Neutrino Rocket Jet Model: An Explanation of High-velocity Pulsars and their Spin-down Evolution

TL;DR

This paper proposes a neutrino rocket model explaining high pulsar velocities, their spin-down evolution, and observed alignments, by utilizing asymmetric neutrino emissions from superfluid vortex neutrons.

Contribution

It introduces a novel neutrino rocket mechanism that accounts for pulsar high velocities, spin-down behavior, and axis alignment, addressing longstanding astrophysical puzzles.

Findings

Maximum pulsar velocity exceeds 1000 km/s

Explains alignment of spin axis and motion in Crab and Vela pulsars

Correlates spin-down rate with pulsar period for P > 0.5s

Abstract

The fact that the spatial velocity of pulsars is generally higher than that of their progenitor stars has bothered astronomers for nearly 50 years. It has been extensively argued that the high pulsar velocity should be acquired during a natal kick process on a timescale of 100ms - 10s in the supernova explosion, in which some asymmetrical dynamical mechanism plays a key role. However, a satisfactory picture generally is still lacking. In this study, it is argued that the neutrino rocket model can well account for the high speed as well as the long-term evolution behaviors of pulsars. The neutrinos are emitted from superfluid vortex neutrons through the neutrino cyclotron radiation mechanism. The unique characters of left-handed neutrinos and right-handed antineutrinos resulting from the nonconservation of parity in weak interactions play a major role in the spatial asymmetry. The continuous acceleration of pulsars can be naturally explained by this model, which yields a maximum velocity surpassing 1000 km s$^{-1}$. The alignment between the spinning axis and the direction of motion observed for the Crab pulsar (PSR 0531) and the Vela pulsar (PSR 0833) can be well accounted for. The observed correlation between the spin-down rate and the period of long-period pulsars with $P \gtrsim 0.5$s can also be satisfactorily explained.