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Hubble Space Telescope non-detection of PSR J2144-3933: the coldest known neutron star

3 Pith papers cite this work. Polarity classification is still indexing.

3 Pith papers citing it
abstract

We report non-detections of the $\sim 3\times 10^8$ yr old, slow, isolated, rotation-powered pulsar PSR J2144$-$3933 in observations with the Hubble Space Telescope in one optical band (F475X) and two far-ultraviolet bands (F125LP and F140LP), yielding upper bounds $F_{\rm F475X}< 22.7$ nJy, $F_{\rm F125LP}< 5.9$ nJy, $F_{\rm F140LP}< 19.5$ nJy, at the pivot wavelengths 4940 \AA, 1438 \AA\ and 1528 \AA, respectively. Assuming a blackbody spectrum, we deduce a conservative upper bound on the surface (unredshifted) temperature of the pulsar of $T<42,000$ K. This makes PSR~J2144--3933 the coldest known neutron star, allowing us to study thermal evolution models of old neutron stars. This temperature is consistent with models with either direct or modified Urca reactions including rotochemical heating, and, considering frictional heating from the motion of neutron vortex lines, it puts an upper bound on the excess angular momentum in the neutron superfluid, $J<10^{44}\,\mathrm{erg\,s}$.

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hep-ph 3

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2026 3

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UNVERDICTED 3

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representative citing papers

Minimal Proton-Mass Dark Matter

hep-ph · 2026-06-18 · unverdicted · novelty 7.0

A minimal dark matter model with one complex scalar carrying B and L numbers, stabilized by proton stability, with mass near the proton mass and relic density from UV freeze-in.

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Showing 3 of 3 citing papers after filters.

  • Minimal Proton-Mass Dark Matter hep-ph · 2026-06-18 · unverdicted · none · ref 41 · internal anchor

    A minimal dark matter model with one complex scalar carrying B and L numbers, stabilized by proton stability, with mass near the proton mass and relic density from UV freeze-in.

  • Probing freeze-in dark matter using Bose-Einstein condensate in neutron star hep-ph · 2026-05-21 · unverdicted · none · ref 39 · internal anchor

    Bose-Einstein condensate formation in neutron stars enhances dark matter annihilation by 10^15-10^20, allowing freeze-in models to produce observable heating and probe neutrino-fog scattering cross-sections.

  • Constraining dark matter self-interaction from kinetic heating in neutron stars hep-ph · 2026-04-23 · unverdicted · none · ref 118

    Observation of neutron stars at 1000-1200 K could constrain asymmetric dark matter self-interaction cross-sections by two orders of magnitude beyond bullet cluster limits.