2.1 NuStar observation

The Nuclear Spectroscopic Telescope Array (NuStar) is a hard X-ray telescope consisting of two identical modules (FPMA and FPMB) operating in the energy range 3–79 keV (Harrison et al. Reference Harrison2013). NuStar observed GX 304-1 on 2022 January 29 (MJD 59608.5, ObsID 30701015002) for a total duration of about 174 ks. Fig. 1 shows the one-day averaged monitoring observations of GX 304-1 from the MAXI mission in the 2–20 keV energy band and the epoch of the NuStar observation is marked with a vertical solid line. The orbital phase of the NuStar observation was about 0.65 (using the orbital parameters $P_{\mathrm{orb}}$ =132.189 d and $T_0$ =MJD 55425.6 Sugizaki et al. Reference Sugizaki, Yamamoto, Mihara, Nakajima and Makishima2015). We have extracted data separately from both the modules using the standard NuStar data analysis software (nustardas v2.1.4) included in heasoft v6.34 Footnote ^a along with the calibration database caldb version 20240826. The nupipeline task (version 0.4.12) was run with saamode=strict and tentacle=yes because the background event rates were high to obtain clean event files.

Figure 1.

MAXI one day averaged light curve of GX 304-1 in the 2–20 keV energy band spanning the duration MJD 55054.5 (2009 August 11) until MJD 60545 (2024 August 23). The solid, dotted and dashed vertical lines indicate the epochs of NuStar, Swift, and XMM-Newton observations, respectively. A few epochs of Swift observations before 2009 August 11 are not shown here as they precede the time since the MAXI mission became operational.

The event files were barycentered using the ftools task ‘barycorr’. We used a circular region of radius $80^{\prime\prime}$ centred on the source to extract the source events for both FPMA and FPMB modules. The nuproducts task was used to generate light curves binned in 1 s.

2.2 XMM-Newton observation

XMM-Newton (Jansen et al. Reference Jansen2001) observations of GX 304-1 were carried out on 2023 July 11 (MJD 60137, ObsID 0931790601) for a total duration of about 8 ks at an orbital phase of about 0.65 (using the orbital parameters $P_{\mathrm{orb}}$ =132.189 d and $T_0$ =MJD 55425.6 Sugizaki et al. Reference Sugizaki, Yamamoto, Mihara, Nakajima and Makishima2015) which is similar to the orbital phase of the NuStar 2022 observation. XMM-Newton has three European Photon Imaging Camera (EPIC) cameras viz. one pn and two metal oxide semi-conductor (MOS) cameras (Strüder et al. Reference Strüder2001; Turner et al. Reference Turner2001). The EPIC cameras were operated in the large window mode during this observation. The time resolution for the pn camera and the two MOS cameras used during this observation was 48 ms and 0.9 s, respectively. Observation Data Files (ODFs) were processed using version 21.0.0 of the XMM-Newton Science Analysis System (sas)Footnote ^b and the current calibration files (CCF)Footnote ^c released on 2024 April 29. We searched for possible intervals of high instrumental background which yielded a negative result. The effective source exposures were about 5 and 7 ks for the pn and MOS cameras, respectively. We corrected the event arrival times to the solar system barycenter using sas’s ‘barycen’ task. A circular region of radius $30^{\prime\prime}$ and $40^{\prime\prime}$ was used to extract the source events for the pn and the MOS cameras. Background events were extracted using circular regions away from the source with radii of $70^{\prime\prime}$ , $60^{\prime\prime}$ , and $50^{\prime\prime}$ for the pn, MOS1, and MOS2 cameras, respectively. We selected all the events in the energy range 0.3–10 keV, with pattern range 0–4 for the pn camera and 0–12 for the two MOS cameras. The averaged count rate for the pn and MOS cameras was about 1 and 0.4 counts s⁻¹, respectively. The background contribution to the total count rate was negligible for EPIC cameras (averaged count rate of about 0.01 counts s⁻¹).

2.3 Swift observations

The Neil Gehrels Swift Observatory (Gehrels et al. Reference Gehrels2004) observed GX 304-1 for various durations spanning the period from 2005 April 6 (MJD 53466) until 2024 February 27 (MJD 60367.8). Swift has three onboard instruments viz. the Burst Alert Telescope (BAT, Krimm et al. Reference Krimm2013), the X-Ray Telescope (XRT, Burrows et al. Reference Burrows2005), and the Ultraviolet/Optical Telescope (UVOT, Roming et al. Reference Roming2005). We have used the data from only the XRT and the UVOT instruments in this work. The log of Swift/XRT observations used in this study before regular outbursts were detected from the pulsar around 2010 April is given in Table A1. The pulsar entered a low luminosity state around 2017 September and was found to be in the same state until around 2018 October (Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018). We have analysed all available Swift observations since 2018 October to probe if the pulsar continues to remain in a similar low accretion regime, and these observations are listed in Table A2. Swift/XRT observations were mostly carried out in the photon counting (PC) mode having a time resolution of about 2.5 s. The Swift/XRT light curves for each epoch were extracted using the online tools (Evans et al. Reference Evans2009)Footnote ^d hosted by the UK Swift Science Data Centre. The typical on-source effective exposures are about 1 ks for each Swift/XRT pointing.

Swift/UVOT archival observations of GX 304-1 are available from 2006 September 20 (MJD 53998.1) until 2024 February 27 (MJD 60367.8), having typical exposure times of about a few tens of seconds to a few hundreds of seconds at different epochs. UVOT observations were performed with the filters V ( $\lambda=546.8$  nm, $\delta{\lambda}=76.9$  nm), B ( $\lambda=439.2$  nm, $\delta{\lambda}=97.5$  nm), U ( $\lambda=346.5$  nm, $\delta{\lambda}=78.5$  nm), UVW1 ( $\lambda=260.0$  nm, $\delta{\lambda}=69.3$  nm), UVM2 ( $\lambda=224.6$  nm, $\delta{\lambda}=49.8$  nm), and UVW2 ( $\lambda=192.8$  nm, $\delta{\lambda}=65.7$  nm).Footnote ^e The Level2 UVOT data were analysed using the uvotsource tool from heasoft v6.34 to determine magnitudes and fluxes. A circular region of radius $5^{\prime\prime}$ and $20^{\prime\prime}$ were used to select the source region and background region, respectively. The source was detected in the UVOT filters V, B, U, UVW1, UVM2, and UVW2 having an averaged magnitude of about 14, 15.7, 16.6, 17.9, 20.9, and 19.2, respectively.

3.1 Timing analysis

We used the NuStar combined FPMA and FPMB light curves in the 3–30 keV energy band for timing analysis. The FTOOLSFootnote ^f subroutine efsearch was used to search for pulsations using the chi-squared maximisation method (Leahy et al. Reference Leahy1983). The inferred spin period from NuStar 2022 January (MJD 59608.5) observations is 275.425 $\pm$ 0.003 s. The error on the measured spin period is estimated by fitting a Gaussian to the chi-square versus spin period plot obtained by efsearch. The 1- $\sigma$ error on the Gaussian centre estimate is taken as the error on the spin period. The estimated spin period is consistent with the known spin period of GX 304-1. The previous measured spin period of the source was about 275.12 s on 2018 June 3 (MJD 58272.25) (Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018), which suggests that the source has spun down by about 0.3 s. The folded pulse profile in the 3–30 keV energy band using NuStar observations is shown in Fig. 2.

Figure 2.

NuStar folded profile in the energy band of 3–30 keV obtained from the combined FPMA and FPMB light curve.

The estimated pulsed fraction ( $\mathrm{PF}=(\mathrm{I}_{\mathrm{max}}-\mathrm{I}_{\mathrm{min}})/(\mathrm{I}_{\mathrm{max}}+\mathrm{I}_{\mathrm{min}})$ , where $\mathrm{I}_{\mathrm{max}}$ and $\mathrm{I}_{\mathrm{min}}$ are the maximum and minimum intensities in the folded profile, respectively) in the 3–30 keV energy band is about 21%. A similar folded pulse profile and PF in the 3–30 keV energy band was obtained from the NuStar observations of the pulsar carried on 2018 June 3 (Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018) which suggests that the profile shape has not changed during this period. Similar PF of about 20% in the 3–20 keV energy band was obtained during the February-January 2012 INTEGRAL observations of the pulsar (Klochkov et al. Reference Klochkov2012).

We have used the XMM-Newton pn data for timing analysis as the pulsar is relatively fainter in the MOS data. We used the pn 0.3–10 keV light curve binned in 10 s for timing analysis. The spin period estimated using efsearch is 275.5 $\pm$ 0.3 s. The error on the estimated spin period is obtained by the method described earlier. The folded profile in the 0.3–10 keV band using the pn light curve is shown in Fig. 3 which shows the presence of two peaks at low energies. Similar folded pulse profiles having two dominant peaks in soft X-rays ( $\unicode{x003C}$ 10 keV) have been detected during outbursts of the pulsar in 2010 August (Devasia et al. Reference Devasia, James, Paul and Indulekha2011). The estimated PF from EPIC pn observations of the pulsar is about 25%.

Figure 3.

XMM-Newton folded profile of GX 304-1 in the energy band of 0.3–10 keV using data from EPIC pn observations.

3.2 Spectral analysis

The NuStar spectra were extracted from the same extraction parameters used for the light curves. We have done a combined fit of NuStar’s FPMA and FPMB data using xspec 12.14.1. The data have been binned using a minimum of 30 counts per bin. We have used a multiplicative model constant const to account for cross-instrument calibration uncertainties. The value of this constant was frozen at 1 for FPMA and was kept free for FPMB. The spectral fitting using xspec 12.14.1 (Arnaud Reference Arnaud, Jacoby and Barnes1996) was limited to 3–20 keV as the background dominates at higher energies. We fitted the combined spectra using an absorbed PL+BB model as shown in Fig. 4. We have used the tbabs model (Wilms, Allen, & McCray Reference Wilms, Allen and McCray2000) to take care of absorption in the spectrum during spectral fitting. As keeping the $N_\mathrm{H}$ free did not allow us to constrain the absorption, we kept it fixed at $9.6 \times 10^{21}$ cm $^{-2}$ which is the interstellar Galactic absorption along the direction of this source (HI4PI Collaboration et al. 2016).Footnote ^g The best-fit parameters obtained using this model were $\Gamma = 2.21^{+0.12}_{-0.14}$ , $kT_\mathrm{BB} = 1.17^{+0.03}_{-0.02}$ keV, with $\chi^{2}_{\nu}$ /d.o.f = 1.02/476. Using a source distance of 2.01 kpc, we obtained a BB radius $R_\mathrm{BB}= 100^{+7}_{-8} $ m. The unabsorbed flux in the energy range 3–20 keV is $\sim7.5 \pm 0.1 \times10^{-12}$ erg cm $^{-2}$ s $^{-1}$ , which implies a source luminosity of about $3.6 \times10^{33}$ erg s $^{-1}$ for a distance of 2.01 kpc. The estimated luminosity in the 0.5–100 keV energy range is $\sim1 \times10^{34}$ erg s $^{-1}$ using the WebPIMMS tool.Footnote ^h

Figure 4.

Spectrum of GX 304-1 obtained from NuStar’s FPMA (black) and FPMB (red), along with the best-fitting PL+BB model. The residuals between the data and the model are shown in the lower panel.

The XMM-Newton spectra for the pn and MOS cameras were extracted using the same extraction parameters used to extract the source and background light curves. The response matrices and ancillary files were generated using the tasks rmfgen and arfgen. The pn and MOS spectra were rebinned with a minimum of 25 counts per bin to ensure the applicability of the $\chi^{2}$ statistics. We have used xspec 12.14.1 (Arnaud Reference Arnaud, Jacoby and Barnes1996) for spectral fitting in the energy band of 0.5–10 keV. All spectral uncertainties are given at the 90% confidence level for each parameter. We checked that the separate fits of the pn and the MOS data gave similar results and then fitted them simultaneously to improve the statistics. The inter-calibration among the three instruments was accounted for using const.

We first fitted the spectra using an absorbed power-law (PL) model. We obtained hydrogen column density $N_\mathrm{H} = (2.36\pm0.14)\times 10^{22}$ cm $^{-2}$ and a photon-index $\Gamma$ = 1.83 $\pm$ 0.06, with $\chi^{2}_{\nu}$ /d.o.f. = 1.47/249. The fit using the absorbed-PL model was unacceptable and so we fitted the spectra using an absorbed blackbody (BB) model (Fig. 5(a)) which resulted in $N_\mathrm{H} = (7.14\pm0.06)\times 10^{21}$ cm $^{-2}$ , a BB temperature $kT_\mathrm{BB} = 1.16 \pm 0.02$ keV, with $\chi^{2}_{\nu}$ /d.o.f. = 1.12/245. It should be noted that the fitted $N_\mathrm{H}$ in this model is slightly less than the interstellar absorption ( $N_\mathrm{H} \sim 9.6 \times 10^{21}$ cm $^{-2}$ ) along the direction of this source. Using a source distance of 2.01 kpc, we obtained a BB radius $R_\mathrm{ BB}= 132\pm 5 $ m. The unabsorbed flux is $8.0 \pm 0.2 \times10^{-12}$ erg cm $^{-2}$ s $^{-1}$ in the energy range of 0.5–10 keV, which implies a source luminosity of $3.9 \pm 0.1 \times10^{33}$ erg s $^{-1}$ for a distance of 2.01 kpc.

Figure 5.

(a) Spectrum of GX 304-1 fitted with the absorbed blackbody model. The spectra of the pn, MOS1, and MOS2 cameras are shown in black, red, and green, respectively. The residuals between the data and the model are shown in the lower panel. (b) The same spectra shown in (a) fitted with the absorbed powerlaw+blackbody model with the residuals between the data and the model shown in the lower panel.

We also tried fitting the PL+BB model as shown in Fig. 5(b) and the best-fit parameters obtained using this model were $N_\mathrm{H} = (1.48^{+0.29}_{-0.31}) \times 10^{22}$ cm $^{-2}$ , $\Gamma = 1.65^{+0.44}_{-0.43}$ , $kT_\mathrm{BB} = 1.10^{+0.10}_{-0.09}$ keV, with $\chi^{2}_{\nu}$ /d.o.f = 0.91/243. Using the F-test analysis, the probability that the improvement in the fit occurs by chance was found to be $1\times 10^{-24}$ and $1\times 10^{-11}$ in comparison with the single PL and BB models, respectively. Using a source distance of 2.01 kpc, we obtained a BB radius $R_\mathrm{BB}= 113^{+21}_{-15} $ m. The unabsorbed flux in the energy range 0.5–10 keV is $5.2 \pm 1.3 \times10^{-12}$ erg cm $^{-2}$ s $^{-1}$ , which implies a source luminosity of about $2.5 \pm 0.6 \times10^{33}$ erg s $^{-1}$ for a distance of 2.01 kpc. The estimated luminosity in the 0.5–100 keV energy range is $\sim7 \times10^{33}$ erg s $^{-1}$ using the WebPIMMS tool.

3.3 Long-term spin evolution in GX 304-1

We use all the spin period measurements reported in the literature, those measured by the FERMI/GBM observations and the spin periods estimated in this work from NuStar and XMM-Newton observations to construct the long-term spin history of GX 304-1, which is shown in Fig. 6. The spin evolution of this pulsar spans nearly five decades (February 1977 until July 2023). 272 s pulsations from the source were detected by McClintock et al. (Reference McClintock, Rappaport, Nugent and Li1977) using SAS-3 observations, which were also detected by Huckle et al. (Reference Huckle1977) using Ariel V observations. Thereafter, the source became quiescent for almost three decades when it was detected using INTEGRAL observations (Manousakis et al. Reference Manousakis2008). Pulsations having a periodicity of about 275.5 s was detected by FERMI/GBM during the onset of an outburst in 2010 April which suggests that the pulsar spun down by about 3.3 s during the long dormant period. The estimated spin-down rate during this quiescent period is $\sim-4.3 \times 10^{-14}$ Hz s $^{-1}$ which is similar to those detected in other BeXRB pulsars during long ( $\sim$ yr) dormant periods (Malacaria et al. Reference Malacaria2020; Chandra, Roy, & Agrawal Reference Chandra, Roy and Agrawal2023). During the active period since 2010, the pulsar underwent a series of regular outbursts until 2013 before the outburst decayed. The pulsar exhibited spin-up during outbursts at a rate of $\sim1 \times 10^{-12}$ Hz s $^{-1}$ (Sugizaki et al. Reference Sugizaki, Mihara, Nakajima and Makishima2017; Malacaria et al. Reference Malacaria2020) and spin-down between outbursts at a rate of $\sim-5 \times 10^{-14}$ Hz s $^{-1}$ (Malacaria et al. Reference Malacaria2020). The long-term spin-up rate during this active episode of the pulsar was estimated to be $\sim1.3 \times 10^{-13}$ Hz s $^{-1}$ (Malacaria et al. Reference Malacaria2020).

Figure 6.

Long-term spin history of GX 304-1 from 1977 February until 2023 July. The reversal in trend from long-term spin-up to long-term spin-down of the X-ray pulsar is discernible between the period 2010–2023.

The pulsar was detected by FERMI/GBM around MJD 57005 (2014 December 14) and MJD 57008 (2014 December 17) having spin period of about 274.8 s suggesting that the pulsar had undergone a change from a long-term spin-up to a spin-down trend during the preceding quiescent episode of the pulsar. Interestingly, the pulsar was again detected after one orbital period (about 132 d) around MJD 57140 (2015 April 28) and MJD 57143 (2015 May 1) having a similar spin period of about 274.8 s which confirms the onset of spin-down episode of the pulsar. The spin period measured using NuStar observation during the low X-ray luminosity state of the pulsar around MJD 58272 (2018 June 3) was 275.12 $\pm$ 0.02 s (Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018). Spin periods estimated in this work using the NuStar and the XMM-Newton observations from 2022 January and 2023 July corroborates the detection of a long-term spin-down manifestation in this pulsar. The estimated long-term spin-down rate is $\sim-3.4 \times 10^{-14}$ Hz s $^{-1}$ which is similar to those detected during spin-down periods between X-ray outbursts in this source. This suggests that the underlying mechanism of spin-down between regular outbursts observed in this source during 2010–2013 and that during the ongoing quiescent period since 2015 might be the same. Spin variations on long time-scales have been detected in several accretion-powered pulsars (Makishima et al. Reference Makishima1988; Nagase Reference Nagase1989; Bildsten et al. Reference Bildsten1997; Chakrabarty et al. Reference Chakrabarty1997; Fritz et al. Reference Fritz2006; Camero-Arranz et al. Reference Camero-Arranz, Finger, Ikhsanov, Wilson-Hodge and Beklen2009; Inam, Şahiner, & Baykal 2009; González-Galán et al. Reference González-Galán2012; Chandra et al. Reference Chandra, Roy, Agrawal and Choudhury2021).

3.4 X-ray activity during change in long-term spin trend

The X-ray light curves in the 2–20 keV and 15–50 keV energy bands from the MAXI and Swift/BAT monitoring observations of the source are shown in Fig. 7. The light curves are plotted for the period spanning MJD 56380-57000 (2013 March 29–2014 December 9) when the source underwent spin evolution from a long-term spin-up to spin-down trend and was undetected by FERMI/GBM observations. The dotted vertical lines in the figures show the epochs of periastron passages using the orbital parameters $P_{\mathrm{orb}}$ =132.189 d and $T_0$ =MJD 55425.6 (Sugizaki et al. Reference Sugizaki, Yamamoto, Mihara, Nakajima and Makishima2015). There is an indication of a weak X-ray brightening of the source during periastron passages around MJD 56482 (2013 July 9), MJD 56614 (2013 November 18), MJD 56746 (2014 March 30), and MJD 56879 (2014 August 10) which is seen in both MAXI and Swift/BAT observations. The estimated X-ray luminosities during these periastron passages are about ${2}\times 10^{35}$ , ${7}\times 10^{34}$ , ${6}\times 10^{34}$ , and ${2}\times 10^{34}$ erg s $^{-1}$ which suggests that accretion is not quenched during this period. The luminosities are inferred using the luminosities given in Tsygankov et al. (Reference Tsygankov2019) when the source was in a low luminosity state and then scaling the luminosity using the MAXI count rate for a given epoch (assuming that there is no spectral evolution at low luminosities which is confirmed by Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018).

Figure 7.

(a) MAXI one day averaged light curve of GX 304-1 in the 2–20 keV energy band spanning the duration when the change in long-term spin trend occurred in this pulsar. The dotted vertical lines indicate the epochs of periastron passages of the neutron star. (b) Swift/BAT one day averaged light curve of GX 304-1 in the 15–50 keV energy band shown during the same duration with times of periastron passages marked with vertical dotted lines.

3.5 Long term photometric observations of the companion star

The long-term photometric observations of the companion star V850 Cen is shown in Fig. 8. We have plotted the V-band magnitudes reported in the literature (Corbet et al. Reference Corbet1986; Haefner Reference Haefner1988) during the period MJD 44285.5 (1980 February 16) until MJD 46121.5 (1985 February 25) along with those obtained from the ASAS-SN optical observations (https://asas-sn.osu.edu/), AAVSO (https://www.aavso.org/), and Swift/UVOT. The averaged V-band magnitude during the period spanning almost five years from 1980–1985 was $\sim$ 13.6, while that during the period MJD 57423.7 (2016 February 5) to MJD 60367.8 (2024 February 27) was $\sim$ 13.9. Optical brightening of the companion star in BeXRBs has been associated with X-ray outbursts in these systems (Corbet et al. Reference Corbet, Mason, Cordova, Branduardi-Raymont and Parmar1985; Negueruela et al. Reference Negueruela1997; Reig et al. Reference Reig, Larionov, Negueruela, Arkharov and Kudryavtseva2007; Caballero-Garca et al. Reference Caballero-Garca2016; Coe et al. Reference Coe2024).

Figure 8.

Long-term photometric observations of the companion star of GX 304-1 using observations reported in the literature (Corbet et al. Reference Corbet1986; Haefner Reference Haefner1988) spanning the duration MJD 44285.5 until MJD 46121.5 and those obtained from the ASAS-SN optical observations (https://asas-sn.osu.edu/), AAVSO (https://www.aavso.org/) and Swift/UVOT.

The increase in averaged V-band magnitude by about 0.3 suggests that the companion star has become relatively less active recently due to which there have likely been no episodes of mass ejection from the companion star that feeds the relatively bright X-ray outbursts in this binary pulsar. This is confirmed by the weak X-ray detection of the pulsar on MJD 57411 (2016 January 24) and MJD 57525 (2016 May 17) at a flux level of 23 $\pm$ 4 mCrab and 22 $\pm$ 14 mCrab respectively using MAXI observations (Nakajima et al. Reference Nakajima2016b,a) after which the pulsar has remained dormant. Unfortunately, no regular optical monitoring observations of the source is available during the period when the pulsar switched from a long-term spin-up trend to spin-down except for one optical spectroscopic observation (around MJD 56763 (2014 April 16)) using the the 3.9 m Anglo Australian Telescope (AAT) which suggested that the radius of the decretion disc around the companion star had shrunk significantly (by almost a factor of 2) compared to the epochs when the pulsar was moderately active in X-rays (Malacaria et al. Reference Malacaria2017).

3.6 Long-term ultraviolet observations of the companion star

The X-ray (2–20 keV) and ultraviolet light curves for GX 304-1 obtained from MAXI and Swift/UVOT observations are shown in Fig. 9. The Swift/UVOT light curves show the inferred fluxes in the U, UVW1, and the UVW2 filters. The ultraviolet fluxes of the source show a marked gradual increase around MJD 55300 (2010 April) until around MJD 56000 (2012 March) in all three filters (U, UVW1, and UVW2) which interestingly coincides with the re-kindling of the X-ray outbursts detected in this pulsar as observed from simultaneous MAXI X-ray light curve. The increase in the ultraviolet fluxes in the U, UVW1 and the UVW2 filters are about a factor of 2.3, 2, and 1.5 during the dormant period (around MJD 55268) compared to that during the beginning of X-ray outbursts (around MJD 55550). It also seems that the increase in the ultraviolet activity of the companion star preceded the onset of bright X-ray outbursts by about half a year. A similar increase in the ultraviolet flux in the UVW1 band preceded the onset of X-ray outbursts in the BeXRB Swift J004516.6-734703 by about a year (Kennea et al. Reference Kennea2020). The increase in UV flux was attributed to the formation of a circumstellar disc around the companion star in Swift J004516.6-734703 (Kennea et al. Reference Kennea2020). It is likely that the increase in the UV signatures in GX 304-1 might also indicate the resurgence of the formation of a decretion disc around the companion star which was big enough to trigger bright X-ray outbursts in the binary after about half a year. After the regular X-ray outbursts ceased in GX 304-1, the ultraviolet fluxes in the three bands have shown little long-term variation with no indication of returning to the pre-outburst level. However, there is suggestion of a decrease in the ultraviolet fluxes around MJD 60300 (2023 December) on short timescales.

Figure 9.

Long-term X-ray and ultraviolet observations of GX 304-1 as observed with MAXI and Swift/UVOT, respectively. We show, from top to bottom, the one-day averaged X-ray count rate in the 2–20 keV band from MAXI and the UV fluxes in the U, UVW1, and UVW2 bands from Swift/UVOT.

3.7 Long-term quiescent X-ray activity of GX 304-1 using Swift/XRT

The long-term Swift/XRT light curve of GX 304-1 in the 0.3–10 keV band is shown in Fig. 10(a) for the duration spanning 2005 April 6 (MJD 53466) until 2010 March 15 (MJD 55270.86) and in Fig. 10(b) for the period from 2018 December 17 (MJD 58469) until 2024 February 27 (MJD 60367.8). The count rates have been averaged for a given epoch. It is observed that the XRT count rate during the period between MJD 53466-55270.86 varied from about $\sim$ 0.4 $\ \mathrm{counts \ s^{-1}}$ to $\sim$ 1.2 counts s⁻¹ showing a dynamic range of about 3. The averaged count rate during this period was about 0.7 counts s⁻¹. This suggests that the pulsar was moderately active in X-rays but did not undergo an outburst as the peak XRT count rates even during weak outbursts in 2016 February was about 2–4 counts s⁻¹ (Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018).

Figure 10.

(a) Swift/XRT light curve (0.3–10 keV energy band) of GX 304-1 spanning the quiescent phase for the duration 2005 April 6 (MJD 53466) until 2010 March 15 (MJD 55270.86). The vertical dotted lines indicate the epochs of periastron passages of the neutron star. The averaged XRT count rate during this duration is about 0.7 counts s⁻¹. (b) Same as (a) for the duration spanning nearly five years from 2018 December 17 (MJD 58469) until 2024 February 27 (MJD 60367.8). The averaged XRT count rate during this duration is about 0.2 counts s⁻¹.

The XRT count rate spanning the duration 2018 December 17 until 2024 February 27 varied from about 0.06–0.3 counts s⁻¹ (having a dynamic range of about 5) which suggests that the pulsar was in a low X-ray activity state. This quiescent behaviour of the pulsar is similar to that observed from 2016 June until 2018 October when the XRT count rate varied in the range of about 0.1–0.25 counts s⁻¹ (Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018). The averaged count rate during this period was about 0.2 counts s⁻¹. As seen in Fig. 10(b), the pulsar also did not exhibit any clear enhancement in X-ray activity at periastron passages. This intriguing low luminosity state of the source has now lasted for about seven years since September 2017. Similar long-term quiescent episodes on nearly decadal timescales has been detected in other Be/X-ray binaries such as 1A 0535+262, GS 0834-430, RX J0209.6-7427, XTE J1946+274, 2S 1417-624, KS 1947+300, and RX J0440.9+4431 (Usui et al. Reference Usui2012; Miyasaka et al. Reference Miyasaka2013; Gupta, Naik, & Jaisawal Reference Gupta, Naik and Jaisawal2019; Chandra et al. Reference Chandra, Roy, Agrawal and Choudhury2020, Reference Chandra, Roy and Agrawal2023; Liu et al. Reference Liu2023).

4.1 Quasi-spherical accretion in GX 304-1

The long-term spin-down in this pulsar can be explained using the theory of quasi-spherical accretion from the stellar wind of the companion star (Shakura et al. Reference Shakura, Postnov, Kochetkova and Hjalmarsdotter2012; Shakura et al. Reference Shakura, Postnov, Kochetkova and Hjalmarsdotter2014). The conditions for the applicability of this model such as slow spin period and X-ray luminosity $\unicode{x003C} {4}\times 10^{36}$ erg s $^{-1}$ are fulfilled by GX 304-1 observations. The spin period of this pulsar is about 275 s and the inferred X-ray luminosity during the period when the spin evolution changed from a long-term spin-up to the spin-down regime is about ${2}\times 10^{35}$ erg s $^{-1}$ except during bright outbursts of the source when the luminosity reaches about $10^{37}$ erg s $^{-1}$ (Yamamoto et al. Reference Yamamoto2011a; Klochkov et al. Reference Klochkov2012; Malacaria et al. Reference Malacaria, Klochkov, Santangelo and Staubert2015; Sugizaki et al. Reference Sugizaki, Yamamoto, Mihara, Nakajima and Makishima2015; Jaisawal, Naik, & Epili Reference Jaisawal, Naik and Epili2016). The inferred luminosity during the low state of the pulsar from XMM-Newton observations (when the pulsar was spinning down) is about $2.5 \times 10^{33}$ erg s $^{-1}$ in the 0.5–10 keV energy band. The spin-up during outbursts and spin-down on short time-scales in between regular outbursts have been explained using this model by Postnov et al. (Reference Postnov2015). Using the quasi-settling accretion theory, the estimated spin-down rate is given by Postnov et al. (Reference Postnov2015),

(1) \begin{equation} {\dot{\omega}^*}_{sd}\sim 10^{-8} \frac{Hz}{d} \Pi_{sd} \mu^{13/11}_{30}\dot{M}^{3/11}_{16}\left({\frac{P^*}{100 \ \mathrm{s}}}\right)^{-1},\end{equation}

where $\mu_{30}=\mu/10^{30} [\mathrm{G\ cm^3}]$ is the dipole magnetic moment given by $\mu=\mathrm{BR^3/2}$ where R is the radius of the neutron star having a typical value of 10 km, $\dot{M}_{16}=\dot{M}/10^{16}[\mathrm{g\ s^{-1}}]$ is the mass accretion rate onto the neutron star and $P^*$ is the equilibrium spin period of the neutron star. We obtain $\dot{{\omega}^*}_{sd} \sim -3.1 \times 10^{-8}$ Hz/d (using $\Pi_{sd} \sim 4.6$ (Shakura et al. Reference Shakura, Postnov, Kochetkova and Hjalmarsdotter2012; Reference Shakura, Postnov, Kochetkova and Hjalmarsdotter2014; Postnov et al. Reference Postnov2015), $\dot{M}_{16}=0.22$ using $\mathrm{L_X}=0.1\dot{M}\mathrm{c^2}$ and $\mathrm{L_X}={2}\times 10^{35}$ erg s $^{-1}$ , $\mu_{30}=2.35$ and $P^{*}_{eq}=275\ $ s) which is slightly larger than the estimated long-term spin-down rate by a factor of $\sim$ 1.7. Fig. 11 shows the observed spin-up/down rates obtained from a linear fit of spin evolution of the pulsar during spin-up/down episodes.

Figure 11.

Plot showing estimated spin-up and spin-down rates spanning the duration of about five decades. The estimated spin-up and spin-down rates using the quasi-spherical settling accretion theory are shown using horizontal dotted lines (Shakura et al. Reference Shakura, Postnov, Kochetkova and Hjalmarsdotter2012; Shakura et al. Reference Shakura, Postnov, Kochetkova and Hjalmarsdotter2014; Postnov et al. Reference Postnov2015).

The spin-up rate estimated during outbursts using the quasi-settling accretion theory is $\sim2.5 \times 10^{-7}$ Hz/d (Postnov et al. Reference Postnov2015). The dotted horizontal lines in Fig. 11 show the estimated spin-up/spin-down rates using the quasi-spherical settling accretion theory. The long-term spin-down rates are remarkably similar to the short time-scale spin-down rates estimated between outbursts in this source which suggests that both the short-term and long-term spin-down might be caused by the same mechanism in this pulsar. The long-term spin-up rate is about a factor of 4 smaller than the spin-up rates estimated during X-ray outbursts detected in this pulsar. Thus, this model can estimate the spin-down rate within a factor of $\sim$ 1.7 and may qualitatively explain the long-term spin-down in this pulsar. Quasi-spherical accretion has been used to explain the long-term spin-down episodes in GX 1+4 and Vela X-1 (Shakura et al. Reference Shakura, Postnov, Kochetkova and Hjalmarsdotter2012; Chandra et al. Reference Chandra, Roy, Agrawal and Choudhury2021).

4.2 Tug of war between spin-up and spin-down torques

It is observed around MJD 56000 (ref. Fig. 11) that the spin-up rates estimated during outbursts seem to diminish systematically with time (except for one instance of rapid spin-up during a giant outburst detected in this pulsar) by a factor of about 2 as the pulsar changes trend from a long-term spin-up to spin-down. However, the spin-down rates inferred in between the outbursts remain nearly the same during this period (Fig. 11). The estimated peak X-ray flux in the 2–10 keV energy band during the spin-down episodes in between the outbursts diminished by a factor of about 1 000 compared to the flux during the spin-up regimes (ref. Table 1 in Postnov et al. Reference Postnov2015) which suggests that the accretion rate onto the neutron star ( $\dot{M}$ ) decreased by the same factor during spin-down phases. The spin-up torque ( $K_\mathrm{su}$ ) acting on the neutron star is given by Pringle & Rees (Reference Pringle and Rees1972),

(2) \begin{equation} K_\mathrm{su} = \dot{M} (GM_\mathrm{ns} r_\mathrm{m})^{1/2},\end{equation}

where G is the gravitational constant, $M_\mathrm{ns}$ is the mass of the neutron star and $r_\mathrm{m}$ is the radius at which the effective pressure in the accretion disc equals the magnetic pressure. As the accretion rate drops during the spin-down regimes, consequently the spin-up torque also decreases significantly during this period. The spin evolution of an accretion-powered pulsar is given by,

(3) \begin{equation} 2 \pi I \dot{\nu} = K_\mathrm{su} - K_\mathrm{sd},\end{equation}

where I is the moment of inertia of the neutron star and $K_\mathrm{sd}$ is the spin-down torque acting on the neutron star. Assuming that the spin-down torque acting on the neutron star is nearly constant (which is observed in Fig. 11 that the estimated spin-down torques in between outbursts are almost the same), the spin-down torque would eventually overtake the decreasing spin-up torque (after around MJD 56200) leading to a long-term spin-down in the pulsar.

The estimated averaged X-ray luminosities (in the 0.5-100 keV energy range using the method described earlier) during the period MJD 57005-57008 and MJD 57140-57143 when the pulsar was already spinning down was $\sim{4.4}\times 10^{35}$ and $\sim{9.6}\times 10^{35}$ erg s $^{-1}$ , respectively. These luminosities are about a factor of 10–100 smaller than those detected during bright X-ray outbursts in this pulsar which suggests that the increase in accretion rate during this period did not lead to a sufficient increase in the spin-up torque to change the long-term spin-down trend of the pulsar. The estimated luminosities after about a year around MJD 57423 and MJD 57506 were about ${1.2}\times 10^{35}$ and ${2.8}\times 10^{34}$ erg s $^{-1}$ , respectively (Rouco Escorial & Wijnands Reference Rouco Escorial and Wijnands2016). From long-term X-ray monitoring observations of the source spanning the duration around MJD 58000-58420, the estimated luminosities were found to lie in the range $\sim{0.8-1.9}\times 10^{34}$ erg s $^{-1}$ (Rouco Escorial & Wijnands Reference Rouco Escorial and Wijnands2016). Recent Swift/XRT, XMM-Newton and NuStar observations analysed in this work confirm the prolonged low state of the pulsar. The relatively low luminosity of the pulsar since the last bright outburst detected in 2013 suggests relatively weak spin-up torque acting on the pulsar and the continued dominance of the spin-down torque over the spin-up torque. The estimated spin period of the source (275.12 $\pm$ 0.02 s) around MJD 58272 (Rouco Escorial & Wijnands Reference Rouco Escorial and Wijnands2016) and those obtained from NuStar and the XMM-Newton observations in this work confirms this proposition as the pulsar continues to spin-down on long time-scales.

The long-term spin-down of the pulsar ( $\sim-4.3 \times 10^{-14}$ Hz s $^{-1}$ ) changed to a short-term spin-up trend after the onset of outbursts in 2010 ( $\sim1.3 \times 10^{-13}$ Hz s $^{-1}$ ) with the averaged spin-up rate being an order of magnitude higher than the long-term spin-down rate. This suggests that the average momentum imparted by the accreted material during the spin-up phase was greater than the momentum lost due to magnetic breaking over the long-term spin-down phase lasting about 28 yr which is also observed in SMC X-3 (Townsend et al. Reference Townsend2017). We now discuss possible mechanisms to explain the enigmatic long-term low luminosity state of the pulsar since 2018 December.

4.3 Propeller effect

The XRT count rates shown in Fig. 10 are converted into the corresponding 0.5–100 keV luminosities (Fig. 12) using the spectral study and luminosities from Tsygankov et al. (Reference Tsygankov2019) (when the source was faint having an XRT count rate of about 0.13 counts s⁻¹) and then scaling our observed XRT count rates which are listed in Tables A1 and A2. An assumption is made during this conversion that the spectrum of the pulsar does not change during faint state which is confirmed by Escorial et al. (Reference Escorial, van den Eijnden and Wijnands2018). The estimated luminosities shown in Fig. 12(a) for the duration 2005 April 6 (MJD 53466) until 2010 March 15 (MJD 55270.9) varied in the range of $\sim{3.7-11.2}\times 10^{34}$ erg s $^{-1}$ showing variation by a factor of about 3. The luminosities for the duration spanning 2018 December 17 (MJD 58469) until 2024 February 27 (MJD 60367.8) is shown in Fig. 12(b) showing luminosities in the range of $\sim{0.6-2.9}\times 10^{34}$ erg s $^{-1}$ , which suggests that the source has been quasi-stable in a low luminosity state for the last five years. The pulsar was in a slightly higher low luminosity regime during 2005 April 6–2010 March 15. Accreting pulsars may switch to the propeller regime at low mass accretion rates caused by the centrifugal barrier if the velocity of the rotating magnetosphere exceeds the local Keplerian velocity (Illarionov & Sunyaev Reference Illarionov and Sunyaev1975). The critical luminosity for the onset of the propeller effect ( $L_\mathrm{prop}$ ) is given by Tsygankov et al. (Reference Tsygankov2017),

(4) \begin{equation} L_\mathrm{prop}\simeq \frac{GM\dot{M}_\mathrm{prop}}{R} \simeq 4 \times 10^{37} k^{7/2}B_{12}^2 P_s^{-7/3} M_{1.4}^{-2/3} R_6^5 \,\mathrm{erg\,s}^{-1}, \end{equation}

where M, R, $P_s$ and B are the mass, radius, spin period, and magnetic field of the neutron star, respectively. $\dot{M}_\mathrm{ prop}$ is the mass-accretion rate onto the neutron star. The factor k is the ratio of the magnetospheric radius and the Alfvén radius which in the case of disc accretion is taken to be $k=0.5$ (Ghosh & Lamb Reference Ghosh and Lamb1978). Using $M=1.4\ {\rm M}_{\odot}$ , R=10 km, $P_s \sim 275.4$ s, $B=4.7 \times 10^{12}$ G (Yamamoto et al. Reference Yamamoto2011a) and $k=0.5$ (assuming disc accretion), the estimated $L_\mathrm{prop}$ is $\sim3.2\times 10^{32}$ erg s $^{-1}$ which is shown by a dashed horizontal line in Fig. 12(a) and (b).

Figure 12.

(a) Plot showing estimated X-ray luminosity (0.5–100 keV) of GX 304-1 spanning the duration 2005 April 6 (MJD 53466) until 2010 March 15 (MJD 55270.9). The horizontal dashed line shows the estimated limiting luminosity for the propeller effect to set in. The dotted and dash-dotted horizontal lines show the limiting luminosity for accretion to occur from a cold disc. The averaged X-ray luminosity (0.5–100 keV) during this duration is about $6.3 \times 10^{34}$ erg s $^{-1}$ . (b) Same as (a) for the duration spanning from 2018 December 17 (MJD 58469) until 2024 February 27 (MJD 60367.8). The averaged X-ray luminosity (0.5–100 keV) during this duration is about $1.5 \times 10^{34}$ erg s $^{-1}$ . The downward arrows show the epoch of the NuStar and the XMM-Newton observations used in this study and the estimated 0.5–100 keV unabsorbed luminosities for these epochs are shown by stars.

The magnetic field $(B=4.7 \times 10^{12}$ G Yamamoto et al. Reference Yamamoto2011a) used in estimating the limiting luminosity due to the onset of the propeller effect using equation (4) was obtained from the detection of cyclotron resonance scattering feature (CRSF) in the spectra. The magnetic field can also be estimated independently by using (Christodoulou, Kazanas, & Laycock Reference Christodoulou, Kazanas and Laycock2016),

(5) \begin{equation}B = \left(2\pi^2 \xi^7\right)^{-1/4}\sqrt{\frac{G M I}{R^6} |\dot{P_S}|} \,, \end{equation}

where $\xi$ is a dimensionless parameter which is the ratio of the inner edge of the accretion disc and the magnetospheric radius (Ghosh & Lamb Reference Ghosh and Lamb1979; Wang Reference Wang1996; Christodoulou et al. Reference Christodoulou, Kazanas and Laycock2016), M and R are the mass and the radius of the neutron star, respectively, I is the moment of inertia of the neutron star given by $I=\frac{2MR^2}{5}$ and $\dot{P_S}$ is the rate of spin change of the pulsar during outbursts. Using $\xi$ =1, $M=1.4\ {\rm M}_{\odot}$ , $R=10$ km, $\dot{P_S} \sim 3.1 \times 10^{-8}$ s s $^{-1}$ (Postnov et al. Reference Postnov2015) and $G=6.67\times 10^{-8}$ cm $^3$ g $^{-1}$ s $^{-2}$ , the estimated magnetic field of the neutron star is $\sim3.8 \times 10^{13}$ G, which is higher by a factor of about 8 than that inferred from the detection of cyclotron line in the spectra. Using $B\sim 3.8 \times 10^{13}$ G, the estimated luminosity for the onset of the propeller effect is $\sim2.6\times 10^{33}$ erg s $^{-1}$ , which is about an order of magnitude higher than that estimated earlier. The magnetic field of the neutron star can also be estimated independently using the models given by Ghosh & Lamb (Reference Ghosh and Lamb1979) and Kluźniak & Rappaport (Reference Kluźniak and Rappaport2007), which are applicable to disc-fed systems. The Ghosh and Lamb model (Ghosh & Lamb Reference Ghosh and Lamb1979) is applicable to systems irrespective of whether they have achieved spin equilibrium and the model predicts (Klus et al. Reference Klus, Ho, Coe, Corbet and Townsend2014)

(6) \begin{equation} -\dot{P}=5.0\times10^{-5} \mu_{30}^{2/7} n(\omega_{s}) R_{6}^{6/7}\left(\frac{M}{M_\odot}\right)^{-3/7}I_{45}^{-1} (PL_{37}^{3/7})^2,\end{equation}

where $\dot{P}$ is the long-term spin derivative of the neutron star (in s yr $^{-1}$ ), I is the moment of inertia of the neutron star and $n(\omega_{s})$ is the dimensionless accretion torque and depends on the fastness parameter $\omega_{s}$ (Ghosh & Lamb Reference Ghosh and Lamb1979; Klus et al. Reference Klus, Ho, Coe, Corbet and Townsend2014). Using $\dot{P}\sim 0.08$ s yr $^{-1}$ , $n(\omega_{s})\sim$ 1, $R=10^6$ cm, $M=1.4\ {\rm M}_{\odot}$ , $I_{45}$ =1.92 g cm $^3$ , $P=275$ s and $L \sim 2\times 10^{37}$ erg s $^{-1}$ , the magnetic field is estimated to be $\sim5.5 \times 10^{6} \ G$ , which is lower by a factor of about $10^6$ than that inferred from the detection of cyclotron line in the spectra. Using the Kluzniak and Rappaport model (Kluźniak & Rappaport Reference Kluźniak and Rappaport2007)

(7) \begin{equation}-\dot{P}=8.2\times10^{-5}\mu_{30}^{2/7} g(\omega_{s}) R_{6}^{6/7}\left(\frac{M}{M_\odot}\right)^{-3/7}I_{45}^{-1} (PL_{37}^{3/7})^2,\end{equation}

where $g(\omega_{s})$ depends on the fastness parameter $\omega_{s}$ and is nearly equal to unity. Using $\dot{P}\sim 0.08$ s yr $^{-1}$ , $g(\omega_{s})\sim$ 1, $R=10^6$ cm, $M=1.4\ {\rm M}_{\odot}$ , $I_{45}$ =1.92 g cm $^3$ , $P=275$ s and $L \sim 2\times 10^{37}$ erg s $^{-1}$ , the magnetic field estimated using this model is $\sim 9.8\times 10^{5}$ G, which is similar to that estimated using the Ghosh and Lamb model by within a factor of about 6. Similar lower magnetic field estimates compared to that inferred from cyclotron lines were obtained for accreting pulsars (not near spin equilibrium) by Klus et al. (Reference Klus, Ho, Coe, Corbet and Townsend2014) using the Ghosh and Lamb model (Ghosh & Lamb Reference Ghosh and Lamb1979) as well as the Kluzniak and Rappaport model (Kluźniak & Rappaport Reference Kluźniak and Rappaport2007). The magnetic field estimates obtained using the Ghosh and Lamb model and the Kluzniak and Rappaport model would reduce the threshold luminosity for the onset of the propeller effect by a factor of about $10^6$ compared to that obtained using the magnetic field estimated using the cyclotron line.

The estimated luminosities of the pulsar during the faint state (Fig. 12) are well above the threshold luminosity (at least by a factor of about 19 for $L_\mathrm{prop} \sim 3.2\times 10^{32}$ erg s $^{-1}$ and by a factor of about 3 for $L_\mathrm{ prop} \sim 2.6\times 10^{33}$ erg s $^{-1}$ ) for the propeller effect to set in. Another telltale manifestation of the onset of the propeller effect is the sudden decrease in the luminosity of the pulsar as observed in 4U 0115+63 and V0332+53 (Campana et al. Reference Campana2001; Tsygankov et al. Reference Tsygankov2016) which is not observed in GX 304-1. In addition, the detection of pulsations from the source using NuStar and XMM-Newton observations indicates that accretion is still continuing at low luminosities. Hence, the long-term low luminosity regime of the pulsar cannot be explained using the propeller effect.

4.4 Sustained accretion from a cold disc?

The observed long-term low luminosity regime of the pulsar may be explained using accretion from a ‘cold disc’ wherein for low accretion rates well above the propeller regime, the temperature of the disc may fall below the Hydrogen ionisation temperature of about 6 500 K (Tsygankov et al. Reference Tsygankov2017). In this case, the matter in the disc is non-ionised (referred to as ‘cold disc’) and accretion can proceed through the cold disc (Tsygankov et al. Reference Tsygankov2017). Two criteria need to be satisfied for accretion from the cold disc. First, the accretion rate has to be sufficiently high to overcome the centrifugal barrier which implies that the luminosity of the source should be higher than the threshold luminosity for the propeller effect to take over which is satisfied during the Swift/XRT, NuStar, and XMM-Newton observations of GX 304-1 (ref. Fig. 12). Secondly, the luminosity of the source should be lower than the luminosity for stable accretion from a cold disc ( $L_\mathrm{cold}$ ) given by Tsygankov et al. (Reference Tsygankov2017),

(8) \begin{equation} L_\mathrm{cold} = 9\times 10^{33}\,k^{1.5}\,M_{1.4}^{0.28}\,R_6^{1.57}\,B_{12}^{0.86}\quad \mathrm{erg\,s^{-1}}.\end{equation}

The above threshold for $L_\mathrm{cold}$ assumes that the disc temperature is highest at the magnetospheric radius and as a result the disc temperature for any radius lesser than the magnetospheric radius is less than 6 500 K (Tsygankov et al. Reference Tsygankov2017). Using $M=1.4\ {\rm M}_{\odot}$ , $R=10$ km, $B=4.7 \times 10^{12}$ G (Yamamoto et al. Reference Yamamoto2011a) and $k=0.5$ (assuming disc accretion), the estimated $L_\mathrm{cold}$ is $\sim 1.2\times 10^{34}$ erg s $^{-1}$ which is shown by a dash-dotted horizontal line in Fig. 12(a) and (b).

The observed 0.5–100 keV luminosities of the source lies within a factor of about 2–3 times the $L_\mathrm{cold}$ estimated for the source during the period since December 2018 and within a factor of about 3–10 during the period spanning 2005 April 6 (MJD 53466) until 2010 March 15 (MJD 55270.9). It should be noted that the equation (8) does not take into account the interaction between the pulsar magnetosphere and the accretion disc and a more accurate threshold for $L_\mathrm{cold,acc}$ is given by Tsygankov et al. (Reference Tsygankov2017),

(9) \begin{equation} L_\mathrm{cold,acc} \simeq 7\times 10^{33}\, A^{-7/13}\,k^{21/13}\,M_{1.4}^{3/13}\,R_6^{23/13} B_{12}^{12/13}\,T_{6500}^{28/13}\ \mathrm{erg\,s^{-1}},\end{equation}

where A is given by,

(10) \begin{equation} A = \left\{ \begin{array}{ll} \strut\displaystyle 0.057\,\beta^{-6}, & \mathrm{if}\quad\beta \ge \frac{\sqrt{3}}{2},\\ 1-\beta, & \mathrm{if}\quad\beta \unicode{x003C} \frac{\sqrt{3}}{2}, \end{array} \right.\end{equation}

and $T_{6500}=T_\mathrm{eff}/6500\,\mathrm{K}$ . The parameter $\beta$ indicates the location in the accretion disc where the viscous stress impacting the temperature distribution of the disc disappears (Tsygankov et al. Reference Tsygankov2017). For $\beta$ of unity, the viscous stress disappears at the magnetospheric radius while for $\beta$ =0, the stress disappears at a radius much smaller than the magnetospheric radius (Tsygankov et al. Reference Tsygankov2017). Assuming that the viscous stress disappears at the magnetospheric radius (i.e. $\beta$ =1) and using $T_\mathrm{eff}=6500$ K, the threshold $L_\mathrm{cold,acc}$ is estimated to be $\sim4.4\times 10^{34}$ erg s $^{-1}$ which is shown by a dotted horizontal line in Fig. 12(a) and (b). Interestingly, $L_\mathrm{cold,acc}$ is higher by a factor of about 4 than $L_\mathrm{cold}$ and using the more accurate threshold for accretion to proceed from a cold (non-ionised) disc, the estimated luminosities of the source lie below this threshold suggesting that accretion is likely mediated through a cold disc during the prolonged low luminosity period from 2018 December until 2024 February. However, it seems that during the period 2005 April 6 (MJD 53466) until 2010 March 15 (MJD 55270.9), the pulsar was in a low luminosity state and likely not accreting from a cold disc for most of the time. Accretion from a cold disc has been suggested to occur during periods in between outbursts in GRO J1008-57 (lasting for about 200 d Tsygankov et al. Reference Tsygankov2017). In GX 304-1, this phenomenon has been observed in between Type I outbursts (lasting a few tens of days) and also after the cessation of regular outbursts (lasting for about 400 d Escorial et al. Reference Escorial, van den Eijnden and Wijnands2018). The prolonged low-luminosity state (spanning a duration of about 5 yr as shown in Fig. 12) powered by accretion from a cold disc in GX 304-1 might be the longest manifestation of this phenomenon reported in any accreting pulsar.

4.5 Accretion from stellar wind

The companion stars in BeXRB systems contain massive stars and it is likely that accretion may proceed directly via the stellar wind. The companion star in GX 304-1 belongs to the B2V class (Mason et al. Reference Mason, Murdin, Parkes and Visvanathan1978; Thomas et al. Reference Thomas, Morton and Murdin1979; Parkes et al. Reference Parkes, Murdin and Mason1980) which have typical terminal wind velocities ( $v_w$ ) of $\sim\mathrm{800 \ km \ s^{-1}}$ and mass-loss rates of about $10^{-8}\,{\rm M}_{\odot}\ \mathrm{yr^{-1}}$ (Prinja Reference Prinja1989; Vink, de Koter, & Lamers Reference Vink, de Koter and Lamers2000). Assuming that the gravitational potential energy of the captured stellar wind by the neutron star is entirely converted into X-rays, the X-ray luminosity ( $L_\mathrm{wind}$ ) is given by Reig & Zezas (Reference Reig and Zezas2018),

(11) \begin{equation}L_\mathrm{wind} \approx 4.7 \times 10^{37} M_{1.4}^3 \, R_6^{-1} \, M_\mathrm{*}^{-2/3} \, P_\mathrm{orb}^{-4/3} \, \dot{M}_{-6} \, v_\mathrm{w,8}^{-4} \, \, \mathrm{erg \, s^{-1}},\end{equation}

where $M_\mathrm{*}$ is the mass of the companion star in solar masses, $P_\mathrm{orb}$ is the orbital period of the binary in days while $\dot{M}$ and $v_w$ are expressed in units of $10^{-6} {\rm M}_{\odot}\ \mathrm{yr^{-1}}$ and $10^{-8} \mathrm{cm \ s^{-1}}$ , respectively. Using $M_\mathrm{*}$ =9.9 ${\rm M_{\odot}}$ (Sugizaki et al. Reference Sugizaki, Yamamoto, Mihara, Nakajima and Makishima2015), $v_w \sim \mathrm{800 \ km \ s^{-1}}$ , $\dot{M} \sim 10^{-8} {\rm M}_{\odot} \mathrm{\ yr^{-1}}$ for B2V type stars (Prinja Reference Prinja1989; Vink et al. Reference Vink, de Koter and Lamers2000), $P_\mathrm{orb}\sim$ 132.2 d (Sugizaki et al. Reference Sugizaki, Yamamoto, Mihara, Nakajima and Makishima2015), $M=10\ {\rm M}_{\odot}$ , and $R=10$ km, the estimated X-ray luminosity from the stellar wind is $\sim4\times 10^{32}$ erg s $^{-1}$ . The estimated $L_\mathrm{wind}$ is lower by about a factor of 15–70 than the range of luminosities of the pulsar shown in Fig. 12(b). The estimated X-ray luminosity during the low state from XMM-Newton and NuStar observations is $\sim2.5\times 10^{33}$ erg s $^{-1}$ in the 0.5–10 keV energy band and $\sim3.6\times 10^{33}$ erg s $^{-1}$ in the 3–20 keV energy band, respectively, which are an order of magnitude higher than that can be powered solely by wind accretion. Thus, accretion from the stellar wind emanating from the Be star alone cannot explain the observed long-term low luminosity regime observed in this pulsar, and it is possible that other favourable accretion mechanisms such as accretion through a cold (non-ionised) disc may operate simultaneously.

4.6 Origin of soft excess in the spectra

The hot BB excess ( $kT_\mathrm{BB}$ > $\sim$ 1 keV) detected in GX 304-1 is similar to those detected in other BeXRBs RX J0440.9+4431 (La Palombara et al. Reference La Palombara, Sidoli, Esposito, Tiengo and Mereghetti2012), RX J0146.9+6121 (La Palombara & Mereghetti Reference La Palombara and Mereghetti2006), 4U 0352+309 (Coburn et al. Reference Coburn2001; La Palombara & Mereghetti Reference La Palombara and Mereghetti2007), RX J1037.5-5647 (Reig & Roche Reference Reig and Roche1999; La Palombara et al. Reference La Palombara, Sidoli, Esposito, Tiengo and Mereghetti2009), 3A 0535+262 (Mukherjee & Paul Reference Mukherjee and Paul2005), 4U 2206+54 (Masetti Reference Masetti2004; Torrejón et al. Reference Torrejón, Kreykenbohm, Orr, Titarchuk and Negueruela2004; Reig et al. Reference Reig2009), SAX J2103.5+4545 (Inam et al. Reference Inam, Baykal, Swank and Stark2004), and SXP 1062 (Hénault-Brunet et al. Reference Hénault-Brunet2012; González-Galán et al. Reference González-Galán2018). These BeXRBs have long pulse periods $(P \unicode{x003E} 100$ s) and the hot BB excess were detected during low luminosity states ( $\leq5\times 10^{35}$ erg s $^{-1}$ ) in these pulsars (La Palombara et al. Reference La Palombara, Sidoli, Esposito, Tiengo and Mereghetti2012). The spin period of GX 304-1 is about 275 s and the inferred luminosity during low states is $\sim2.5\times 10^{33}$ and $\sim3.6\times 10^{33}$ erg s $^{-1}$ from XMM-Newton and NuStar observations, respectively, which suggests that GX 304-1 also belongs to this category of BeXRBs showing a soft X-ray excess.

It has been shown that in the low luminosity accretion powered pulsars ( $L_\mathrm{X}\le10^{36}$ erg s $^{-1}$ ), the thermal component can be attributed to either emission by photo-ionised or collisionally heated diffuse gas or thermal emission from the surface of the neutron star (Hickox, Narayan, & Kallman Reference Hickox, Narayan and Kallman2004). Assuming that the soft excess comes from the surface of the neutron star, the size of the emission region can be estimated using $R_{\rm col}\sim R_\mathrm{NS}$ $(R_\mathrm{NS}/R_m)^{0.5}$ (Hickox et al. Reference Hickox, Narayan and Kallman2004), where $R_{\rm col}$ is the radius of the accretion column and $R_m$ is the magnetospheric radius. The magnetospheric radius is given by (Campana et al. Reference Campana, Colpi, Mereghetti, Stella and Tavani1998),

(12) \begin{equation}R_{m} =2\times 10^7\,{\dot M}_{15}^{-2/7}\,B_9^{4/7}\,M_{1.4}^{-1/7}\,R_6^{12/7} \ \mathrm{cm},\end{equation}

where ${\dot M}$ is the accretion rate (in units of $10^{15}\,\mathrm{\ g \, s^{-1}}$ ), B, M and R are the magnetic field, mass and radius of the neutron star, respectively. Using $L_X \sim 5\times 10^{33}$ erg s $^{-1}$ , $M=1.4\ {\rm M}_{\odot}$ and $R=10$ km, the accretion rate is estimated to be $\sim2.7 \times 10^{13}\,\mathrm{\ g \, s^{-1}}$ . Using $B\sim 4.7 \times 10^{12}$ G (Yamamoto et al. Reference Yamamoto2011a), the magnetospheric radius is estimated to $\sim7 \times 10^{9}$ cm. The estimated radius of the accretion column (which is an estimate of the expected size of the polar cap) is R $_{\rm col} \sim$ 120 m which is remarkably similar to the estimated black body emitting radius of about 100–110 m. This suggests that the observed blackbody emission emanates from the polar cap of the neutron star.

4.7 Exploring spectral energy distribution of the companion star

We searched the literature for photometric detection of the companion star at other wavelengths using the catalogues available in the VizieR database (Ochsenbein, Bauer, & Marcout Reference Ochsenbein, Bauer and Marcout2000). The catalogue entries using the Gaia (Prusti et al. Reference Prusti2016; Brown et al. Reference Brown2021) and TESS (Stassun et al. Reference Stassun2019) observations were taken within $5^{\prime\prime}$ of the source position. The spectral energy distribution (SED) of the companion star is shown in Fig. 13 plotted along with the Swift/UVOT estimated fluxes in the U, UW1, and UW2 filters. We have shown the UVOT fluxes obtained during the quiescent state just before the regular X-ray outbursts began from the source (around MJD 55268) and that during the beginning of outbursts (around MJD 55550). There is an indication of UV excess from the companion star when X-ray outbursts were detected from the neutron star compared to the time when the source was in a quiescent phase. The detailed SED modelling of the companion star is beyond the scope of this work.

Figure 13.

Spectral energy distribution for the companion star of GX 304-1. The black-filled circles show data taken from literature using the Gaia (Prusti et al. Reference Prusti2016; Brown et al. Reference Brown2021) and TESS (Stassun et al. Reference Stassun2019) observations and are obtained from the Vizier database (Ochsenbein et al. Reference Ochsenbein, Bauer and Marcout2000). The blue and red stars show data from the Swift/UVOT in U, UW1 and UW2 filters obtained during the quiescent state just before the regular X-ray outbursts began from the source (around MJD 55268) and that during the beginning of outbursts (around MJD 55550), respectively.