Experimental results for the collapse of granular columns on a rotating table are presented. In the non-rotating case two flow regimes are exhibited dependent on the aspect ratio a = h(0)/r(0), where h(0) is the initial height and r(0) is the initial column radius. Scaling relations for the characteristic geometrical properties of the collapsed column under varying rotation rates are obtained. As the rotation rate increases, material is lost from the main pile and travels to the edge of the rotating table. This results in a decrease in the final radius of the main collapsed pile, as material is lost during this secondary, rotation-induced spreading phase. The degree of mass ejection in the secondary spread increases with rotation frequency for a given initial aspect ratio. Analysis of the flow characteristics including time evolution and final pile height are also described. (C) 2014 Elsevier B.V. All rights reserved.