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PSR J0337+1715
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PSR J0337+1715
PSR J0337+1715
Observation data
Epoch J2000.0      Equinox J2000.0
Constellation Taurus
Right ascension 03h 37m 43.82589s
Declination +17° 15′ 14.8280″
Characteristics
Spectral type Pulsar
Astrometry
Proper motion (μ) RA: 4.51 mas/yr
Dec.: 2.2 mas/yr
Parallax (π)0.770 mas
Distance4200 ly
Astrometry
Proper motion (μ) RA: 4.51 mas/yr
Dec.: 2.2 mas/yr
Orbit[1]
PrimaryPulsar
CompanionInner WD
Period (P)1.6293932 d
Semi-major axis (a)1.92379 lt-s [a]
Eccentricity (e)0.00069437
Inclination (i)39.263°
Orbit[2]
PrimaryPulsar-Inner WD pair
CompanionOuter WD
Period (P)327.25685 d
Semi-major axis (a)117.992 lt-s [b]
Eccentricity (e)0.03535596
Pulsar
Mass1.436 M
Rotation2.73258863244 ms
Age2.45 Gyr
Inner white dwarf
Mass0.1937 M
Outer white dwarf
Mass0.4069 M
Other designations
PSR J0337+1715
Database references
SIMBADdata

PSR J0337+1715 is a millisecond pulsar discovered in a Green Bank Telescope drift-scan survey from 2007. It is spinning 365.95 times per second (2.7325 milliseconds), 4,200 light years away in the constellation Taurus. It has a mass of just under 1.44 Solar masses. It is the first pulsar found in a stellar triple system. It is co-orbiting very closely with another star, a 0.2 solar-mass white dwarf, with a period of 1.6294 days. There is a second white dwarf further out (within one astronomical unit) which is orbiting both the pulsar and the inner white dwarf, and has an orbit with a period of 327.25 days, an eccentricity of 0.035, and a mass of 0.4 solar masses.[3][4] The fact that the pulsar is part of a triple system provides an opportunity to test the nature of gravity and the strong equivalence principle, with a sensitivity several orders of magnitude greater than before.[5][6][7]

Results were published in 2018 showing that if there is any departure from the equivalence principle it is no more than three parts per million[4][8][9] at 95% confidence level, improved to two parts per million in 2020.[10]

Planetary system

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In 2022 evidence for a small planet with a mass comparable to that of the Moon on a wide orbit was found.[11] In 2024, a study refined our knowledge of the planet's physical and orbital properties, finding that its mass is approximately 0.0041±0.003 M🜨, or about 30% that of the Moon, making it one of the least massive known objects outside the Solar System. Its orbital parameters have been more thoroughly established, showing that it is on a slightly eccentric orbit lasting 3,310 days (or just over 9 years) which is also severely inclined relative to the plane of the triple system's orbit, suggesting it may have arrived there via influence from a Kozai mechanism.[12]

Since PSR J0337+1715 (AB) b's orbit is relatively stable (for at least 100 million years), it may possibly be the last surviving member of a population of small objects which were formed after the progenitor of the pulsar in this system became a red supergiant, engulfing one of the two other stars and creating a common envelope between it and said star. The engulfed star was slowed down from the common envelope gas, transferring its orbital energy to that gas, causing it to expand and be expelled from the star, settling into a circumbinary disk where many small objects condensed from this gas. Of those, only PSR J0337+1715 (AB) b is still present, as all the others were on less stable orbits which likely got them ejected from the system or crashing into one of the stars.[12]

A 2025 study on the current pulsar planet candidates strongly suggests that PSR J0337+1715 (AB) b is not real, and is merely an artifact of "red noise", which is a product of variability within the pulsar in the system, and can manifest as quasiperiodic modulations in pulsar timing data, which can be falsely reported as planetary candidates.[13]

The PSR J0337+1715 planetary system
Companion
(in order from star)
Mass Semimajor axis
(AU)
Orbital period
(days)
Eccentricity Inclination Radius
b (unconfirmed) 0.0041 M🜨 5.52 3,310 days 0.257 119°

Notes

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References

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