1 Initiation and growth of a hydraulic fracture from a circular wellbore X. Zhang 1 , R. G. Jeffrey 1 , A. P. Bunger 1 and M. Thiercelin 2 1 CSIRO Earth Science and Resource Engineering, Private Bag 10, Clayton South, VIC 3169, Australia 2 Schlumberger RTC-Unconventional Gas, 14131 Midway Road, Suite 700, Addison, TX-75001, USA Submitted to Int. J. Rock Mech. Min. Sci. Abstract A two-dimensional (2D) model is presented for initiation and growth of one or more hydraulic fractures from a well that is aligned with either the maximum or intermediate principal in-situ stress. The coupling of fluid flow and rock deformation plays a key role in reorientation and pattern evolution of the fractures formed. After fracture initiation, the fracture can reorient as it extends from the wellbore until it becomes aligned with the preferred direction for fracture growth relative to the far-field stresses. Initiation and growth of multiple fractures are considered to study their interaction and competition with each other. In such cases, some fractures are unable to extend at all or they arrest after some limited growth, but others can grow in length relative to earlier developed fractures. For fractures that are driven by a uniformly distributed internal pressure, which implies injection of an inviscid fluid, fracture closure may occur at the portion of the fracture path adjacent to the wellbore. This local fracture closure does not typically occur when fluid viscous dissipation is introduced, but the local width is greatly reduced and a fluid lag zone develops. The reduced fracture width results in fluid viscous friction and an associated pressure drop near the wellbore, which makes fracture stimulation more expensive and less successful and may reduce well productivity. Initiation of a fracture using a viscous fluid and a higher injection rate causes the fracture to curve more gradually as it seeks to align with the maximum principal stress direction, a result from our model that is consistent with widely used tortuosity remedy methods. A dimensionless parameter is developed that is shown to characterise near wellbore reorientation and curving of hydraulic fractures driven by viscous