# XMM-Newton detection and spectrum of the second fastest spinning pulsar   PSR J0952-0607

**Authors:** Wynn C.G. Ho (Haverford College), Craig O. Heinke (U. of Alberta),, Andrey I. Chugunov (Ioffe Institute)

arXiv: 1905.12001 · 2019-09-12

## TL;DR

This paper reports the discovery and spectral analysis of the second fastest spinning pulsar, PSR J0952-0607, using XMM-Newton, providing insights into neutron star physics and gravitational wave emission mechanisms.

## Contribution

First X-ray detection and spectral characterization of PSR J0952-0607, the second fastest pulsar, informing models of neutron star oscillations and gravitational wave production.

## Key findings

- X-ray spectrum well-fit by power law or thermal plus power law models
- No evidence of orbital modulation or variability detected
- Constraints on r-mode amplitude and neutron star core temperature

## Abstract

With a spin frequency of 707 Hz, PSR J0952-0607 is the second fastest spinning pulsar known. It was discovered in radio by LOFAR in 2017 at an estimated distance of either 0.97 or 1.74 kpc and has a low-mass companion with a 6.42 hr orbital period. We report discovery of the X-ray counterpart of PSR J0952-0607 using XMM-Newton. The X-ray spectra can be well-fit by a single power law model (Gamma = 2.5) or by a thermal plus power law model (kTeff = 40 eV and Gamma = 1.4). We do not detect evidence of variability, such as that due to orbital modulation from pulsar wind and companion star interaction. Because of its fast spin rate, PSR J0952-0607 is a crucial source for understanding the r-mode instability, which can be an effective mechanism for producing gravitational waves. Using the high end of our measured surface temperature, we infer a neutron star core temperature of ~10^7 K, which places PSR J0952-0607 within the window for the r-mode to be unstable unless an effect such as superfluid mutual friction damps the fluid oscillation. The measured luminosity limits the dimensionless r-mode amplitude to be less than ~1x10^-9.

---
Source: https://tomesphere.com/paper/1905.12001