A systematic bias in fitting the surface-density profiles of interstellar filaments

Abstract

The surface-density profiles of dense filaments, in particular those traced by dust emission, appear to be well fit with Plummer profiles, i.e. Sigma(b)=SigmaB+SigmaO1+[b/wO]2[1-p]/2. Here SigmaB is the background surface-density; SigmaB+SigmaO is the surface-density on the filament spine; b is the impact parameter of the line-of-sight relative to the filament spine; wO is the Plummer scale-length (which for fixed p is exactly proportional to the full-width at half-maximum, wO=FWHM/222/[p-1]-11/2); and p is the Plummer exponent (which reflects the slope of the surface-density profile away from the spine). In order to improve signal-to-noise it is standard practice to average the observed surface-densities along a section of the filament, or even along its whole length, before fitting the profile. We show that, if filaments do indeed have intrinsic Plummer profiles with exponent pINTRINSIC, but there is a range of wO values along the length of the filament (and secondarily a range of SigmaB values), the value of the Plummer exponent, pFIT, estimated by fitting the averaged profile, may be significantly less than pINTRINSIC. The decrease, Delta p = pINTRINSIC - pFIT, increases monotonically with increasing pINTRINSIC; with increasing range of wO values; and -- if, but only if, there is a finite range of wO values -- with increasing range of SigmaB values. For typical filament parameters the decrease is insignificant if pINTRINSIC = 2 (0.05 <~ Delta p <~ 0.10), but for pINTRINSIC =3 it is larger (0.18 <~ Delta p <~ 0.50), and for pINTRINSIC =4 it is substantial (0.50 <~ Delta p <~ 1.15). On its own this effect is probably insufficient to support a value of pINTRINSIC much greater than pFIT ~ 2, but it could be important in combination with other effects.