A Fundamental Plane for Gamma-Ray Pulsars

Constantinos Kalapotharakos, Alice K. Harding, Demosthenes Kazanas, Zorawar Wadiasingh

Published 2019-04-03Version 1

We show that the $\gamma$-ray pulsar observables, i.e., their total $\gamma$-ray luminosity, $L_{\gamma}$, spectrum cut-off energy, $\epsilon_{\rm cut}$, stellar surface magnetic field, $B_{\star}$, and spin-down power $\dot{\mathcal{E}}$, obey a relation of the form $L_{\gamma}=f(\epsilon_{\rm cut},B_{\star},\dot{\mathcal{E}})$, which represents a 3D plane in their 4D log-space. Fitting the data of the 88 pulsars of the second Fermi pulsar catalog, we show this relation to be $L_{\gamma}\propto \epsilon_{\rm cut}^{1.18\pm 0.24}B_{\star}^{0.17\pm 0.05}\dot{\mathcal{E}}^{0.41\pm 0.08}$, a pulsar fundamental plane (FP). We show that the observed FP is remarkably close to the theoretical relation $L_{\gamma}\propto \epsilon_{\rm cut}^{4/3}B_{\star}^{1/6}\dot{\mathcal{E}}^{5/12}$ obtained assuming that the pulsar $\gamma$-ray emission is due to curvature radiation by particles accelerated at the pulsar equatorial current sheet just outside the light cylinder. Interestingly, this seems incompatible with emission by synchrotron radiation. The corresponding scatter is $\sim0.35$dex and can only partly be explained by the observational errors while the rest is probably due to the variation of the inclination and observer angles. We predict also that $\epsilon_{\rm cut}\propto \dot{\mathcal{E}}^{7/16}$ toward low $\dot{\mathcal{E}}$ for both young and millisecond pulsars implying that the observed death-line of $\gamma$-ray pulsars is due to $\epsilon_{\rm cut}$ dropping below the Fermi-band. Our results provide a comprehensive interpretation of the observations of $\gamma$-ray pulsars, setting requirement for successful theoretical modeling.