Hybrid laser welding offers promising advantages over the traditional arc-based welding processes. The high penetration ability of lasers and the filler wire delivery of gas metal arc welding enable joining of thick section materials without the need of multipass. The output power of modern solid state lasers provides enough energy to penetrate thicknesses exceeding 20 mm in steel. However, the high aspect ratio fusion zone with the rapid solidification does not always provide beneficial conditions for achieving good weld profiles. Distribution of the liquid metal between the top and root sides of a joint, and hence the weld profile, is determined by a complex balance between the vaporization pressure of a laser, the electromagnetic force of an arc, and the surface tension of a meltpool. In this work, the stability of the root profile and all the aspects related to the achievement of acceptable roots in pipeline welding have been investigated. It has been found that in order to achieve a smooth root profile in deep penetration hybrid laser welding, not only a sufficient penetration force but also a certain amount of energy need to be provided. This is required to maintain the keyhole fully developed with a steady state pressure balance throughout the thickness. It is also important to achieve sufficient temperature in the root and to provide appropriate wetting between the liquid metal and the back surface of the material. Depending on the power density and energy used, different regimes were identified with sagging of the root in the initial stage, followed by good quality root profiles and then ending on excessive melt expulsion with a further increase in power density. The results suggest that if operated in the right regime, the process is very tolerant, in terms of energy, and power density required for acceptable root profiles and good quality joints can be achieved.