Pulsar planet
A pulsar planet is an exoplanet that orbits a pulsar, a highly magnetized, rapidly rotating neutron star that emits periodic pulses of electromagnetic radiation due to its beaming magnetic field.[1] These planets exist in extreme environments characterized by intense radiation, strong magnetic fields, and relativistic particle winds, making their survival and detection particularly challenging.[2] The first pulsar planets were discovered in 1992 orbiting the millisecond pulsar PSR B1257+12, approximately 2,300 light-years away in the constellation Virgo, by astronomers Aleksander Wolszczan and Dale Frail using precise pulsar timing observations with the Arecibo Observatory.[1] This groundbreaking detection, involving two Earth-mass planets initially, was confirmed in 1994 with the identification of a third inner planet, establishing PSR B1257+12 as the first confirmed multi-planet extrasolar system.[3] The planets in this system—named Draugr (PSR B1257+12 b), Poltergeist (PSR B1257+12 c), and Phobetor (PSR B1257+12 d)—have minimum masses of approximately 0.02, 4.3, and 3.9 Earth masses, respectively, and orbit with periods of 25.3, 66.5, and 98.2 days in a 4:2:3 mean-motion resonance.[3] Pulsar planets are primarily detected via pulsar timing arrays, which measure tiny deviations in pulse arrival times induced by the planets' gravitational tugs on the pulsar.[2] As of 2025, only eight such planets have been confirmed across six pulsar systems, underscoring their scarcity compared to the thousands of exoplanets orbiting main-sequence stars.[2] Notable additional systems include the Jupiter-mass planet PSR B1620-26 b, orbiting a pulsar-white dwarf binary in the globular cluster M4 about 7,200 light-years away, discovered through timing in 1999 and estimated to be over 12 billion years old.[4] Other confirmed planets, such as the super-Jupiter PSR J1719-1438 b with a 2.18-hour orbital period and PSR J2322-2650 b on a 7.75-hour orbit, further illustrate the diversity of these worlds, ranging from terrestrial-like masses to gas giants.[5][2]Discovery
Initial Detection
The first pulsar planet system was discovered in 1992 around the millisecond pulsar PSR B1257+12 by astronomers Aleksander Wolszczan and Dale Frail, who utilized radio pulsar timing observations conducted with the Arecibo Observatory's 305-m telescope.[1] This technique measures the arrival times of pulsar radio pulses to detect periodic perturbations caused by orbiting companions.[6] The initial analysis revealed two Earth-mass planets, later designated PSR B1257+12 c and d, with minimum masses of approximately 4.3 M⊕ and 3.9 M⊕ (where M⊕ denotes Earth mass), and orbital periods of 66.5 days and 98.2 days, respectively.[7] A third, lower-mass companion, PSR B1257+12 b, with a minimum mass of about 0.02 M⊕ and an orbital period of 25.3 days, was evidenced but not fully resolved in the 1992 data.[7] These findings were announced in a paper published in Nature on January 9, 1992.[1] The discovery faced significant initial skepticism within the astronomical community, as planets were deemed unlikely to survive the supernova explosion that formed the neutron star host. Verification came through extended timing observations spanning multiple orbital periods, which confirmed the gravitational perturbations and ruled out alternative explanations such as astrophysical noise or instrumental effects.[3] By 1994, a dedicated study fully confirmed all three companions, solidifying PSR B1257+12 as the first verified planetary system beyond our Solar System and demonstrating that pulsars could host stable planetary orbits.[8]Subsequent Confirmations
Following the groundbreaking 1992 detection of planets around PSR B1257+12, subsequent confirmations of pulsar planets have been sparse, relying primarily on high-precision pulsar timing observations that detect periodic perturbations in pulse arrival times caused by orbiting companions. These efforts, conducted through international collaborations using facilities such as the Arecibo Observatory, Green Bank Telescope (part of the NANOGrav collaboration), Parkes Observatory, and Effelsberg Telescope, have gradually built a catalog of confirmed systems, highlighting the rarity of these extreme environments. By 2025, a comprehensive review identified eight confirmed planets across six pulsars, updating earlier counts that recognized only five systems prior to 2022 and underscoring the challenges in distinguishing true planets from disrupted stellar remnants in pulsar binaries.[2] The first post-1992 confirmation came in 2003 with PSR B1620−26 b, a super-Jupiter-mass planet in a circumbinary orbit around the pulsar and its white dwarf companion within the globular cluster M4. This discovery, refined through long-term timing observations at Arecibo and other telescopes, revealed a companion with a mass of 2.5 Jupiter masses and an orbital period of 36,500 days, interpreted as a captured planet surviving in the cluster's dense environment.[4][2] Advancing to 2011, PSR J1719−1438 b was confirmed via pulsar timing analysis from the High Time Resolution Universe survey, using the Parkes Telescope. This Jupiter-mass object, with a mass of 1.2 Jupiter masses and an ultrashort orbital period of 2.18 hours, prompted the "diamond planet" hypothesis due to its high density suggesting a carbon-dominated composition from an eroded low-mass star.[2] In 2012, observations of PSR J1311−3430, a millisecond pulsar detected in Fermi gamma-ray data, confirmed a planetary-mass companion through combined radio timing and optical photometry at multiple observatories, including the Very Large Telescope. The companion has a mass of 8.6 Jupiter masses and an orbital period of 93.8 minutes, characteristic of an eclipsing binary black widow system where the pulsar ablates its low-mass partner.[2] Further confirmations emerged in 2018 with two systems identified via the High Time Resolution Universe survey and follow-up timing at Green Bank and Jodrell Bank telescopes. PSR J2322−2650 b, a 0.8 Jupiter-mass planet with a 7.75-hour orbital period, was detected as a low-luminosity millisecond pulsar's companion, potentially also carbon-rich.[9][2] Similarly, PSR J0636+5128's companion, confirmed through X-ray and optical studies alongside radio timing, has a mass of 7.2 Jupiter masses and a 95.8-minute period, overlapping with black widow dynamics in this compact binary.[10][2] These discoveries, spanning from 2003 to 2018, were enabled by pulsar timing arrays that achieve microsecond precision, allowing detection of companions down to Earth masses, and reflect collaborative efforts across global radio astronomy networks to resolve ambiguities in earlier candidate signals. The 2025 analysis solidified this tally of eight planets, emphasizing that while pulsar planets remain exceptional, their confirmed existence challenges models of planetary survival near neutron stars.[2]Characteristics
Orbital and Physical Properties
Pulsar planets exhibit a wide range of masses, spanning from sub-terrestrial to super-Jovian scales. The lowest-mass confirmed example is the innermost planet in the PSR B1257+12 system, with a mass of approximately 0.02 Earth masses (M⊕), determined through pulsar timing analysis that accounts for orbital inclinations around 53 degrees.[11] In contrast, higher-mass companions approach or exceed Jovian sizes, such as the ~12 Jupiter mass (M_J) object orbiting PSR J1311−3430, inferred from optical and radio observations of the black widow binary system.[12] This mass range highlights the diversity in pulsar planetary systems, with lower-mass bodies typically classified as terrestrial and higher-mass ones as gaseous giants.[2] Orbital periods among confirmed pulsar planets vary dramatically, from ultrashort durations in tight binaries to extended circumbinary orbits lasting nearly a century. For instance, the planet around PSR J1719−1438 completes an orbit in just 0.09 days at a separation of ~0.004 astronomical units (AU), as measured by pulse arrival time variations. At the other extreme, the 2.5 M_J planet in the PSR B1620−26 system has an orbital period of approximately 100 years and a semi-major axis of 23 AU, consistent with a stable, hierarchical triple configuration involving the pulsar and a white dwarf companion. These periods reflect the dynamical environments, with close-in orbits often resulting from post-supernova accretion or capture processes. Compositions of pulsar planets are inferred from mass and density estimates, revealing a divide between rocky interiors for low-mass objects and hydrogen-helium envelopes for more massive ones. The planet in PSR J1719−1438, with a minimum mass of ~1.2 M_J but a radius constrained to ~40% of Jupiter's (assuming high density), is thought to be carbon-dominated and possibly crystallized, resembling a compact Jupiter-mass object with a diamond-like structure due to its progenitor white dwarf's composition.[13] Similarly, the terrestrial planets in PSR B1257+12, with masses of 0.02 M⊕, 4.3 M⊕, and 3.9 M⊕, are modeled as rocky bodies based on their densities comparable to Earth's.[11] Higher-mass examples, like the ~2.5 M_J planet in PSR B1620−26, likely retain gaseous envelopes akin to Jupiter. Orbital eccentricities and inclinations are derived primarily from long-term pulsar timing residuals, indicating generally stable, low-eccentricity configurations in well-studied systems. In PSR B1257+12, the planets orbit with eccentricities near zero (e ≈ 0 for the innermost, e ≈ 0.02 for the outer two) and an inclination of ~53 degrees relative to the line of sight, suggesting coplanar, circular orbits stabilized by mutual resonances.[11] The PSR B1620−26 planet also resides in a near-circular orbit (e < 0.16), with an inclination of ~55 degrees, supporting its long-term survival in the globular cluster environment. These parameters underscore the resilience of pulsar planets against perturbations from the host neutron star's formation. Planetary sizes are not directly measured but inferred from masses and assumed bulk densities, yielding radii from sub-Earth to Jupiter scales. For the terrestrial PSR B1257+12 planets, radii range from ~0.3 R⊕ for the innermost to ~1–2 R⊕ for the outer two, based on rocky composition models.[14] Jovian-mass planets like that around PSR J1311−3430 are estimated to have radii ~1 R_J, while the dense PSR J1719−1438 companion implies a compact size of ~0.4 R_J. These inferences provide key context for understanding post-supernova planetary architectures.Environments and Radiation Effects
Pulsar planets endure extreme radiation environments originating from the magnetosphere of their host neutron stars, where accelerated charged particles produce intense beams of gamma-ray and X-ray emission. These fluxes can reach up to $10^{12} erg cm^{-2} s^{-1} for planets in close orbits, driven primarily by the pulsar's spin-down luminosity channeled into relativistic outflows. Such radiation levels dwarf those incident on planets around main-sequence stars, leading to pervasive ionization and potential photochemical processing of any residual atmospheres. For the planets orbiting PSR B1257+12, this constant bombardment from the pulsar's core manifests as a harsh radiative flux that permeates the system.[14] Relativistic particle winds, composed of electron-positron pairs ejected at velocities approaching 0.1c, further degrade planetary atmospheres through dynamic pressure and sputtering. Mass loss from atmospheric ablation follows a ram-pressure scaling, approximated as \frac{dm}{dt} \propto \rho v_{\rm wind}^2, where \rho denotes atmospheric density and v_{\rm wind} the wind speed; this process efficiently strips volatiles, particularly for low-mass atmospheres in sub-Alfvénic wind regimes lacking protective bow shocks. In systems like PSR B1257+12, the magnetized wind couples directly to planetary surfaces via Joule dissipation, with energy capture rates on the order of $10^{18} W for inner planets, potentially altering orbital dynamics over millions of years.[15] Pulsar magnetic fields, spanning $10^8 to $10^{12} G depending on the neutron star's age and type, amplify these hazards by channeling particles and inducing electromagnetic interactions with planetary material. Millisecond pulsars hosting planets, like those in PSR B1257+12, typically exhibit fields around $10^8 G, sufficient to generate auroral precipitation of charged particles onto planetary nightsides, illuminating them with Earth-like but far more energetic displays. Stronger fields in younger systems can strip volatiles through magnetic drag, enhancing ablation efficiency.[16][17] Illustrative cases highlight these effects: PSR J1719−1438 b, a dense Jupiter-mass object, likely retains a carbon-dominated composition exposed by ablation of lighter elements under pulsar irradiation and wind, with evaporation timescales exceeding $10^6 years due to its high refractive index minimizing absorption. In black widow systems, such as PSR B1957+20, the pulsar's wind drives evaporative mass loss from low-mass companions at rates that can reduce their mass by factors of 10 over hundreds of millions of years, ionizing and dispersing material into intrabinary shocks.[18][19][20] Thermal contrasts define another facet, with tidally locked pulsar planets exhibiting dayside temperatures elevated to thousands of Kelvin from direct magnetospheric heating, while nightsides cool via radiation to hundreds of Kelvin. Observations of PSR J2322−2650 b reveal dayside brightness temperatures around 2000–2300 K, contrasting sharply with nightside values near 900 K, underscoring the role of atmospheric circulation—or its absence—in redistributing heat. Orbital proximity intensifies these gradients, as closer paths increase irradiation asymmetry.[21]Formation
Proposed Mechanisms
The formation of planets around pulsars is theorized to occur through several distinct mechanisms, primarily due to the extreme conditions following a supernova explosion that creates the neutron star. These processes differ markedly from standard protoplanetary disk formation around main-sequence stars, as the supernova disrupts any pre-existing planetary system.[22] One prominent mechanism is second-generation planet formation, where planets reform from a fallback disk of material ejected during the supernova but recaptured by the neutron star's gravity. This disk, composed of supernova ejecta and potentially enriched with heavy elements, can condense into solid bodies through processes akin to those in solar system formation, though on shorter timescales due to the compact environment. Theoretical models suggest that such disks form rapidly post-explosion, with masses sufficient to produce terrestrial-sized planets if the fallback is efficient.[23] Another proposed pathway involves the disruption and recapture of material from a companion star or pre-existing planet during the supernova. In this scenario, the asymmetric explosion ablates or shreds the companion, scattering fragments that are partially recaptured into a circumstellar disk around the pulsar, from which planets accrete. For instance, in systems like PSR B1620−26, dynamical interactions may lead to the recapture of planetary-mass objects from a disrupted companion, forming a circumbinary planet. This mechanism is particularly relevant for binary pulsars, where the companion's mass loss provides the raw material. Primordial survival represents a rarer possibility, in which planets from the progenitor star's system endure the supernova without ejection. For this to occur, planets must orbit at distances close enough to resist the natal kick velocity of the neutron star (typically 100–500 km/s), avoiding disruption by the expanding shockwave. However, simulations indicate survival probabilities below 1% for most configurations, making this mechanism unlikely except in highly asymmetric or low-kick supernovae.[22][24] In dense environments like globular clusters, hierarchical triple disruptions offer an additional formation channel, as seen in PSR B1620−26. Here, close encounters between the pulsar binary and a pre-existing star-planet pair lead to dynamical exchange, capturing the planet into a wide orbit around the pulsar-white dwarf binary. Scattering experiments show that such interactions are feasible in cluster cores, with the planet's survival depending on the encounter geometry and velocities.[25][26] Supporting evidence for these post-supernova formation processes comes from the PSR B1257+12 system, where the planets exhibit compositions indicative of supernova enrichment. Models of white dwarf-neutron star mergers, a variant of the disruption mechanism, predict carbon-oxygen disks that form carbon-rich planets, potentially with diamond interiors.[27]Survival and Evolutionary Implications
The survival of planets during the supernova explosion that forms a pulsar requires specific conditions to counteract the natal kick imparted to the neutron star. Asymmetric supernova explosions typically impart kick velocities of 100–500 km/s to the nascent pulsar, which can disrupt planetary orbits unless the planets are sufficiently distant or the kick is aligned favorably. For planets orbiting at distances greater than approximately 1 AU, the orbital velocity can exceed the radial component of the kick, increasing the likelihood of retention, with survival probabilities estimated at around 1–10% for such configurations in single systems. In binary systems, the kick can be diluted by the companion star's mass, enhancing survivability for circum-binary planets, often resulting in highly eccentric orbits (e > 0.9) post-explosion.[28][29][30] Post-supernova, pulsar planets undergo evolutionary changes influenced by tidal interactions and, in binary systems, gravitational wave emission. Tidal forces from the compact neutron star can lead to locking of the planet's rotation, though this process may be inefficient for highly irradiated or ablating bodies. In close binary pulsar systems, the orbital period of the pulsar-companion pair decays due to gravitational radiation, with observed rates such as dP/dt ≈ -2.4 × 10^{-12} s/s in the Hulse-Taylor binary (PSR B1913+16), potentially perturbing associated planetary orbits over gigayears. Fallback accretion from supernova ejecta plays a key role in rebuilding planetary material, where a disk of ~0.1 M_⊙ forms around the neutron star and supplies rocky cores through episodic accretion phases, enabling second-generation planet formation.[31][32] The existence of pulsar planets challenges conventional planetary formation models, which rely on protoplanetary disks around main-sequence stars, as massive progenitors have short lifetimes and intense radiation that preclude standard accretion. Instead, these systems suggest resilient second-generation formation pathways, such as from disrupted companions or fallback disks, with implications for the prevalence of planets if debris disks are commonly detected around young pulsars. Overlap with black widow and redback systems highlights planets as potential ablated remnants, where low-mass companions (M < 0.05 M_⊙, akin to super-Jupiters or brown dwarfs) are gradually evaporated by pulsar irradiation, leaving planetary-mass objects in short-period orbits. Potential planetary-mass remnants in such systems, like the ablated companion in PSR B1957+20, underscore this evolutionary link.[28]Observability
Detection Techniques
Pulsar timing is the primary and most successful technique for detecting planets orbiting pulsars, leveraging the extraordinary rotational stability of these neutron stars, which emit regular radio pulses acting as cosmic clocks. Astronomers monitor the times of arrival (TOAs) of these pulses over months to years, identifying periodic residuals—deviations from the expected arrival times—caused by the gravitational influence of orbiting planets on the pulsar's motion around the system's center of mass. These residuals are modeled using Keplerian orbital parameters, where the relationship between orbital period P, semi-major axis a, and masses follows Kepler's third law adapted for the system: P^2 \propto a^3 / (M_p + M_\star), with M_p the planet mass and M_\star the pulsar mass. This method enables determination of orbital periods, eccentricities, and minimum planet masses (m \sin i), as demonstrated in the seminal discovery of two Earth-mass planets around the millisecond pulsar PSR B1257+12.[1][33] For planets in close orbits, radial velocity measurements via Doppler shifts in the pulse profiles offer a complementary approach, particularly when timing precision alone is insufficient. The pulsar's orbital motion induces line-of-sight velocity changes that broaden or shift the observed pulse spectrum, allowing inference of the planet's gravitational pull despite the challenges posed by the pulsar's rapid rotation, which inherently widens pulse profiles. This technique is most viable for short-period systems where the velocity amplitude is larger, though it requires high-resolution spectroscopy and is less commonly applied than timing due to signal dilution in radio observations.[34] In binary pulsar systems, eclipse timing variations provide another detection avenue, where perturbations from an additional planet alter the timing of eclipses between the pulsar and its stellar companion. Periodic deviations in eclipse mid-times reveal the planet's orbital influence, analogous to transit timing variations in optical binaries, and have been explored for systems like PSR J1311−3430, though primarily for confirming low-mass companions rather than isolated planets. Multi-wavelength observations in X-ray and ultraviolet bands can indirectly support detections by identifying ablation signatures, such as ionized outflows or enhanced emission from planetary atmospheres eroded by the pulsar's intense radiation, offering constraints on planet locations and compositions.[34][35] The sensitivity of these methods, especially pulsar timing on millisecond pulsars, reaches minimum detectable planet masses of m \sin i \sim 10^{-7} M_\odot or lower (as small as ~0.01 Earth masses in optimal cases for orbital periods of tens to hundreds of days), far surpassing radial velocity sensitivities for Sun-like stars.[33][36]Observational Challenges
Observing pulsar planets presents significant hurdles primarily due to the intrinsic properties of pulsars and the interstellar environment, which introduce noise and biases that obscure subtle planetary signals. The primary detection method relies on high-precision pulsar timing, where orbital perturbations from planets manifest as small deviations in pulse arrival times; however, various sources of timing noise and geometric constraints limit the sensitivity and scope of these observations.[16] One major challenge arises from timing noise induced by the interstellar medium (ISM), particularly through dispersion and multipath propagation. Dispersion occurs as free electrons in the ISM delay radio pulses in a frequency-dependent manner, with the delay proportional to ν⁻², where ν is the observing frequency; this effect, quantified by the dispersion measure (DM = ∫ n_e dl), can smear pulses and degrade timing precision unless corrected via multi-frequency observations.[16] Multipath propagation, caused by ISM inhomogeneities, leads to scattering that broadens pulses (scaling as ν⁻⁴) and introduces variable delays, further contaminating timing residuals and mimicking or masking planetary signals.[16] To distinguish these effects from planetary perturbations, observations require long temporal baselines spanning years or even decades, as seen in pulsar timing arrays that achieve the necessary stability to model ISM variations.[16] The low mass ratio between planets and their host pulsars exacerbates detection difficulties, as planetary gravitational perturbations induce extremely small changes in pulse arrival times, typically on the order of microseconds (Δt ~ μs).[37] For a typical pulsar mass of ~1.35 M_⊙, these perturbations scale with the planet's mass and orbital parameters, necessitating timing precision at the level of 1 μs or better to detect Earth-mass planets, which demands stable, high-sensitivity radio telescopes and long-term monitoring.[16][37] Pulsar beam geometry imposes additional limitations, as the narrow, lighthouse-like radio beams emitted from the neutron star's magnetosphere sweep across the observer's line of sight only periodically.[16] Planets located outside this narrow beam are invisible to direct radio emission observations, relying solely on indirect detection through timing perturbations in the pulsar's signal, which further restricts the parameter space for discoveries.[16] Timing signals can also be contaminated by intrinsic pulsar phenomena, such as glitches or binary companion motion. Glitches—sudden spin-ups in the pulsar's rotation frequency (Δν/ν ~ 10^{-11} to 10^{-5})—produce step-like residuals or quasi-periodic variations that can mimic the orbital signatures of planets, particularly in pulsars exhibiting frequent events like the Vela pulsar.[38] In binary systems, unmodeled orbital motion of the pulsar itself introduces delays that overlap with planetary signals, requiring precise modeling to avoid false positives or missed detections.[37] The overall rarity of pulsar planets compounds these technical challenges, with surveys indicating that fewer than 0.5% of pulsars host Earth-sized or larger planets.[39] Among the more than 700 known millisecond pulsars (MSPs), fewer than 1% show confirmed planetary companions as of 2025, reflecting a strong selection bias toward these stable, rapidly rotating objects that are easier to time precisely compared to young, erratic pulsars.[22][2] Comprehensive searches, such as the 2015 survey of 151 young pulsars, have yielded no detections, and recent surveys like those from FAST continue to confirm the low occurrence rate without additional planetary discoveries, underscoring how formation biases and observational preferences for MSPs limit the sample size and introduce incompleteness.[22][40]Occurrence
Confirmed Systems
The confirmed pulsar planets comprise eight bodies distributed across six systems, highlighting their extreme rarity with an occurrence rate below 0.5% among observed pulsars.[2] These detections, primarily via pulsar timing and eclipsing variability, reveal a predominance of giant planets, except in the pioneering PSR B1257+12 system, and underscore challenges to standard planet formation models in high-radiation environments.[2] A 2025 analysis validated this tally as the "Rule of Six," confirming no additional systems despite extensive surveys.[2] The PSR B1257+12 system, orbiting a millisecond pulsar approximately 2,300 light-years away, hosts the first discovered extrasolar planets and the only confirmed multi-planet pulsar arrangement.[1] It includes three low-mass terrestrial planets: PSR B1257+12 b (0.02 M⊕, orbital period 25.3 days), PSR B1257+12 c (4.3 M⊕, 66.5 days), and PSR B1257+12 d (3.9 M⊕, 98.2 days), detected through precise timing residuals from the pulsar's 6.2 ms rotation.[1] These planets maintain long-term stability in a 4:2:3 mean-motion resonance, demonstrating dynamical equilibrium despite the pulsar's intense radiation. Discovered in 1992, this system revolutionized exoplanet science by proving planets could survive supernova events.[1] PSR B1620−26 b orbits a binary pulsar-white dwarf pair in the globular cluster M4, about 12,400 light-years distant, marking the first circumbinary pulsar planet. With a mass of 2.5 M_J and an orbital period of roughly 100 years (36,500 days), it likely formed through dynamical capture or exchange interactions in the dense cluster environment, rather than in situ accretion. Confirmed in 2003 via pulsar timing perturbations influenced by both the pulsar and white dwarf, this Jupiter-mass world illustrates planet formation in extreme stellar densities. PSR J1719−1438 b, a 1.2 M_J planet, circles a 5.7 ms millisecond pulsar in an ultra-compact orbit of 2.18 hours, the shortest known for any pulsar planet. Detected in 2011 through radio timing observations with the Parkes telescope, its minimum mass suggests it may be the remnant core of a low-mass white dwarf eroded by the pulsar's energetic wind and radiation. This system, located about 3,900 light-years away, exemplifies post-supernova planetary evolution under ablation. PSR J2322−2650 b is a low-mass giant planet (0.8 M_J) in a 7.75-hour eclipsing orbit around a faint millisecond pulsar.[9] Discovered in 2018 as part of the High Time Resolution Universe survey, its detection relied on radio eclipse modeling, revealing a bloated companion likely heated by the pulsar's emission.[9] Positioned roughly 750 light-years away, this system provides insights into the lower mass limit for giant planets in binary evolution.[9] In the black widow system PSR J0636+5128, a 7.2 M_J companion orbits the 2.87 ms pulsar every 95.8 minutes, with evidence of high irradiation causing orbital eccentricity and heating.[41] Confirmed in 2018 through multi-wavelength photometry and timing from archival Gemini and Keck data, the companion's low density indicates ongoing mass loss from pulsar wind ablation.[41] This system (∼2,300 light-years away) highlights extreme tidal interactions in compact binaries.[41] PSR J1311−3430 features an 8.6 M_J planet in a 93.8-minute orbit around a fast-spinning 1.4 ms gamma-ray pulsar, exhibiting the deepest radio eclipse among black widows due to its low-inclination, irradiated companion.[42] Initially detected in 2012 via Fermi Large Area Telescope blind searches and confirmed through spectroscopy in 2015, the system's parameters suggest a helium-dominated world ablated to planetary mass.[42] Located about 9,800 light-years away, it probes the boundary between planetary and stellar remnants.[42]| System | Planet(s) | Mass(es) | Orbital Period(s) | Discovery Year | Key Notes |
|---|---|---|---|---|---|
| PSR B1257+12 | b, c, d | 0.02, 4.3, 3.9 M⊕ | 25.3, 66.5, 98.2 d | 1992 | Multi-planet; resonant stability |
| PSR B1620−26 | b | 2.5 M_J | 36,500 d | 2003 | Circumbinary in globular cluster |
| PSR J1719−1438 | b | 1.2 M_J | 2.18 h | 2011 | Evaporated WD remnant candidate |
| PSR J2322−2650 | b | 0.8 M_J | 7.75 h | 2018 | Eclipsing; low-mass giant |
| PSR J0636+5128 | b | 7.2 M_J | 95.8 min | 2018 | Black widow; heated, eccentric |
| PSR J1311−3430 | b | 8.6 M_J | 93.8 min | 2012 | Deepest eclipse; fast spinner |