The Mouse Pulsar Wind Nebula

PSR J1747-2958 is a young (tau=26 kyr), energetic (Edot=2.5x10^36 erg/s) supersonic pulsar at an estimated distance d=5 kpc. It powers the Mouse pulsar wind nebula (PWN; G359.23-0.82), which consists of a pulsar tail spanning 12' in radio and 45" in X-rays. We present the results of our analysis of Chandra X-ray Observatory ACIS and HRC observations of the pulsar and its X-ray nebula, as well as an analysis of archival lower-frequency data. The HRC image reveals a point-like source at the pulsar position, $\approx$1" from the bow shock apex of the PWN. The deep ACIS image and radio/gamma-ray pulse profiles indicate that the compact nebula is composed of a flattened equatorial outflow deformed by the ram pressure, and that the angle between the pulsar's spin axis and the line of sight is about $70^\circ$, while the magnetic dipole axis is inclined to the spin axis by about the same angle. The spatially-resolved spectral map of the X-ray tail shows that the photon index of the power-law (PL) spectrum increases from Gamma=1.65$\pm$0.02 to 3.0$\pm$0.1 over the 45" extent, while the spatially-averaged spectrum of the X-ray tail fits a single absorbed PL with Gamma=2.09$\pm$0.03. We detected the Mouse PWN in 150 MHz GMRT data and found evidence of its detection in 24 ${\rm \mu}$m Spitzer data. The radio and infrared data suggest that, at low frequencies, the spectrum of the X-ray-emitting region of the tail can be described by a broken PL with at least one spectral turnover between radio and X-ray frequencies. Using the multiwavelength data, we estimated a magnetic field $B\sim200$ ${\rm \mu G}$ in the tail (which is consistent with the rapid synchrotron cooling observed) and a bulk flow speed $v\sim4000$ km/s. Together, the estimates also suggest the particle acceleration mechanism produces a broad electron SED, spanning $\gtrsim5$ orders of magnitude.