The NANOGrav Nine-Year Data Set: Observations, Arrival Time Measurements, and Analysis of 37 Millisecond Pulsars

Authors

Zaven Arzoumanian
Adam Brazier
Sarah Burke-Spolaor
Sydney J. Chamberlin
Shami Chatterjee
Brian Christy
James M. Cordes
Neil J. Cornish
Kathryn Crowter
Paul B. Demorest
Timothy Dolch
Justin A. Ellis
Robert D. Ferdman
Emmanuel Fonseca
Nathan Garver-Daniels
Marjorie E. Gonzalez
Fredrick A. Jenet
Glenn Jones
Megan L. Jones
Victoria M. Kaspi
Michael Koop
Michael T. Lam
T. Joseph W. Lazio
Lina Levin
Andrea N. Lommen
Duncan R. Lorimer
Jing Luo
Ryan S. Lynch
Dustin Madison
Maura A. McLaughlin
Sean T. McWilliams
David J. Nice
Nipuni Palliyaguru
Timothy T. Pennucci
Scott M. Ransom
Xavier Siemens
Ingrid H. Stairs
Daniel R. Stinebring, Oberlin CollegeFollow
Kevin Stovall
Joseph K. Swiggum
Michele Vallisneri
Rutger van Haasteren
Yan Wang
Weiwei Zhu

Abstract

We present high-precision timing observations spanning up to nine years for 37 millisecond pulsars monitored with the Green Bank and Arecibo radio telescopes as part of the North American Nanohertz Observatory for Gravitational Waves (NANOGrav) project. We describe the observational and instrumental setups used to collect the data, and methodology applied for calculating pulse times of arrival; these include novel methods for measuring instrumental offsets and characterizing low signal-to-noise ratio timing results. The time of arrival data are fit to a physical timing model for each source, including terms that characterize time-variable dispersion measure and frequency-dependent pulse shape evolution. In conjunction with the timing model fit, we have performed a Bayesian analysis of a parameterized timing noise model for each source, and detect evidence for excess low-frequency, or "red," timing noise in 10 of the pulsars. For 5 of these cases this is likely due to interstellar medium propagation effects rather than intrisic spin variations. Subsequent papers in this series will present further analysis of this data set aimed at detecting or limiting the presence of nanohertz-frequency gravitational wave signals.

Repository Citation

Arzoumanian, Zaven, Adam Brazier, Sarah Burke-Spolaor, et al. 2015. "The NANOGrav Nine-Year Data Set: Observations, Arrival Time Measurements, and Analysis of 37 Millisecond Pulsars." Astrophysical Journal 813(1): article 65.

Publisher

IOP Publishing

Publication Date

10-29-2015

Publication Title

Astrophysical Journal

Department

Physics and Astronomy

Document Type

Article

DOI

https://dx.doi.org/10.1088/0004-637X/813/1/65

Keywords

Gravitational waves, Data analysis, Black hole binaries, Timing array, Relativistic gravity, Interstellar plasma, Radio pulsars

Language

English

Format

text