The cosmic ray distribution in Sagittarius B

The H. E. S. S. instrument has observed a diffuse flux of similar to TeV gamma-rays from a large solid angle around the Galactic center ( GC). This emission is correlated with the distribution of gas in the region, suggesting that the gamma-rays originate in collisions between cosmic-ray hadrons (CRHs) and ambient matter. Of particular interest, H. E. S. S. has detected gamma-rays from the Sagittarius (Sgr) B molecular cloud complex. Prompted by the suggestion of a hadronic origin for the gamma-rays, we have examined archival 330 and 74 MHz Very Large Array radio data and 843 MHz Sydney University Molonglo Sky Survey data covering Sgr B, looking for synchrotron emission from secondary electrons and positrons ( expected to be created in the same interactions that supply the observed gamma-rays). Intriguingly, we have uncovered nonthermal emission, but at a level exceeding expectation. Adding to the overall picture, recent observations by the Atacama Pathfinder Experiment telescope show that the cosmic-ray ionization rate is 10 times greater in the Sgr B2 region of Sgr B than the local value. Lastly, Sgr B2 is also a very bright X-ray source. We examine scenarios for the spectra of CRHs and/or primary electrons that would reconcile all these different data. We determine that ( 1) a hard (similar to E-2.2), high-energy (greater than or similar to TeV) population of CRHs is unavoidably required by the H. E. S. S. gamma-ray data, and ( 2) the remaining broadband, nonthermal phenomenology is explained either by a rather steep (similar to E-2.9) spectrum of primary electrons or a (similar to E-2.7) population of CRHs. Perhaps unsurprisingly, no single power-law population of either leptons or hadrons can explain the totality of broadband, nonthermal Sgr B phenomenology.