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Low braking index of PSR J1734-3333: an interaction between fall-back disc and magnetic field? (2015)

Chen, W.-C., Li, X.-D.

Oxford University Press

In: Monthly Notices of the Royal Astronomical Society / Letters

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Publication Date: 2015-11-06

Description: Recent timing observation reported that the radio pulsar PSR J1734–3333 with a rotating period P = 1.17 s is slowing down with a period derivative $\dot{P}=2.28\times 10^{-12}\ \rm s\,s^{-1}$ . Its derived braking index n = 0.9 ± 0.2 is the lowest value among young radio pulsars with the measured braking indices. In this Letter, we attempt to investigate the influence of the braking torque caused by the interaction between the fall-back disc and the strong magnetic field of the pulsar on the spin evolution of PSR J1734–3333. Analytical result show that this braking torque is obviously far more than that by magnetic dipole radiation for pulsars with spin period of 〉0.1 s, and play an important role during the spin-down of the pulsars. Our simulated results indicate that, for some typical neutron star parameters, the braking index and the period derivative approximately in agreement with the measured value of PSR J1734–3333 if the material inflow rate in the fall-back disc is 2 x 10 17 g s – 1 . In addition, our scenario can account for the measured braking indices of four young pulsars. However, our predicted X-ray luminosity are one to two order of magnitude higher than the observation. We proposed that this discrepancy may originate from the instability of fall-back disc.

Print ISSN: 1745-3925

Electronic ISSN: 1745-3933

Topics: Physics

Published by Oxford University Press

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The cosmic web through the lens of graph entropy (2020)

García-Alvarado, M V ; Li, X-D ; Forero-Romero, J E

Oxford University Press

In: Monthly Notices of the Royal Astronomical Society / Letters. 2020; 498(1): L145-L149. Published 2020 Aug 20. doi: 10.1093/mnrasl/slaa145.

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Publication Date: 2020-08-20

Description: We explore the information theory entropy of a graph as a scalar to quantify the cosmic web. We find entropy values in the range between 1.5 and 3.2 bits. We argue that this entropy can be used as a discrete analogue of scalars used to quantify the connectivity in continuous density fields. After showing that the entropy clearly distinguishes between clustred and random points, we use simulations to gauge the influence of survey geometry, cosmic variance, redshift space distortions, redshift evolution, cosmological parameters, and spatial number density. Cosmic variance shows the least important influence while changes from the survey geometry, redshift space distortions, cosmological parameters, and redshift evolution produce larger changes of the order of 10−2 bits. The largest influence on the graph entropy comes from changes in the number density of clustred points. As the number density decreases, and the cosmic web is less pronounced, the entropy can diminish up to 0.2 bits. The graph entropy is simple to compute and can be applied both to simulations and observational data from large galaxy redshift surveys; it is a new statistic that can be used in a complementary way to other kinds of topological or clustering measurements.

Print ISSN: 1745-3925

Electronic ISSN: 1745-3933

Topics: Physics

Published by Oxford University Press on behalf of The Royal Astronomical Society.

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