<p>Binary millisecond pulsar systems are superb probes of stellar, binary evolution and the physics of extreme environments. The location of millisecond pulsars relative to the ‘spin-up line’ in the spin period and spin-down rate (<i>P</i>–<i>Ṗ</i>) diagram plays a critical role in understanding population studies of radio millisecond pulsars and accreting neutron stars in X-ray binaries. Here we report the discovery of the pulsar PSR J0435+3233, which exhibits an exceptionally high spin-down rate of 4.8775101(2) × 10<sup>−17 </sup>s s<sup>−1</sup>—two orders of magnitude higher than that of other known millisecond pulsars, thus occupying a distinctive position in the <i>P</i>–<i>Ṗ</i> diagram. This discovery implies a formation channel that differs from the classical evolutionary path, challenging the theoretical models of the recycling process and placing stringent constraints on spin-up theories. One plausible scenario is that its progenitor was a neutron star undergoing super-Eddington accretion, with the currently observed pulsar being a remnant of such a system. Another possible mechanism is its formation through the accretion-induced collapse of a magnetized ONeMg white dwarf, although this scenario requires specific theoretical assumptions. Hence, PSR J0435+3233 has an important impact on binary evolution theory.</p>

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Stringent tests of spin-up theories posed by a millisecond pulsar with an extreme spin-down rate

  • Qingdong Wu,
  • Na Wang,
  • Jianping Yuan,
  • Guoliang Lü,
  • Di Li,
  • Pei Wang,
  • Weiwei Zhu,
  • Richard N. Manchester,
  • Shuangqiang Wang,
  • Chenchen Miao,
  • Mengyao Xue,
  • Chunhua Zhu,
  • Dongxiang Shen,
  • Wenming Yan,
  • Zhigang Wen,
  • Kejia Lee,
  • Chengmin Zhang,
  • Jumei Yao,
  • Rai Yuen,
  • Jingbo Wang,
  • De Zhao,
  • Feifei Kou,
  • Shengnan Sun,
  • Jiarui Niu

摘要

Binary millisecond pulsar systems are superb probes of stellar, binary evolution and the physics of extreme environments. The location of millisecond pulsars relative to the ‘spin-up line’ in the spin period and spin-down rate (P) diagram plays a critical role in understanding population studies of radio millisecond pulsars and accreting neutron stars in X-ray binaries. Here we report the discovery of the pulsar PSR J0435+3233, which exhibits an exceptionally high spin-down rate of 4.8775101(2) × 10−17 s s−1—two orders of magnitude higher than that of other known millisecond pulsars, thus occupying a distinctive position in the P diagram. This discovery implies a formation channel that differs from the classical evolutionary path, challenging the theoretical models of the recycling process and placing stringent constraints on spin-up theories. One plausible scenario is that its progenitor was a neutron star undergoing super-Eddington accretion, with the currently observed pulsar being a remnant of such a system. Another possible mechanism is its formation through the accretion-induced collapse of a magnetized ONeMg white dwarf, although this scenario requires specific theoretical assumptions. Hence, PSR J0435+3233 has an important impact on binary evolution theory.