The impact of classical and General Relativistic obliquity precessions on the habitability of circumstellar neutron stars' planets
Abstract
Recently, it has been shown that rocky planets orbiting neutron stars can be habitable under non unrealistic circumstances. If a distant, pointlike source of visible light such as a Sun-like main sequence star or the gravitationally lensed accretion disk of a supermassive black hole is present as well, possible temporal variations p(t) of the planet's axial tilt p to the ecliptic plane should be included in the overall habitability budget since the obliquity determines the insolation at a given latitude on a body' s surface. I point out that, for rather generic initial spin-orbit initial configurations, general relativistic and classical spin variations induced by the post-Newtonian de Sitter and Lense-Thirring components of the field of the host neutron star and by its pull to the planetary oblateness J2p may induce huge and very fast variations of p which would likely have an impact on the habitability of such worlds. In particular, for a planet's distance of, say, 0.005\,au from a 1.4\,M neutron star corresponding to an orbital period Pb=0.109\,d, obliquity shifts p as large as maxp-pmin 50-100 over characteristic timescales as short as 10\,d (J2p) to 3\,Myr (Lense-Thirring) may occur for arbitrary orientations of the orbital and spin angular momenta L,\,Sns,\,Sp of the planet-neutron star system. In view of this feature of their spins, I dub such hypothetical planets as ``nethotrons".
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