Pulsars are the most stable macroscopic clocks found in nature. Spinning with periods as short as a few milliseconds, their stability can supersede that of the best atomic clocks on Earth over timescales of a few years. Stable clocks are synonymous with precise measurements, which is why pulsars play a role of paramount importance in testing fundamental physics. As a pulsar rotates, the radio beam emitted along its magnetic axis appears to us as pulses because of the lighthouse effect. Thanks to the extreme regularity of the emitted pulses, minuscule disturbances leave particular fingerprints in the times-of-arrival (TOAs) measured on Earth with the technique of pulsar timing. Tiny deviations from the expected TOAs, predicted according to a theoretical timing model based on known physics, can therefore reveal a plethora of interesting new physical effects. Pulsar timing can be used to measure the dynamics of pulsars in compact binaries, thus probing the post-Newtonian expansion of general relativity beyond the weak field regime, while offering unique possibilities of constraining alternative theories of gravity. Additionally, the correlation of TOAs from an ensemble of millisecond pulsars can be exploited to detect low-frequency gravitational waves of astrophysical and cosmological origins. We present a comprehensive review of the many applications of pulsar timing as a probe of gravity, describing in detail the general principles, current applications and results, as well as future prospects.

Perrodin, D., Sesana, A. (2017). Radio pulsars: Testing gravity and detecting gravitational waves. In L. Rezzolla, P. Pizzochero, D.I. Jones, N. Rea, I. Vidana (a cura di), The Physics and Astrophysics of Neutron Stars (pp. 95-148). Springer International Publishing [10.1007/978-3-319-97616-7_3].

Radio pulsars: Testing gravity and detecting gravitational waves

Sesana, A
2017

Abstract

Pulsars are the most stable macroscopic clocks found in nature. Spinning with periods as short as a few milliseconds, their stability can supersede that of the best atomic clocks on Earth over timescales of a few years. Stable clocks are synonymous with precise measurements, which is why pulsars play a role of paramount importance in testing fundamental physics. As a pulsar rotates, the radio beam emitted along its magnetic axis appears to us as pulses because of the lighthouse effect. Thanks to the extreme regularity of the emitted pulses, minuscule disturbances leave particular fingerprints in the times-of-arrival (TOAs) measured on Earth with the technique of pulsar timing. Tiny deviations from the expected TOAs, predicted according to a theoretical timing model based on known physics, can therefore reveal a plethora of interesting new physical effects. Pulsar timing can be used to measure the dynamics of pulsars in compact binaries, thus probing the post-Newtonian expansion of general relativity beyond the weak field regime, while offering unique possibilities of constraining alternative theories of gravity. Additionally, the correlation of TOAs from an ensemble of millisecond pulsars can be exploited to detect low-frequency gravitational waves of astrophysical and cosmological origins. We present a comprehensive review of the many applications of pulsar timing as a probe of gravity, describing in detail the general principles, current applications and results, as well as future prospects.
Capitolo o saggio
pulsars, gravitational waves, black holes, general relativity
English
The Physics and Astrophysics of Neutron Stars
Rezzolla, L; Pizzochero, P; Jones, DI; Rea, N; Vidana, I
2017
978-3-319-97615-0
457
Springer International Publishing
95
148
Perrodin, D., Sesana, A. (2017). Radio pulsars: Testing gravity and detecting gravitational waves. In L. Rezzolla, P. Pizzochero, D.I. Jones, N. Rea, I. Vidana (a cura di), The Physics and Astrophysics of Neutron Stars (pp. 95-148). Springer International Publishing [10.1007/978-3-319-97616-7_3].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/290701
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