Experiments for unconfined 3D gravity currents produced from continuous inflows propagating down an inclined bottom 0˚≦θ≦15˚ have been investigated. While the denser fluid is released propagating on the sloping surface, a gravity plume analogous to the elliptical shape is generated. The plume travels downslope and spreads laterally due to the gravitational force in streamwise direction and the entrainment in spanwise direction. The formation of front spreading depends on the initiating buoyancy flux, the slope of the bottom and the density difference between the heavy fluid and the ambient fluid. In our experiment the relative density difference is specified as the Non-Boussinesq flow regime, nearly 5.2%. Theoretical expressions were carried out to demonstrate the flow characteristics in experiments based on the dimensional analysis. Interestingly, on θ≧6˚ the effect of slope angle is relatively minimal, as indicated by the shape factor, π1=b⁄xf , that is consistently at the same order, where b is the maximum width of spreading plume and xf is location of effluent front. It is also known that the location of inlet point source, i.e. the virtual origin, could be determined based on linear regressions from the plot of xf~b or from the power-law relations between front location and relative density, xf~〖((∆p/ρ0 )g)〗^(-3/5). The location of virtual origin becomes further upstream as the flow rate increases. Additionally, from the relation xf~h, where h is the thickness of current head, it is noted that the growth of head thickness and the front velocity have a profound effect on the bottom slope rather than the buoyancy flux. With respect to the evolving flow motion, our results also showed that the growth of lateral spreading was dominated by the inlet flow rate.