A temporal, inviscid, linear stability analysis of a liquid jet and the co-
flowing gas stream surrounding the jet has been performed. The basic liquid
and gas velocity profiles have been computed self-consistently by solving
numerically the appropriate set of coupled Navier-Stokes equations reduced
using the slenderness approximation. The analysis in the case of a uniform
liquid velocity profile recovers the classical Rayleigh and Weber non-visco
us results as limiting cases for well-developed and very thin gas boundary
layers respectively, but the consideration of realistic liquid velocity pro
files brings to light new families of modes which are essential to explain
atomization experiments at large enough Weber numbers, and which do not app
ear in the classical stability analyses of non-viscous parallel streams. In
fact, in atomization experiments with Weber numbers around 20, we observe
a change in the breakup pattern from axisymmetric to helicoidal modes which
are predicted and explained by our theory as having an hydrodynamic origin
related to the structure of the liquid-jet basic velocity profile. This wo
rk has been motivated by the recent discovery by Ganan-Calvo (1998) of a ne
w atomization technique based on the acceleration to large velocities of co
axial liquid and gas jets by means of a favourable pressure gradient and wh
ich are of emerging interest in microfluidic applications (high-quality ato
mization, micro-fibre production, biomedical applications, etc.).