Thermal Structure and Chemical Enrichment of the North and South Polar Spurs: Supersolar N/O and Ne/O in the X-ray Plasma

Abstract

The North Polar Spur (NPS) is a prominent diffuse X-ray feature whose origin has remained uncertain for decades. Using a uniform analysis of archival Suzaku and XMM--Newton data with new Chandra observations, we constrain its thermal and chemical properties. The NPS emission is fully absorbed by the neutral interstellar medium, demonstrating that the plasma lies beyond the Galactic disk and is not a local supernova remnant or nearby superbubble. The spectra require a two-temperature model with a warm--hot component (kT ≈ 0.2 keV) and a hotter component (kT = 0.4--0.5 keV), with emission measures of (41.8 4.9) × 10-3 and (12.9 2.2) × 10-3 cm-6~pc, respectively. A key result is the detection of super-solar abundance ratios in the warm--hot phase, with N/O = 3.6 0.3 and Ne/O = 1.9 0.1 solar. A Suzaku observation of the outer South Polar Spur (SPS) shows similar absorption, temperatures, and enhanced abundances (N/O = 2.9 0.4, Ne/O = 1.6 0.2), though with lower emission measures. The similar super-solar abundance ratios suggest a common enrichment history. These properties are consistent with those measured along other sightlines through the X-ray--bright shells of the Galactic bubbles. Together, these results support that the NPS and SPS trace opposite limbs of the Galactic bubbles. The chemical properties suggest a strong contribution from stellar feedback in shaping the Galactic bubbles.