Linear to circular conversion in the polarized radio emission of a magnetar

Abstract

Radio emission from magnetars provides a unique probe of the relativistic, magnetized plasma within the near-field environment of these ultra-magnetic neutron stars. The transmitted waves can undergo birefringent and dispersive propagation effects that result in frequency-dependent conversions of linear to circularly polarized radiation and vice versa, thus necessitating classification when relating the measured polarization to the intrinsic properties of neutron star and fast radio burst emission sites. We report the detection of such behaviour in 0.7–4 GHz observations of the P = 5.54 s radio magnetar XTE J1810−197 following its 2018 outburst. The phenomenon is restricted to a narrow range of pulse phase centred around the magnetic meridian. Its temporal evolution is closely coupled to large-scale variations in magnetic topology that originate from either plastic motion of an active region on the magnetar surface or free precession of the neutron star crust. Our model of the effect deviates from simple theoretical expectations for radio waves propagating through a magnetized plasma. Birefringent self-coupling between the transmitted wave modes, line-of-sight variations in the magnetic field direction and differences in particle charge or energy distributions above the magnetic pole are explored as possible explanations. We discuss potential links between the immediate magneto-ionic environments of magnetars and those of fast radio burst progenitors.

Main

Magnetars are a class of slowly rotating neutron star with implied surface magnetic field strengths exceeding 10¹⁴ G. Most magnetars are exclusively detected at X-ray and gamma-ray wavelengths (ref. ¹, https://www.physics.mcgill.ca/~pulsar/magnetar/main.html). So far, only six have been found to emit radio pulses. The magnetar XTE J1810−197 was initially discovered following a high-energy outburst in 2003 (ref. ²) with a peculiar flat-spectrum radio counterpart³. Follow-up observations revealed the magnetar emitted bright, highly polarized radio pulses⁴. The radio emission displayed dramatic changes in pulse profile shape and intensity over time^5,6. Polarimetry of individual single pulses revealed the presence of low-level circular polarization with an apparent frequency-dependent change in handedness⁶. This behaviour was believed to be the product of the electromagnetic radiation propagating through a birefringent medium such as the highly magnetized, relativistic electron–positron pair plasma within neutron star magnetospheres⁷. Polarization-dependent dispersion within such a plasma can result in an efficient conversion between the linearly and circularly polarized components of the transmitted radiation, an effect known as Faraday conversion (sometimes referred to as generalized Faraday rotation or the Cotton–Mouton or Voigt effect)^8,9. This propagation effect has been invoked as a means for generating rotation-phase-dependent variations in the linear and circular polarization of some pulsars^10,11,12,13, and was recently suggested as the mechanism responsible for generating circular polarization within the eclipses of the pulsar binary system PSR J1748−2446A (ref. ¹⁴). A similar linear-to-circular conversion can take place due to either fully or partially coherent averaging of linearly polarized emission modes that have undergone birefringent delays within neutron star magnetospheres^15,16,17. Partially coherent mode mixing has been recently investigated as a means for explaining non-orthogonal jumps in linear polarization position angles (PAs) and frequency-dependent curricular polarization variations in young pulsars¹⁸. Recent advances in wide-bandwidth radio telescope instrumentation and signal processing systems have since allowed us to identify and characterize these effects and use them to probe the immediate plasma environment in and around the magnetospheres of these extreme objects.

Observations

After more than a decade of quiescence, radio pulses were again detected from XTE J1810−197 on modified Julian date (MJD) 58460, following a high-energy outburst that began sometime between MJD 58442 and 58448 (refs. ^19,20). We began a monitoring campaign of the magnetar using the Commonwealth Scientific and Industrial Research Organisation (CSIRO) Parkes 64 m radio telescope (also known as Murriyang) and the 76 m Lovell Telescope at the Jodrell Bank Observatory (JBO). Here we focus on the observations taken between MJD 58460 and 58512. A total of ten observations were performed during this time period using the Parkes Ultra-Wideband Low (Parkes-UWL) receiver system, covering a broad frequency range extending from 704 to 4,032 MHz. At JBO, a set of 33 observations that were taken using a comparatively narrowband (512 MHz) receiver system centred at 1,532 MHz. All observations were corrected for frequency-dependent dispersion and Faraday rotation introduced by propagation of the radio pulses through the interstellar medium. Details of the observations and data processing procedure can be found in the Methods and Extended Data Table 1.

Results and analysis

The radio emission from XTE J1810−197 after its reactivation was composed of narrow, millisecond-duration subpulses^21,22. Averaging hundreds of rotations over time results in an average pulse profile composed of three distinct, highly polarized components: a strong ‘central’ component flanked by a wide leading component and a narrow trailing component (Extended Data Figs. 1 and 2). Simple power-law fits to the total intensity spectrum across the pulse profile revealed spectral indices (κ, see Methods for details), with predominantly negative values across the precursor and trailing components, whereas the central component displayed either a flat or inverted spectrum (Extended Data Fig. 3). The component-dependent spectral indices remained fairly stable over the first 2 months of the outburst, unlike much of the other radiative properties of the magnetar that displayed substantial temporal evolution. In Fig. 1 we highlight epoch-to-epoch changes in the frequency-averaged linear and circular polarization of XTE J1810−197 normalized by the peak total intensity flux. We observed remarkable variations in the linear and circular polarization of the central component as a function of pulse phase and time. An initial increase in left- and right-hand circular polarization and simultaneous decrease in linear polarization in the leading half of the component were abruptly interrupted sometime between MJDs 58464 and 58466. This coincided with the disappearance of an apparent quasi-periodic spacing between substructures in the central profile component¹⁹ and an inversion of the linear polarization PA swing across the profile (Extended Data Fig. 1). A second such PA-swing inversion occurred between MJDs 58532 and 58343 but was not associated with polarization variations across the central component.

Fig. 1: Polarization evolution of XTE J1810−197 with time.

Linear and circular polarized emission detected by Lovell and Parkes observed at each epoch after averaging in frequency over 1,340–1,724 MHz and 0.07–2.0 h. These data are presented as functions of pulse phase and time. Red and blue colours correspond to positive and negative values, respectively. The initial smooth linear variations across pulse phase and slowly increasing level of positive (left-handed) circular polarization undergo a dramatic change after 13 December 2018 (MJD 58465, lower horizontal line). Sudden reversals in circular handedness correspond to dips in linear intensity due to strong conversion effects. The circular intensity diminishes within roughly 12 days of the 13 December 2018 event (MJD 58477, upper horizontal line). It was then followed by an apparent drift of the linear-to-circular conversion feature to increasingly later phases with time.

Following the initial PA-inversion the magnetar began to display clear frequency-dependent variations in its polarization properties. This is highlighted in Fig. 2 where we show the frequency and phase-resolved linear position angle between Stokes Q and U and ellipticity angle between Stokes V and the total polarization (L), \({\it{\varPsi}} =0.5\,{\tan }^{-1}(U/Q)\) and \({\it{\chi}} =0.5\,{\tan }^{-1}(V/L)\), across the central profile component from MJD 58463–58471. The right-hand panels of Fig. 2 show the single-pulse PA and ellipticity angle distributions measured on MJDs 58468, 58469 and 58471 gradually branch out along two separate paths at the same pulse phases where substantial right-hand circular polarization was detected. Such rapidly diverging PA distributions are often attributed to radio emission from two orthogonally polarized modes (OPMs)²³. While there does appear to be a weak OPM in the precursor and trailing components, along with a clear OPM jump at pulse phases between 0.52 and 0.53 on MJDs 58468–58471, the branching PA distributions in question are inconsistent with switching between orthogonal emission states. The separation and recombination of the PA-swing distributions are substantially slower than the near-instantaneous transitions expected for OPMs²⁴. Additionally, while the ‘orthogonal modes’ are 90° apart from one another at pulse phases between 0.495 and 0.508, they are only offset by ±45° from the nominal PA track. This instead points to the polarization variations having arisen from some form of birefringent propagation effect either within the magnetosphere or near-field environment of XTE J1810−197 (refs. ^16,25).

Fig. 2: Evolution of the phase- and frequency-resolved polarization properties of XTE J1810−197.

Left-hand panels show the linear polarization PA (Ψ, left) and ellipticity angle (χ, middle-left) for the Parkes-UWL observations as a function of pulse phase and observing frequency. Blank horizontal lines correspond to frequency channels that were excised due to contamination by RFI. Right-hand panels display the frequency-averaged, 2D histograms of the single-pulse distributions of Ψ (middle-right) and χ (right) for the four Parkes-UWL search-mode observations. Large frequency-dependent variations and branching paths in the single-pulse distributions caused by propagation effects in the magnetar magnetosphere are evident in observations from MJD 58467 onwards.

To understand what is driving the frequency-dependent polarization changes in XTE J1810−197, we analysed the Stokes spectra extracted from individual pulse-phase bins within the central component. In Fig. 3 we plot the polarization fraction and normalized Stokes Q, U and V parameters corresponding to the peak in left-hand circular polarization on MJD 58471. All three Stokes parameters show strong variations that become more intense at lower observing frequencies, which coincides with a gradual decline in total polarization fraction. We characterized these variations by fitting the polarization spectra in each phase bin with a phenomenological model²⁶ (see Methods for details). The priors on the model parameters are listed in Table 1. Our median recovered values and 68% confidence intervals are presented in Fig. 4 for the five observations where intense circular polarization was detected. These include the wavelength dependence (α), generalized rotation measure (GRM), rotation about the Stokes V axis (φ) and tilt angle between the polarization vector rotation axis away from the right-hand Stokes V pole (ϑ). Extended Data Fig. 4 depicts the reduced chi-square statistic for 1,000 random draws per model spectrum. All four model parameters vary substantially with pulse phase and observing epoch, indicating a strong line-of-sight dependence. A significant degree of clustering around ϑ ≅ 90° occurred at phases between 0.495 and 0.507 in most epochs. Outside this region of pulse phase, the value of ϑ varies between 0–90° and 90–180°. The wavelength dependence and GRM also vary with pulse phase and observing epoch, with α generally taking on values that are smaller than theoretical predictions for Faraday conversion^9,27,28. Some of this behaviour can be attributed to only weak frequency-dependent variations occurring at phases earlier than 0.492 and later than 0.53. However, this does not adequately explain the consistent measurements of α < 1 or the near-zero wavelength dependency recovered around pulse phases of 0.5 or after 0.51 on MJDs 58470 and 58471, where the model fails to reconstruct the data below 1,300 MHz (Extended Data Fig. 5 and the animated versions of Fig. 3 in the Supplementary Information).

Fig. 3: Example detection of linear-to-circular conversion in XTE J1810–197.

a,b, Linear polarization PA and 1-σ uncertainties (a) along with the time- and frequency-averaged polarization profile (b) of XTE J1810−197 detected on 19 December 2018, where the black, orange, green and blue lines, respectively, correspond to the total intensity (I), two linear polarizations (Q and U) and the circular polarization (V). c,d, The vertical magenta line indicates the phase bin (0.505 in this plot) for which we plot the corresponding time-averaged total polarization fraction (c) and polarization spectra (d) where the error bars correspond to the off-pulse r.m.s. flux. e, In the latter, Stokes Q, U and V were normalized by total polarization (P), which traces out a clear frequency-dependent circle on the Poincaré sphere. The dashed magenta lines in c and d correspond to the median a posteriori fit to the data. Animated versions of this figure that scan across pulse phase and include different epochs are depicted in Supplementary Videos 1–10.

Table 1 Priors for the Faraday conversion model

Fig. 4: Recovered phase-resolved geometric parameters from the polarization conversion model for five Parkes-UWL epochs.

a–d, Median a posteriori values (points) 68% confidence intervals (error bars) for the spectral exponent (a), GRM in units of rad m^−α (b), and the longitude (c) and latitude (d) of the conversion axis. Different colours represent points measured from different epochs between MJD 58467 and 58471, as indicated in the key located in the upper left.

We investigated whether rapid fluctuations in the propagating medium could explain the deviations away from a simple λ^α dependence and depolarization by fitting our model to the single-pulse data collected on MJDs 58468 and 58469. The recovered distributions of these two model parameters are shown for five pulse-phase ranges in Extended Data Fig. 6. We expected the resulting measurements of α would be narrowly distributed about some preferred wavelength dependence while the recovered GRMs follow a broader distribution, reflective of changes in the underlying plasma density. However, there is instead a strong peak in the GRM at values between 2 and 5 rad m^−α while α measurements are distributed along a broad range of values that resemble the time-averaged results for these two epochs. As a result, we can rule out rapid temporal variations in the intervening medium density as causing the low measured values of α and model inconsistencies. We also looked at whether the presence of multiple over-dense regions (Faraday screens) could explain the deviations by comparing the single-pulse fits to four sets of simulated polarization spectra that were generated using our model with a fixed α = 1 (Methods and Extended Data Table 2). Our recovered GRM and α for these simulations are shown in Extended Data Fig. 7. All four panels display varying degrees of clustering around the true α, along with a clear correlation between the recovered GRM and wavelength scaling. The pile-up of measurements where α → 0 and the GRM rapidly increases in addition to the long tail in the α distributions are caused by the simulated spectra deviating from what our model could accurately reproduce. Simulations where the injected GRM were drawn from a Gaussian (Extended Data Fig. 7b,d) provide the closest match to the observed single-pulse measurements, however, the substantial peak around a particular wavelength dependence is not present in our observations of XTE J1810−197. The lack of a peak in α among the real data could be due to conversion within individual Faraday screens arising from different physical processes, and therefore imparting different wavelength dependencies. However, this same behaviour could very well arise from a different type of birefringent propagation, such as mode coupling, without needing to invoke more complex averaging over temporal variations or multiple Faraday screens.

Discussion

Interpretation of the polarization properties

Our observations of XTE J1810−197 and characterization of the variable polarization properties are challenging to interpret. While it is possible that the observed behaviour could be due to an intrinsic emission process (ref. ²⁹ and references therein), we have ruled out intrinsic orthogonal emission modes as a means for generating the rapid changes in PA and circular polarization across the central component. The single-pulse PA and ellipticity angle distributions across the central profile component in Fig. 2 deviate by only 45° from the dominant emission mode. Similar behaviour has been described in other pulsars and magnetars as arising from some form of propagation effect in the near-field regime^10,30. Exactly what kind of propagation effect is taking place depends on the environment the outgoing radio waves propagate through, and whether the wave modes of the emitted electromagnetic radiation couple to the intervening medium or themselves.

The rotation of the polarization data about an arbitrary axis in Fig. 3 (and the animated versions in the Supplementary Information) visually appeared consistent with the radio waves from the magnetar having undergone Faraday conversion⁸. Unlike the propagation through the magnetized interstellar medium (which we precorrected for in these data), Faraday conversion results in a rotation of the polarization vector that is not restricted to the QU plane. Under this interpretation, the values of α and ϑ can be directly related to the physical process driving the conversion. A relativistic pair plasma threaded by a uniform magnetic field perpendicular to the wave direction will have linear polarization modes (ϑ = 90°) and impart a linear-to-circular conversion with an α = 3 dependence⁹. Propagation through the near-wind of a magnetar can result in values of α that range between 1 and 2 depending on the size of the phase shift that is applied to the propagating wave modes²⁸. Our model fits in Fig. 4 show the polarization data are consistent with propagation through a plasma with highly variable, elliptical modes with a small region of pulse phase between 0.495 and 0.507 being consistent with purely linear modes. Yet the recovered values of α range between 0 and 1 with some level of clustering around 0.5, inconsistent with theoretical expectations. These models also predict the fraction of polarization should remain constant with frequency, which is decidedly not the case for XTE J1810−197. Hence Faraday conversion alone cannot fully describe the polarization variability that we detected. Other effects, such as charge imbalances, differences in electron–positron streaming velocities and the number-density ratio of cold versus and relativistic particles in the dispersive plasma can all give rise to the elliptically polarized modes that we detect^9,31,32,33. Changes in the magnetic field direction and mixtures of plasma modes arising from inhomogeneities in charged particle density or magnetic field strength can result in the observed damping of polarization with frequency⁹. These phenomena are not captured by comparatively simple models of Faraday conversion.

Linear to circular conversion can also arise from a phenomenon known as mode coupling. Here, differences in refractive index introduce a delay in one of the linearly polarized modes that coherently recombine at the polarization limiting radius¹⁶. This results in a fraction of the initially linearly polarized radio waves being converted to circular¹⁵. Mode coupling can occur when the magnetic field in a pair plasma that was initially quasi-tangential to the wave direction suddenly diverges from the ray path. The change in field direction can result from bending of the field lines due to the rotation of the star³⁴ or the presence of a twist in the magnetic field³⁵. Numerical ray tracing simulations of radio waves propagating through highly asymmetric electron-ion plasma that included this effect resulted in the transmitted PA displaying wavelength dependencies of λ^0.5, as opposed to the usual quadratic dependence of standard Faraday rotation³⁴. Partially coherent addition of two modes with differing spectral indices or a frequency-dependent coherence fraction could explain both the intense polarization variations and depolarization that we observed in XTE J1810−197 (refs. ^18,24). It would also explain the unusual non-orthogonal deviations in the ellipticity angle and PA in Fig. 2. The increasing circular polarization and unusually small wavelength dependence in the later observations could be explained by changes in the dominant polarization mode over time. These effects could be further tested by extending the recently developed partial coherence model of ref. ¹⁸ into the frequency domain. Observations of future outbursts in XTE J1810−197 at frequencies below 1 GHz would also provide strong constraints on the presence of either wave-mode coupling or Faraday conversion through detections of complete depolarization or the presence multiple oscillatory cycles in Stokes Q, U and V.

The emission from XTE J1810−197 becomes depolarized at the same pulse phases where the total intensity takes on an inverted spectral shape. Such behaviour may be the result of synchrotron absorption in the intervening magnetospheric plasma, where the frequency dependence of synchrotron absorption can alter the spectral shape and radio polarization characteristics^14,36. Synchrotron absorption is a maximum at a frequency determined by the energy spectrum of the absorbing particles. A decrease in the energy of these particles causes the maximum in the absorption coefficient to move to lower frequencies, and hence the turnover in the spectrum to move to lower frequencies. This would explain a purported shift in the spectral turnover of XTE J1810−197 from higher to lower frequencies³⁷. We note, however, that profile components with differing spectral indices are commonplace among pulsars, and that magnetar spectral indices have been observed to undergo large fluctuations^30,38.

Links to changing magnetic topology and precession

The onset of the frequency-dependent polarization variations in XTE J1810−197 occurred following an inversion of the linear PA swing. Similar PA-swing inversions were reported in observations of both PSR J1119−6127 and Swift J1818.0−1607 during their respective 2016 and 2020 outbursts^30,39 and these were speculated to stem from a combination of changes in magnetic field topology and birefringent effects. Such behaviour can be triggered by plastic motion of a crustal plate that would twist and distort the active magnetic field lines or even shift the location of the magnetic pole on the neutron star surface (SGR 1830−0645, ref. ⁴⁰). Fits to the X-ray spectrum of XTE J1810−197 are consistent with the thermal X-ray emission being generated by two closely spaced, non-concentric hotspots on the surface surrounded by a warm cap⁴¹. However, the lack of high-cadence X-ray observations means it is unknown whether the surface hotspots displayed plastic motion at the same time as the polarization variations presented here. Conversely, changes in emission height and underlying PA swing across the pulse profile can also arise from precession of the neutron star due to either spin-orbit coupling with a binary companion (PSR 1906+0746, ref. ⁴²) or a deviation of the neutron star crust away from spheroidal symmetry resulting in free precession⁴³. Spin-orbit precession would require XTE J1810−197 to have a massive companion, for which no such evidence exists. Free precession has been explored as a plausible explanation for the secular PA-swing evolution of XTE J1810−197 following the 2018 outburst, in which the PA inversions are due to the magnetic axis of the star crossing our line of sight⁴⁴. Radiation emitted close to the magnetic axis will originate from closer to the neutron star surface⁴⁵, increasing the chance of the radio waves being subject to birefringent propagation effects from interactions with intense particle outflows in the postoutburst magnetosphere^46,47. Mode coupling is also predicted to be strongest for lines of sight that pass nearest to the magnetic axis, where our line of sight cuts deeper into the twisted magnetosphere³⁴. Both scenarios can explain the rapid increase in circular polarization in Fig. 1 just before the PA-swing inversion and the rapid decay afterwards. The variations in linear-to-circular conversion with pulse phase may then be due to local twists in the magnetic field lines or fluctuations in particle outflow along different lines of sight through the magnetosphere.

Implications

Parallels with rotation-powered pulsars

Studies of rotation-powered pulsars have shown apparent rotation measure (RM) variations as a function of pulse phase, independent of the RM induced by the magnetized interstellar medium (ISM)^11,12,48,49. Some of these variations in the ‘phase-resolved’ RM can be ascribed to scatter broadening⁵⁰, but a magnetospheric or near-field propagation effect such as Faraday conversion provides the most plausible explanation. As a demonstration of how linear-to-circular conversion can give rise to this effect, we applied the phase-resolved RM fitting approach to our observations of XTE J1810−197, the results of which are presented in Extended Data Fig. 8. Significant positive and negative deviations away from the nominal ISM-induced RM of 74.4 rad m⁻² are measured across the central profile component that match-up with the rotation-phases where we detected significant conversion (Fig. 4). Hence, care must be taken when interpreting apparent differential RMs across radio profiles.

Links to birefringent effects in fast radio bursts

Magnetars are often invoked as the central engine of the fast radio burst (FRB) phenomenon. This concept was seemingly confirmed after the detection of an FRB and several other radio bursts from the Galactic magnetar SGR 1935+2154 (refs. ^51,52). Parallels have also been drawn between the secular RM evolution found in two repeating FRB sources^53,54 and the Galactic Centre magnetar SGR 1745−2900 (ref. ⁵⁵). The RM evolutions of these objects are probably the result of slow changes in the particle density and magnetic fields of their local environments. More recently, large RM variations and significant levels of circular polarization have been detected in at least three other repeating FRB sources^56,57,58. All three are probably young objects with complex local environments as indicated by their frequency-dependent depolarization⁵⁹, associations with active star-forming regions, persistent radio sources or both. The RM variations in these sources may be due to transient magnetospheric propagation effects, which we demonstrated can be misidentified when fit using standard Faraday rotation models. In the case of FRB 20201124A, Faraday conversion with wavelength dependencies between α = 2 and 3 have been reported, suggesting the presence of a relativistic plasma surrounding the progenitor object^56,60. The rapid onset and subsequent fading of intense birefringent effects in FRB 20201124A is reflected in our observations of XTE J1810−197 (Fig. 1) and may point to a similar magneto-ionic environment within FRB progenitors. Future systematic studies of birefringent propagation effects in large FRB samples and additional magnetar outbursts using current and upcoming wideband receivers could provide a new means testing radiative transfer models in some of the most extreme magneto-ionic environments in the Universe.

Methods

Parkes observations

Observations of XTE J1810−197 by were performed using Murriyang, the Parkes 64 m radio telescope, with the UWL receiver system⁶¹ providing continuous coverage across radio frequencies between 704 and 4,032 MHz. This includes three observations originally presented in an earlier, initial study²¹. Full Stokes data were recorded using the MEDUSA backend in pulsar search mode⁶², with 8 bit, 128 μs sampling across all 3,328 frequency channels (each 1 MHz in width) that were coherently dedispersed at a dispersion measure of 178 pc cm⁻³. We used DSPSR⁶³ to fold the data at the rotation period of XTE J1810−197 using an iteratively updated version of the ephemeris listed in the Australia Telescope National Facility (ATNF) catalogue⁶⁴. These folded archives had 1,024 bins covering the rotation phase of the magnetar for a time resolution of approximately 5.4 ms. Channels affected by radio-frequency interference (RFI) were excised in a semi-automated fashion. A predetermined list of persistently bad channels was flagged using the paz tool from PSRCHIVE^62,65. This was followed by manual flagging of any remaining RFI-affected channels using the paz tool. We polarization calibrated these data using pac tool in PSRCHIVE to apply the calibration solutions to the data. The solutions were derived from off-source observations of a pulsed signal injected into the signal path by a linearly polarized noise diode to determine the differential gain and phase-delays between the two recorded linear polarizations, alongside a model of the polarimetric response of the UWL inferred from applying measurement equation modelling⁶⁶ to November 2018 commissioning observations of PSR J0437−4715 across a large range of parallactic angles. Faraday rotation induced by the magnetized interstellar medium between us and the source was corrected by applying the nominal RM of 74.4 rad m⁻², which was obtained from observations taken on MJDs 58463, 58467 and 58470 (ref. ²¹). The data presented throughout this work follow the pulsar-polarization convention⁶⁷, where left- and right-handed circular polarization are represented as negative and positive values, respectively.

Noise diode observations were not taken during P885 observations between MJD 58488 and 58544. To calibrate the affected data, we made use of close-in-time noise diode scans that were taken up to several hours before or after the corresponding observations of XTE J1810−197. In principle, the telescope system should be stable over many hours (possibly even days) with minimal instrumental distortions or polarization leakage being introduced to these data. To verify this, we fit the RM of the magnetar at each epoch using direct fits to Stokes Q and U spectra extracted from the precursor component using RMNest⁶⁸. Note these measurements were not corrected for propagation through the ionosphere of the Earth, which can contribute between −0.2 and −2 rad m⁻² at the location of Parkes⁶⁹, which can account for small epoch-to-epoch deviations in the measured RM.

Two fold-mode observations performed on 15 and 18 December 2017 were flux calibrated using on- and off-source observations of the noise diode while pointed at or 1° offset from the radio galaxy 3C 218 (Hydra A) to measure the apparent brightness of the diode and correct for the system absolute gain and phase. However, the absolute gain of early observations could not be calibrated using standard methods. For these observations we estimate the flux density using a similar technique to that used by Scholz et al. to flux calibrate observations of PSR J1622−1950 (ref. ⁷⁰). We estimated the system equivalent flux density (SEFD) for the individual Stokes parameters as a function of frequency from the expected baseline root-mean-square (r.m.s.) of the calibrated fold-mode observation taken on 18 December via the radiometer equation⁷¹

$${\sigma }_{{{{\rm{off}}}}}={C}_{\mathrm{\ell }}\frac{{{{\rm{SEFD}}}}}{\sqrt{{n}_{\mathrm{p}}\Delta \nu \Delta t}}.$$

(1)

Here, C_ℓ is the loss factor from signal digitization, n_p is the number of summed polarizations, Δν the bandwidth and \(\Delta t={T}_{{{{\rm{int}}}}/{n}_{{{{\rm{bin}}}}}}\) is the integration time per phase bin. We then converted the individual Stokes parameters for the affected observation to units of Jansky by scaling the off-pulse r.m.s. by the right-hand side of equation (1) (with n_p = 1).

Jodrell Bank observations

XTE J1810–197 is regularly monitored with the 76 m Lovell Telescope at JBO with the L-band receiver. This is a hybrid system that detects radio waves with linear probes after passing through a quarter wavelength plate. The length of each observation varied from 20 min to several hours, but most of the observations were between 30 and 60 min long. The radio-frequency band was centred at 1,532 MHz, with a bandwidth of 384 MHz after RFI excision⁷². The observations were folded and dedispersed online. The folding requires an initial timing ephemeris, which was precise enough such that the time smearing is insignificant within each 20 s long subintegration. Full Stokes data were recorded with 1,024 phase bins across the pulse period and 768 frequency channels. After manual inspection and RFI excision, the data were polarization calibrated.

The polarization response of the system was tested by monitoring the polarization of three sources: PSRs B0540+23, B0611+22 and B1737−30, which were observed during the same sessions. These observations were compared to the known polarization properties of these sources by examining the differences with the published polarization profiles⁷³. For each observation, a frequency resolved receiver model was derived by fitting for a differential phase and gain. This solution minimizes the frequency dependence of the polarization properties in the observations (apart from those expected from Faraday rotation), and maximizes the similarity between the observed and known polarization properties. Given the obtained receiver solutions are similar, a smooth polynomial as function of frequency was used to describe frequency dependence of the parameters. These polynomials are fit to the combined parameters obtained from the individual solutions. This single combined receiver model was applied to the XTE J1810−197 data to remove the undesired frequency-dependent polarization response of the receiver.

Phase-resolved spectral indices

We tested whether the profile components of XTE J1810−197 exhibit different spectral indices by spectral fits to the total intensity spectra extracted from individual phase bins across the profile. This was performed using copies of the data that were binned such that 256 phase bins cover the rotation period of the magnetar. We fit the data using a simple power-law function of the form

$$S(x)=A\,{x}^{\kappa },$$

(2)

where x = ν/1 GHz is the observation frequency normalized to 1 GHz, A is a linear scaling parameter and κ the spectral index. We used a Gaussian likelihood of the form

$${{{\mathcal{L}}}}({{{\bf{d}}}}| \theta )={\prod_{i=1}^{N}} \frac{1}{\sqrt{2\pi {\sigma }^{2}}}\exp \left(-\frac{{({\bf{d}_{i}}-\mu (\theta ))}^{2}}{2{\sigma }^{2}}\right),$$

(3)

in which d is the measured flux density, N the number of flux density measurements, θ the model parameters, σ the flux density uncertainties and μ = S(x) our power-law model. Throughout this work, the posterior distributions for our various model fits to the data were sampled using Bilby⁷⁴ as a front-end to the Dynesty nested sampling algorithm⁷⁵.

Modelling the linear-to-circular conversion

Electromagnetic radiation that propagates through a birefringent medium with elliptical or linearly polarized natural wave modes will undergo a generalized form of Faraday rotation, known as Faraday conversion. Unlike standard Faraday rotation, induced by intervening plasma with circularly polarized modes such as the magnetized interstellar medium, there is no simple, catch-all model for describing the observational effects of Faraday conversion. This largely comes from the variety of environments in which Faraday conversion can be produced (for example, refs. ^9,27,28,76). Other propagation effects such as coherent and/or partially coherent mode mixing can also lead to a birefringent conversion of linear to circularly polarized radio waves without a well-defined frequency dependence^{15,16,17,18,24} To model the linear-to-circular conversion detected in the radio pulses from XTE J1810−197, we used the phenomenological framework described in ref. ²⁶, which we outline as follows.

The polarization vector P normalized by the total polarization, P, is defined as

$${{{{\bf{P}}}}}_{0}(\lambda )=\frac{1}{P}\left[\begin{array}{c}Q\\ U\\ V\end{array}\right]=\left[\begin{array}{c}\cos [2{\it{\Psi}} (\lambda )]\cos (2{\it{\chi }}_{0})\\ \sin [2{\it{\Psi}} (\lambda )]\cos (2{\it{\chi }}_{0})\\ \sin (2{\it{\chi }}_{0})\end{array}\right],$$

(4)

where χ₀ is the ellipticity angle and Ψ(λ) is the linear polarization PA as a function of wavelength. Ψ(λ) is expressed as

$${\it{\Psi}} (\lambda )={\it{\Psi }}_{0}+{{{\rm{GRM}}}}({\lambda }^{\alpha }-{\lambda }_{\mathrm{c}}^{\alpha }),$$

(5)

in which Ψ₀ is the reference PA at the central observing frequency (λ_c = 2,368 MHz), GRM was defined in the main text and α is the spectral dependence. The linear-to-circular conversion is then emulated by applying a pair of rotation matrices to shift the longitude and latitude of the polarization-rotation axis

$${{{{{R}}}}}_{\vartheta }=\left[\begin{array}{ccc}\cos (\vartheta )&0&\sin (\vartheta )\\ 0&1&0\\ -\sin (\vartheta )&0&\cos (\vartheta )\end{array}\right],$$

(6)

and

$${{{{{R}}}}}_{\varphi }=\left[\begin{array}{ccc}\cos (\varphi )&-\sin (\varphi )&0\\ \sin (\varphi )&\cos (\varphi )&0\\ 0&0&1\end{array}\right].$$

(7)

Here, ϑ is the angle about which the axis has been rotated about the Stokes U axis (away from the positive Stokes V axis) and φ is the angular rotation applied about the Stokes V axis. The full phenomenological model can be written as

$${\hat{{{{{P}}}}}}_{m}(\lambda )={{{{{R}}}}}_{\vartheta }\cdot {{{{{R}}}}}_{\varphi }\cdot {{{{\bf{P}}}}}_{0}(\lambda ).$$

(8)

In principle, the value of ϑ encodes information about the polarization modes of the intervening medium. For ϑ = 0° the modes are circular, 0° < ϑ < 90° or 90° < ϑ < 180° the modes are elliptical and ϑ = 90° corresponds to purely linear modes. In this context, ‘standard’ Faraday rotation would correspond to ϑ = φ = 0° with spectral dependence α = 2.

We applied the phenomenological model to the normalized Stokes Q, U and V spectra extracted from all pulse-phase bins between phases 0.490 and 0.535 for the time-averaged data. Posterior distributions for each of the model parameters were inferred using Bayesian parameter estimation. We used a joint Gaussian likelihood function of the form

$${{{\mathcal{L}}}}({{{\bf{P}}}}(\lambda )| \theta )=\mathop{\prod }\limits_{i=1}^{3}\mathop{\prod }\limits_{j=1}^{N}\frac{1}{\sqrt{2\pi {\hat{\sigma }}_{ij}^{2}}}\exp \left[-\frac{{({{{{\bf{P}}}}}_{i}({\lambda }_{j})-{\hat{{{{{P}}}}}}_{m}^{i}(\theta ;{\lambda }_{j}))}^{2}}{2{\hat{\sigma }}_{ij}^{2}}\right],$$

(9)

where \({\hat{\sigma }}_{ij}^{2}\) is the r.m.s. uncertainty on the ith Stokes parameter in the jth frequency channel (up to N frequency channels) after applying extra error scale factor (EFAC, σ_F) and error in quadrature (EQUAD, σ_Q) terms to correct for unaccounted systematic uncertainties as

$${\hat{\sigma }}_{ij}^{2}={({\sigma }_{{{{\rm{F}}}}}\times {\sigma }_{ij})}^{2}+{\sigma }_{{{{\rm{Q}}}}}^{2}.$$

(10)

Parameter estimation was conducted using the RMNest package⁶⁸. The data were Faraday de-rotated at the nominal RM of 74.4 rad m⁻² and binned to a frequency resolution of 8 MHz per channel before fitting the Faraday conversion model.

We initially suggested the unusually small wavelength dependencies (α ≲ 1) that are predominately seen between phases 0.49 and 0.53 may have been the result of averaging over pulse-to-pulse changes in the spectra due to stochastic plasma variations along the line of sight. This was tested by extracting the Stokes spectra from individual single pulses from the Parkes observations taken on MJDs MJD 58468 and 58469. Although search-mode data were also collected on MJD 58471, the resulting spectra were heavily contaminated by broadband, impulsive RFI. We therefore chose to not include the data from this epoch in our single-pulse investigation. Following data calibration and RFI excision, we fit the phenomenological model to a set of 6,537 Stokes spectra extracted from the single pulses where the total intensity flux as a minimum of ×10 the off-pulse r.m.s. value. Radio frequencies between 704 and 1,300 MHz are strongly affected by impulsive, broadband RFI, which becomes smeared across pulse phase after dedispersing the data. To avoid both the signal to noise and RFI-contamination issues, we ignored all data below 1,300 MHz when conducting the single-pulse parameter estimation. Spectra where the posterior distributions for {GRM, α} → {0, 0} (that is, no significant support for Faraday conversion) at the 95% confidence interval were not included in our final sample. We also ignored spectra where the GRM posterior distributions were not well constrained by imposing a limit where the range of inferred GRM values encompassed by either the upper or lower confidence intervals had to be less than ±20 rad m^−α. After imposing these thresholds, we were left with 2,142 spectra for which we had confidently detected and subsequently characterized the Faraday conversion.

Simulating multiple Faraday screens

Our fits to the polarization spectra extracted from the Parkes-UWL single-pulse data returned a spread of wavelength dependencies that are approximately centred on λ¹. This behaviour was interpreted as potentially resulting from one of two, potentially related scenarios: the relatively simple particle wind model fails to fully capture the complex electrodynamics that take place within the magnetosphere and/or near-wind environment of the magnetar, or there are more than one over-dense ‘Faraday screens’ in which the radiation has propagated through. Under the latter hypothesis, the broad distribution of wavelength dependencies inferred from our single-pulse fits would arise from incoherent addition of multiple rotations of the polarization vector along the line of sight.

We performed four sets of simulations using the phenomenological Faraday conversion model to emulate this behaviour, two of which were designed to test the possible impact of averaging over two OPMs. These OPM simulations used Gaussian priors on φ, the means of which were separated by 180°. The other two simulations sampled φ uniformly between 0 and 180°. We also tested the impact of drawing the injected GRM values from either a uniform or Gaussian distribution on the resulting scatter in the recovered α. After drawing the initial parameters, we generated two individual Stokes spectra in each simulation, both with the wavelength dependence held fixed at α = 1. An ‘observed’ spectrum was then created by incoherently summing these two initial spectra, which we then injected into Gaussian noise. Our measurement uncertainties for the simulated Stokes spectra were drawn from the median Stokes parameter uncertainties measured on MJD 59871. We then applied the same parameter estimation framework that was used for characterizing the real observations.

Phase-resolved Faraday rotation

Phase-resolved studies of rotation-powered pulsars have discovered apparent, rotation-phase-dependent deviations in their RM of away from the nominal ISM-induced values^11,12,48,49. These deviations have been speculated to arise from propagation effects within the magnetospheres of these pulsars. Several repeating FRBs have also been found to exhibit transient, rapid RM variations over relatively short (month to year) time spans^56,58, with peak ΔRMs of up to ±36,000 rad m⁻². Intense Faraday conversion has been identified in least one of these sources to date, which if not accounted for may be confused for large RM variations^56,60. To demonstrate the impact of unmodelled Faraday conversion on measurements of ‘standard’ Faraday rotation, we performed a set of phase-resolved RM fits to the MJD 58463–58471 observations of XTE J1810−197. We used the same RMNest-based approach used for modelling the Faraday conversion, but with a fixed wavelength dependence of α = 2 and the polarization-rotation axis longitude and latitude held fixed at the V axis pole (that is, {φ, ϑ} = {0, 0}).