The second run (O2) of Advanced LIGO and Advanced Virgo led to the breakthrough discovery of the first GW signal1 from a neutron star (NS) merger coincident with the short duration GRB170817A2,3,4, at a distance of 40 Mpc. In several aspects GRB170817A differs from the garden-variety short GRBs observed at cosmological distances. It is a low-luminosity burst with a relatively soft spectrum4, followed by a bright and short-lived quasi-thermal emission (kilonova5,6) peaking at optical and infrared wavelengths7,8,9,10, and a delayed long-lived non-thermal emission (afterglow) visible from X-rays to radio energies8,11,12. Throughout the paper we generically refer to the event as GW170817, and specifically refer to AT2017gfo when discussing the kilonova emission, whereas we use GRB170817A when discussing the GRB and afterglow properties. All these nomenclatures refer to different aspects of the same astrophysical event.

The characteristics of GW170817 might explain why similar events eluded identification thus far. Short GRB localizations are mainly based on rapid observations, typically taken by NASA’s Neil Gehrels Swift Observatory within ~100 s after the burst. At these early times, the UV/optical emission from the kilonova might not be detectable yet, and the delayed onset of the X-ray emission prevents a rapid localization with the Swift X-Ray Telescope (XRT). Within the Swift sample of ~100 short GRBs, ~30 bursts have no counterpart at longer wavelengths. These events are not localized with enough precision to confidently determine their host galaxy and distance scale. It is therefore plausible that a few bursts like GRB170817A had already been detected in the nearby Universe but remained unidentified due to the lack of a precise localization. However, within the sample of short GRBs localized by Swift, we identified an event which resembles the properties of GRB170817A. The short GRB150101B was fortuitously localized thanks to its proximity to a low-luminosity AGN, initially considered as the candidate X-ray counterpart. The detection of this X-ray source triggered a set of deeper observations at X-ray and optical wavelengths, which uncovered the true GRB afterglow. The properties of GRB150101B are non-standard and, in particular, its X-ray and optical counterparts are brighter and longer-lived than those of other cosmological short GRBs. We show that these observations could be explained by a scenario similar to the one proposed for GW170817 in which the optical emission is powered by a bright blue kilonova8,9,13, and the X-rays trace the GRB afterglow viewed off-axis8,12,14.


Comparison with other short GRBs

GRB150101B stands out of the short GRB sample for its prompt emission and afterglow properties. Its gamma-ray phase is weak and very short in duration (~20 ms, Fig. 1), an order of magnitude shorter than GRB170817A. The burst fluence is ~10−7 erg cm−2 (10–1000 keV) corresponding to a total isotropic-equivalent gamma-ray energy release Eγ,iso ~4.7 × 1048 erg at z = 0.1341 (see Section Environment), one of the lowest ever detected by Swift15 (Fig. 1, inset). Since this event was not found by the on-board software, no prompt localization was available. Follow-up observations started with a delay of 1.5 days, after a ground-based analysis found the transient gamma-ray source in the Swift data. Nonetheless, bright optical and X-ray counterparts were found. This is highly unusual as delayed follow-up observations of short GRBs typically fail to detect the counterpart, especially in the case of weak gamma-ray events.

Fig. 1
figure 1

Prompt phase of GRB15010B. a Gamma-ray light curve of GRB150101B as seen by Swift BAT. The time bin is 2 ms. The background contribution is subtracted through the mask-weighting procedure. The shaded area shows the duration T90 ~ 12 ms of the emission in BAT. Vertical error bars are 1 σ. The inset shows the distribution of isotropic-equivalent gamma-ray energy for short GRBs detected by Swift15. The positions of GRB150101B and, for comparison, GRB170817A are marked by the vertical lines. b Background subtracted gamma-ray light curve of GRB150101B above 300 keV, as seen by Fermi GBM. The time bin is 4 ms. It shows that at high energies the prompt phase starts a few milliseconds earlier

In the standard GRB model, the broadband afterglow emission is produced by the interaction of the relativistic fireball with the ambient medium16. It is therefore expected that the afterglow brightness depends, among other variables, on the total energy release of the explosion17. Indeed, typical GRB afterglows are found to be correlated with the total energy radiated in the gamma-rays, being brighter afterglows associated on average to the most luminous GRBs. This is valid for both long duration and short duration bursts18,19. In this context, two surprising features of GRB170817A were that, despite its weak gamma-ray emission, the burst was followed by a bright optical transient20,7, AT2017gfo, and a long-lived X-ray afterglow8,12. The observed optical luminosity of AT2017gfo (Lpk ~ 1041 erg s−1) lies within the range of optical afterglows from short GRBs (1040 erg s1 < Lopt < 1044 erg s−1 at 12 h). However, when normalizing for the gamma-ray energy release, the optical emission stands out of the afterglow population (Fig. 2a). Indeed, this early UV/optical component is widely interpreted as the kilonova emission from the merger ejecta8,9,13, and its luminosity is not directly related to the gamma-ray burst as in the case of a standard afterglow. The optical afterglow of GRB170817A was instead much fainter than AT2017gfo at early times and became visible >100 days after the merger21. Figure 2a singles out GRB150101B as another event with an optical counterpart brighter than the average afterglow population. Its luminosity (Lopt ~ 2 × 1041 erg s−1 at 1.5 d) is ~2 times brighter than AT2017gfo at the same epoch and appears to decay at a slower rate (0.5 ± 0.3 mag d−1), although we caution that residual light from the underlying galaxy may be affecting this estimate.

Fig. 2
figure 2

Comparison of GRB150101B with GW and GRB afterglows. a Optical light curves of short GRBs normalized to the observed gamma-ray energy release. Downward triangles are 3 σ upper limits. Vertical error bars are 1 σ. The optical afterglow of GRB170817A became visible >100 days after the merger21 and is not reported in the plot. b X-ray light curves of short GRBs normalized to the observed gamma-ray energy release. The shaded area shows the 68% dispersion region. In both cases, the counterparts of GW170817 (AT2017gfo and GRB170817A) and GRB150101B stand out of the sample of standard afterglows. They can be described as a bright kilonova (dotted lines) followed by a late-peaking off-axis afterglow (dashed lines)

Figure 2b shows the X-ray light curves of short GRBs normalized by the isotropic-equivalent gamma-ray energy release. In this case too, the X-ray counterparts of GRB170817A and GRB150101B differ from the general population of short GRBs and are consistent with the predictions of off-axis afterglows22. In the off-axis scenario, the post-peak afterglow reveals the total blastwave energy and is therefore as bright as standard on-axis afterglows at a similar epoch, whereas only a small fraction of the total prompt energy is visible in gamma-rays. Off-axis afterglows are therefore expected to have a LX/Eγ,iso ratio higher than the average population of bursts seen on-axis, as observed for GRB150101B and GRB170817A.

Temporal analysis

The earliest follow-up observations of GRB150101B were performed by the Swift satellite starting 1.5 days after the burst. Swift monitoring lasted for 4 weeks and shows a persistent X-ray source (Fig. 3, top panel). The study of GRB150101B at X-ray energies is complicated by its proximity to a low-luminosity AGN, which contaminates the Swift measurements. Observations with the Chandra X-ray Observatory (PI: E. Troja, A. Levan) were critical to resolve the presence of the two nearby sources, and to characterize their properties. The brighter X-ray source, coincident with the galaxy nucleus, shows no significant flux or spectral variations between the two epochs (7.9 d and 39.6 d after the burst). Its observed flux is ~3.7 × 10−13 erg cm−2 s−1 in the 0.3–10 keV energy band, thus accounting for most of the emission measured by Swift. The fainter X-ray source, coincident with the position of the GRB optical counterpart23, instead dropped by a factor of 7 between the two epochs (Fig. 3, bottom panel). By assuming a power-law decay, FXt, we derive a temporal decay slope α ~ 1.2, typical of standard afterglows. A previous study of this event23, based only on the Chandra dataset, used a simple power-law decay to describe the afterglow temporal evolution from early (~1.5 d) to late (~40 d) times. However, Fig. 3 (top panel) shows that such decay (dashed line) would violate the early Swift measurements, not considered in past analyses.

Fig. 3
figure 3

X-ray observations of GRB150101B. Swift observations (top panel) found a single steady X-ray source. Chandra observations (bottom panel) revealed the presence of two nearby X-ray sources: a brighter constant source at the location of the galaxy nucleus (AGN), and a fainter variable source at the location of the GRB optical counterpart. Its X-ray behavior is consistent with a standard power-law decay (dashed line) or a rising afterglow from either an off-axis jet (solid line) or a cocoon (dot-dashed line). However, the superposition of a constant source with a power-law model violates the early Swift observations. These are instead well described by the superposition of a constant source with a late-peaking afterglow. Vertical error bars are 1 σ. The horizontal gray line shows the average flux level of the AGN

The flat Swift light curve, although dominated by the AGN contribution, provides an important indication on the behavior of the early GRB afterglow, which had to remain sub-dominant over the observed period. Figure 3 shows that this is consistent with the onset of a delayed afterglow, as observed for GRB170817A8. Two leading models are commonly adopted to describe the broadband afterglow evolution of GRB170817A: a highly relativistic structured jet seen off-axis8,12,14, and a choked jet with a nearly isotropic mildly relativistic cocoon11,24. We fit both models to the GRB150101B afterglow with a Bayesian MCMC parameter estimation scheme, using the same priors and afterglow parameters as in ref. 12. For the structured jet, we assumed that the energy follows a Gaussian angular profile E(θ) = E0 exp(−θ)−/2θc 2) where θc is the width of the energy distribution. The fit results are summarized in Table 1 and shown in Fig. 3 as a solid line (off-axis jet), and a dot-dashed line (cocoon). These models can reproduce both the Chandra data (bottom panel) and the Swift light curve (top panel). In the cocoon model, the predicted post-peak temporal slope is α ~ 1.0, consistent with the result from the simple power-law fit. This implies that the afterglow peak must precede the first Chandra observation at 8 d, although not by much as the Swift light curve constraints tpk » 1 d. In the jet scenario, the post-peak temporal decay tends to α ~ 2.5, and constrains the range of possible peak times to tpk ~10–15 d.

Table 1 Afterglow parameters for GRB150101B

Other scenarios, such as a long-lasting (~8 d) X-ray plateau followed by a standard afterglow decay, are consistent with the Swift and Chandra constraints. However, the required timescales far exceed the typical lifetime (<104 s) of X-ray plateaus and would not follow the time-luminosity relation25 usually observed in GRB afterglows.

Spectral analysis

The afterglow X-ray spectrum is well described by a simple power-law, Fν ν−β, with spectral index β = 0.64 ± 0.17 (68% confidence level). This implies a non-thermal electron energy distribution with power law slope p = 2.28 ± 0.34 seen below the cooling break, similar to GRB170817A12,26. The first Swift observation at 1.5 days is likely dominated by the AGN contribution (Fig. 3) and can place a 3 σ upper limit on the early X-ray afterglow of ~1.5 × 10−13 erg cm−2 s−1 (Methods section), if one assumes the same spectral shape as the later Chandra epoch. This is a plausible assumption as, for example, continued monitoring of GRB170817A shows no significant variations in its afterglow spectral shape during the first 12 months12,26.

In Fig. 4, we show the spectral energy distribution of the GRB counterpart. At early times, the optical luminosity exceeds the afterglow extrapolation based on the X-ray limits. This optical excess is consistent with the emergence of a kilonova slightly brighter (by a factor of ~2) than AT2017gfo. Given the limited dataset, we cannot exclude that the optical excess is due to an intrinsic variability of the afterglow (e.g., flares). However, these types of chromatic features are usually observed at X-ray rather than at optical wavelengths, typically occur within a few hours after the GRB, and are more frequent in long GRBs than in short GRBs27,28. The luminosity and timescales of the observed optical excess more naturally fit within the kilonova scenario6,29,30. The observed color (rJ < 1.2 at 2.5 d) is somewhat bluer than the color of AT2017gfo at the same epoch, possibly indicating a higher temperature of the ejecta. A slower cooling rate is also consistent with the shallower temporal decay of the optical light.

Fig. 4
figure 4

Spectral energy distribution of GRB150101B. Downward triangles are 3 σ upper limits. At early times, the optical light is brighter than expected based on the extrapolation of the X-ray constraints (dot-dashed line), suggesting that it belongs to a different component of emission. The blue area shows the spectrum of AT2017gfo8,10,20 at 1.5 days, rescaled by a factor 2 in order to match the optical brightness of GRB150101B. At later times, the lack of optical detection is consistent with the X-ray afterglow behavior. At both epochs, our model is consistent with the lack of radio detection at 5.7 d23

At later times, this excess is no longer visible. The deep upper limit from Gemini shows that at ~10 days the afterglow became the dominant component and the kilonova already faded away. This is consistent with the behavior of AT2017gfo8,10,20, and predicted in general by kilonova models13,29,30.


Only a minor fraction (<30%) of short GRBs is associated to an early-type host galaxy31. This number decreases to ~18% if one considers only bona-fide associations, i.e., those with a low probability of being spurious. Notably, both GRB150101B and GW170817 were harbored in a luminous elliptical galaxy (Fig. 5).

Fig. 5
figure 5

The host galaxy of GRB150101B. Color image of the host galaxy of GRB150101B created from the HST/WFC3 observations in filters F606W (blue, green) and F160W (red). The two intersecting lines mark the location of the GRB afterglow. The galaxy optical spectrum (inset) displays several absorption lines (Ca II H & K, G-band, Mg, and Na at z = 0.1341) and a red continuum

We used the NASA/ESA Hubble Space Telescope (HST) to image the galaxy of GRB150101B (PI: Troja) in two filters, F606W and F160W, ~10 months after the burst. Earlier observations (PI: Tanvir) were performed ~40 days after the burst and are used to search for possible transient emission. Further photometric and spectroscopic studies were carried out with the 4.3 m Discovery Channel Telescope. Our results (Methods section) are in keeping with previous findings23,32. The galaxy morphology, its high luminosity (~4 L*), old stellar population (~2 Gyr) and low on-going star formation rate (<~0.5 Msun yr−1) closely resemble the properties of NGC 499333,34. The location of GRB150101B is however farther off center than GW170817, 7.3 kpc away from the galaxy nucleus (~0.9 reff; Methods section). This is a region of faint optical and infrared light (Fig. 5), suggestive of a natal kick velocity for its progenitor, which merged far from its birth site.


There is broad consensus that the properties of GW170817 can be explained by the emergence of a kilonova evolving from blue to red colors8,10,13,20, and a delayed afterglow component8,11,12,21. However, key aspects of this epochal event remain poorly understood. For instance, the luminous blue emission from AT2017gfo points to a large amount (~0.01 Msun) of rapidly expanding (v ~ 0.2 c) ejecta with relatively low opacity35,36, as expected if they are mainly composed of light r-process nuclei. This tail of massive, high-velocity ejecta is challenging to reproduce in standard NS mergers models37,38, and its origin is still not clear. Another highly debated topic is the successful emergence of a relativistic jet, as the broadband afterglow data are well-explained either by a highly relativistic structured jet seen off-axis8,12,14, or by a choked jet embedded in a mildly relativistic wide-angle cocoon11,24. In this context, the discovery of cases similar to GRB170817A, either through gamma-ray or GW triggers, is crucial to understand whether this burst was a peculiar event, a standard explosion or the prototype of a new class of transients.

The case of GRB150101B provides important information to help in this quest. This burst was located in an environment remarkably similar to GW170817, a luminous elliptical galaxy characterized by an old stellar population and no traces of on-going star formation. Therefore, despite the lack of a simultaneous GW detection, a NS merger origin for this burst is highly favored. The prompt phase of GRB150101B, although much shorter in duration, resembles in other aspects the phenomenology of GRB170817A39. Similar to GW170817, the weak gamma-ray emission of GRB150101B was accompanied by unusually bright optical and X-ray counterparts. As shown in Fig. 2a, b, this phenomenology does not match the typical behavior of short GRB afterglows and is suggestive of a GW170817-like explosion, in which the early-time optical emission is dominated by the kilonova and the X-ray emission traces the onset of a delayed afterglow.

If our interpretation is correct, GRB150101B is only the second known case of this phenomenological class of transients and its study can help us to delineate the general properties of these explosions, disentangling them from the particular properties of GW170817. First, the optical counterpart of GRB150101B is more luminous than AT2017gfo at the same epoch (by a factor of ~2), and fades at a slightly slower rate (~0.5 mag d−1). Figure 4 shows that the afterglow contribution is sub-dominant at early times, and the most likely origin of the observed optical light seems a bright kilonova. Interestingly, its brightness and decay rate closely resemble the candidate kilonova from GRB05070940. By assuming an opacity κ ~ 1 g cm−3 and imposing that the peak of the kilonova emission is tpk < 2 d we estimate a large mass >0.02 Msun and velocity v > 0.15c of lanthanide-poor ejecta (see Eq. 4 and 5 of ref. 41), challenging to reproduce in standard simulations of NS mergers37.

Our results suggest that a luminous blue kilonova might be a common feature of NS mergers rather than a peculiar characteristic inherent to GW170817, and reinforce the need for an efficient power source, such as a long-lived NS42, to produce high optical luminosities at early times. While in the majority of previous short GRBs, searches were not sensitive to probe luminosities ~1041 erg s−1, in other cases the optical emission might have been misclassified as standard afterglow. Figure 6 compares the optical measurements of GRB150101B and other nearby short GRBs with the kilonova AT2017gfo. Whereas in some events, such as GRB050509B and GRB080905A, any kilonova component was either delayed or significantly fainter than AT2017gfo43, in other cases the optical counterparts have luminosities comparable to AT2017gfo and could therefore be entirely powered by the kilonova emission or be a mixture of afterglow and kilonova. However, given the poor sampling and large errors of these datasets, it appears that past searches had the sensitivity to detect these early blue kilonovae, but they were not adequate to identify their contribution. Rapid and deep multi-color imaging of future nearby short GRBs would be critical to probe the emergence of a kilonova component from the earliest times (~minutes after the merger) and disentangle it from any underlying afterglow. The optical to gamma-ray ratio, as presented in Fig. 2a, would also be a useful tool to weed out the most promising candidates. The presence of a luminous blue kilonova, if as common (although not ubiquitous) as suggested by our results, is promising for future follow-up observations of GW sources with wide-field optical monitors44.

Fig. 6
figure 6

Early optical emission from short GRBs. Comparison between the kilonova AT2017gfo (dashed line; the hatched area shows the ±1 mag region) and the optical counterparts of nearby short GRBs. Vertical error bars are 1 σ. Downward triangles are 3 σ upper limits. Due to the limited spectral coverage of most events, we did not apply a k-correction and present the absolute magnitudes in the observed r-band filter. However, given the low redshift of these events, we expect this correction factor to be <0.5 mag. The data are from refs. 40,66,67,68

Unfortunately, the constraints at infrared wavelengths are not particularly sensitive to the emergence of a kilonova. The deep HST upper limit at 40 days can exclude some extreme scenarios with large masses (~0.03 Msun) of lanthanide-rich ejecta. This limit is consistent with the range Mej ~0.01–0.1 Msun derived from the candidate kilonova in GRB130603B45 and with the properties of the kilonova AT2017gfo, in which the red component only requires <0.001 Msun of high-opacity material, typical for a NS–NS merger.

At higher energies, the long-lived X-ray emission of GRB150101B and its low gamma-ray energy release resemble the behavior of GRB170817A and its late-peaking afterglow. We fit both the structured jet and cocoon models to the GRB150101B afterglow. Despite the high number of free parameters, the tight constraints of the X-ray and optical upper limits allow us to draw conclusions about both models (Table 1).

In the cocoon-dominated scenario24,46,47, as the jet propagates through the merger ejecta, most of its energy is deposited into a hot cocoon, which then breaks out of the ejecta (while the jet is choked). The interaction of this mildly relativistic cocoon with the ambient medium produces a delayed afterglow. For GRB150101B, the early peak of the X-ray emission implies a wide-angle cocoon with negligible energy injection and significant velocity (Γ ~ 10), difficult to reconcile with full spherical ejecta. The high X-ray luminosity at peak (LX,pk ~5 × 1042 erg s−1) implies that a high energy budget (Ek,iso > 1052 erg) had to be transferred to the cocoon over a very short timescale ~0.01 s. This short duration of the gamma-ray emission is hard to explain within the cocoon model, as observational evidence48 suggests that the breakout should typically occur on longer timescales of ~0.2–0.5 s.

In the structured jet scenario8,12,14,49, the afterglow peak time tpk occurs when the central core of the jet decelerates sufficiently to come into view of the observer. It is a strong function of the viewing angle θv and, for θv < 0.7 rad, occurs before any significant spreading takes place. For a Gaussian structured jet tpk (θv–θc)2.5, where θc is the Gaussian width of the jet energy distribution. For GW170817, broadband afterglow modeling26 robustly constrains θv ~ 25° and θc ~ 4°. Since GRB150101B peaked ~10 times earlier than GW170817, it was likely seen at a smaller angle of θv–θc ~10° for similar explosion properties. This is consistent with its higher value of Eγ,iso and the short duration of its prompt gamma-ray phase. The peculiar properties of GRB150101B could therefore be due to the observer’s orientation and, if observed on-axis, the burst would appear as a canonical short duration GRB.

We show that this hypothesis leads to a self-consistent scenario. We consider the LX/Eγ,iso diagram (Fig. 2b). The post-peak X-ray afterglow is not significantly affected by the viewing angle, and mostly resembles the properties (luminosity and decay rate) of an equivalent on-axis explosion. Since the post-peak LX is roughly the same for on-axis and off-axis jets, the observed Eγ,iso can be used to probe the off-axis angle. In this particular case, the GRB would need an isotropic energy higher by a factor Eγ,on-axis/Eγ,obs ~50–500 for the observed LX/Eγ,iso ratio to fall within the 1 σ range of standard short bursts (shaded area in Fig. 2b). Indeed, this ratio would bring Eγ,on-axis within the typical range of Swift bursts (Fig. 1). For a Gaussian shaped jet, the relation θv/θc ~ (2 ln(Eγ,on-axis/Eγ,obs))1/2 must hold and implies a narrow core, θc ~ 3°–5°, similar to GRB170817A and within the range observed in other short GRBs50,51. By using the models developed in ref. 12, we find that the luminosity and peak time of the X-ray light curve can be reproduced by an explosion with Ek = 3 (−2, +3) x 1050 erg and θv = 13° (−5°, +7°) (Table 1). The jet model favors an environment of moderately low density, n = 0.070 (−0.069, +0.53) cm−3, typical for bright elliptical galaxies52. The interaction between such medium and the relatively high mass of sub-relativistic ejecta (>0.02 Msun) produced by the merger may give rise to a detectable radio signal on a timescale of a few years after the burst53.

We conclude that the overall properties of GRB150101B are naturally accounted for by a structured jet viewed off-axis. This implies that in the nearby (z < 0.2) Universe, where off-axis explosions are detectable by current gamma-ray facilities54, the true-to-observed ratio of short GRBs is much smaller than the beaming correction factor (300) of the uniform jet model51,55. Based on our model of a Gaussian jet, we show in Fig. 7 some predictions for X-ray searches of GW counterparts. Future counterparts of GW sources might span a wide range of behaviors at X-ray energies, depending on the observer’s orientation (in addition to the details of the explosion). For a fiducial distance of 100 Mpc, only a jet seen close to its axis (θ < 20°), like GRB150101B, could be detected by the Swift/XRT. Due to the significant contribution of the jet wings to the emission, these afterglows may not display a clear temporal variability for weeks after the merger and require a long-term monitoring in order to be identified as transients. Explosions seen at larger viewing angles, such as GW170817, show a clear rising afterglow but require the sensitivities of Chandra and, in future, the Athena X-ray Observatory will be able to uncover a wider range of orphan X-ray afterglows.

Fig. 7
figure 7

Predicted X-ray light curves of GW counterparts for different viewing angles. We assumed a set of standard afterglow parameters, reported in the top right corner, and a distance of 100 Mpc. The dashed lines mark the typical sensitivities of present (Swift, Chandra) and future (Athena) X-ray observatories


Gamma-ray data reduction

At 15:23:34.47 UT on 01 January 2015, GRB150101B triggered the Gamma-ray Burst Monitor (GBM) aboard NASA’s Fermi satellite and was later found in a refined analysis of the Swift Burst Alert Telescope (BAT) data. These data were downloaded from the public Swift ( and Fermi ( archives, and analyzed using the standard tools within the HEASoft (version 6.23) package and the public version of the RMFIT software ( Analysis of the untriggered INTEGRAL dataset also detects this event56.

As seen by BAT, the GRB has a duration T90 = 12 ± 1 ms in the 15–150 keV energy band. Search for emission on longer timescales did not detect any significant signal with a typical 3 σ upper limit of ~2.5 × 10−7 erg cm−2 s−1 (15–50 keV). Due to the faintness of the burst, the BAT spectrum was binned into 10 energy channels rather than the standard 80 channels. The spectrum in the range 15–150 keV can be described by a simple power-law model with photon index Γ = 1.2 ± 0.3 (χ2 = 12 for 8 d.o.f.) as well as a black body with kT = 17 ± 5 keV (χ2 = 9 for 8 d.o.f.). Other non-thermal models, such as a power-law with an exponential cutoff, a log-parabola or a Band function, yield comparably good descriptions of the spectrum but have a higher number of free parameters. Given the faintness of this event, these results should be taken with a grain of salt. The blackbody fit suggests the presence of a spectral curvature above ~100 keV, not captured by the simple power-law model. It is however not possible to distinguish between thermal and non-thermal emission based on this dataset.

A comparison of the BAT and GBM datasets (Fig. 1) shows that the start of the GRB emission is delayed by a few milliseconds in BAT. The early prompt phase appears to peak at energies >350 keV, above the BAT bandpass, and is therefore not detected by Swift. We therefore added this hard component of emission to our spectral analysis in order to estimate the total burst energetics. The GBM spectrum was extracted from the three NaI detectors with the highest signal-to-noise (NaI6, NaI7, and NaI8) and the relevant BGO1 detector. The time-averaged spectrum is well described by a power-law with an exponential cutoff (C-STAT = 276 for 274 d.o.f.). The observed fluence in the 10–1000 keV energy band is (1.0 ± 0.2) × 10−7 erg cm−2. At a redshift z = 0.1341, this corresponds to an isotropic-equivalent luminosity Lγ,iso = (2.7 ± 0.6) × 1050 erg s−1 and total gamma-ray energy Eγ,iso = (4.7 ± 0.9) × 1048 erg, calculated over the rest-frame 10–1000 keV band.

These results differ from the preliminary analysis reported through GRB Circular Notices. These differences could be attributed, in part, to the poor signal to noise of the standard BAT spectrum used in that analysis. Our derived value of Eγ,iso is lower than the value reported in ref. 23, which adopts an arbitrary k-correction factor of 5 to convert the fluence measured in the BAT bandpass to the 10–1000 keV range. In our case, such correction is not necessary as we measure the fluence over the broader energy bandpass. The fluence derived from the time-averaged spectral fit of the main burst is consistent with the value reported in ref. 39. Their catalog57,58 luminosities and energetics are instead calculated in a different energy range with a different methodology and cannot be directly compared to our values. The energetics for the entire sample of BAT short bursts with redshift are consistently derived from the time-averaged spectral properties following the same methodology used for GRB150101B.

X-ray data reduction

The data from the Chandra X-ray Telescope were reduced and analyzed in a standard fashion using CIAO v.4.9 and the latest calibration files. The afterglow counts were estimated from a circular aperture of 2-pixel radius in order to minimize the contamination from the nearby galaxy nucleus.

Spectra were fit within XSPEC with an absorbed power-law model by minimizing the Cash statistics. The final photometry is reported in Table 2. We used the tool psfsize_srcs to calculate that, within the selected source extraction region, the contamination of the central AGN is ~0.2% of its flux (~7 × 10−16 erg cm−2 s−1) and can be considered negligible in both epochs.

Table 2 Observations of GRB150101B. Upper limits are 3 σ

Swift XRT data were retrieved from the public repository ( Due to the larger point spread function (PSF) of the XRT, the two nearby sources resolved by Chandra are blended into a single source in the XRT images. Nonetheless these data can still be used to constrain the afterglow brightness. We focused on the first XRT observation at 1.5 d which resulted in a total of 115 source counts in a 9.9 ks exposure. We folded the AGN spectrum through the XRT response function in order to constrain the count rate of the central source. The XRT image was then modeled using two PSF-shaped sources at an offset fixed to the value measured with Chandra. This method allows us to place a 3 σ upper limit of 1.5 × 10−13 erg cm−2 s −1 on the afterglow flux at 1.5 d.

Ultraviolet optical and infrared data reduction

We analyzed the observations from the 4.3 m discovery channel telescope (DCT), the 8.1 m Gemini-South telescope, and the 8.2 m ESO’s very large telescope (VLT). The data were reduced within IRAF59 using standard tools and CCD reduction techniques (e.g., bias subtraction, flat-fielding, etc.). At later times, the location of the burst was imaged with the NASA/ESA hubble space telescope (HST) at two epochs, 40 days and 10 months after the burst. The later observation was used as a template for image subtraction. In each epoch, the optical F606W filter (0.6 μm) and the near-infrared F160W filter (1.6 μm) were used. Upper limits on the source flux were calculated by placing artificial sources of known magnitude at the transient location and recovering their fluxes through PSF-fitting on the subtracted image.

Observations with the ultraviolet and optica telescope (UVOT) aboard Swift were reduced and analyzed using HEASoft v6.23. Count-rates were estimated from a 5 arcsec aperture region and converted into magnitudes using the UVOT zero points60. The final photometry is reported in Table 2.

Host galaxy

We used the late-time HST images to model the surface brightness (SB) profile of the host galaxy using the procedure described in ref. 33. Stars in the vicinity of the galaxy were used to construct an empirical PSF used as input to GALFIT61 for the two-dimensional SB fitting. We tried several SB models, including a single Sèrsic profile, or a double Sèrsic profile (n = 4 for the bulge and n = 1 for the disk), with or without an additional point source at center. We find that the SB profile of the host galaxy is best fitted when the point source component is included in both bands. The need for the central point source component suggests that this galaxy harbors a low luminosity AGN with F606W ~20.8 AB mag, and F160W ~18.2 AB mag, taking up to 2% and 6% of the total light in each band, respectively.

Both the single and double Sèrsic fit results suggest that this is an early-type galaxy, with a Sèrsic index of n = 5.1 ± 1.0 (F606W) or n = 2.4 ± 1.0 and B/T ~ 0.7–0.8. Morphological appearance of this object also supports this result. The effective radius, reff is found to be 3.4 arcsec (or 8.1 kpc at z = 0.1341) to 3.9 arcsec (9.3 kpc) in F606W, and ~2 arcsec (6 kpc) in F160W. The position of GRB150101B was found to be 3 arcsec (~7.3 kpc) from the galaxy center, meaning that the GRB occurred around reff of the host galaxy.

The properties of the stellar population were constrained by modeling the galaxy spectral energy distribution. We excluded the AGN component assuming a composite AGN SED62,63 and normalizing the AGN flux at the value measured in the F160W filter. We fixed the redshift to 0.1341 and used the Chabrier initial mass function64. Two SED fitting procedures were tried, that of ref. 64 and the fitting and assessment of synthetic templates65 (FAST). Both fitting methods return consistent results (Fig. 8): a best-fit mean stellar age of 2 (+6, −1) Gyr, stellar mass of 1.0 (+1.0, −0.2) × 1011 Msun, and star formation rate SFR ~0.5 Msun yr−1.

Fig. 8
figure 8

Spectral energy distribution of the GRB host galaxy. The best fit model is shown by the solid line