the case) and NuSTAR has the best absolute flux calibration of the instruments considered here, we fixed the NuSTAR FPMA normalization to the recommended value of 0.8692 derived from unfocused observations of the Crab Nebula (Madsen et al. 2017). We allow the normalization of the NuSTAR FPMB to vary freely. For the NICER observations, we account for cross-calibration discrepancies against NuSTAR by multiplying the model spectrum with a power law using the same power-law index for all 10 observations and allowing normalization constants to vary. For the IXPE detector units, all parameters in MBPO are allowed to vary freely. See Table A1 for the best-fitting values of the free parameters in the MBPO model for each data set. We also included a 0.5 per cent systematic uncertainty to all instruments used in the data analysis apart from NICER, where we accounted for 1.5 per cent systematic uncertainty, according to the mission’s recommendation.² This is necessary to take into account the unknown internal calibration.

The Mikhail Pavlinsky ART-XC telescope is a grazing incidence focusing X-ray telescope (Pavlinsky et al. 2021) onboard the SRG observatory (Sunyaev et al. 2021). It observed LMC X-1 on 2022 October 27 with a total exposure of 84.4 ks. The ART-XC observation has two short technical interruptions of ∼100 s duration each. ART-XC data were processed with the analysis software artproducts v1.0 and the caldb version 20220908.

APPENDIX B: SPECTRAL FIT WITH COMPPS MODEL

To use consistent spectral parameters in the polarimetric modelling of Section 3.4, we fitted the spectra from NICER and NuSTAR with the same model, COMPPS, in slab geometry (Poutanen & Svensson 1996) with thermal distribution of the electrons, and with multitemperature blackbody emission from the disc as seed photons. The spectra used are the same as in Section 3.1. We used an energy range of 1–8 keV for NICER and 3–20 keV for NuSTAR. The spectra above 20 keV were background dominated in NuSTAR. To prevent potential confounding effects arising from the soft excess feature discussed in Section 3.1, data below 1 keV for NICER were excluded from the analysis. In the COMPPS model, the covering fraction was fixed to unity while the reflection fraction was set to zero, as no reflection features were seen in the spectra. We used a constant to account for instrumental uncertainties, TBFEO for the neutral absorption, and an additional Gaussian absorption between 9 and 10 keV GABS to account for an absorption feature discussed in detail in the spectral analysis in Section 3.1. The constant for NICER spectrum was frozen at 1.0, while the fit resulted in 0.91 and 0.89 for NuSTAR-FPMA and NuSTAR-FPMB, respectively. We obtained the best fit for an inner disc temperature of 0.81 ± 0.01 keV, for an electron temperature of 10 ± 1 keV, and for an optical depth of 1.26 ± 0.09. The χ²/dof for the fit is 1231/1125. The parameters of the fit are outlined in Table B1. The χ²/dof appears better than for the spectral fit described in Section 3.1 due to the intentional reduction of the NICER energy range, which excludes some intricate spectral features in the soft X-rays (see Fig. 3), and due to better capture of the COMPPS model of the joint spectrum. However, we do not keep this spectral fitting attempt as leading in the main paper body, because the COMPPS model cannot separate the thermal and Comptonized component, which is necessary for the basic polarization analysis of the two dominant components performed in Section 3.3.