Electroluminescence (EL) with nearly pure circular polarization (CP) at room temperature has been demonstrated by a lateral-type spin-LEDs consisting of AlGaAs/GaAs double-heterostructures and the crystalline AlO_x (x-AlO_x) tunneling barrier. In this LT-spin-LED, relatively high current density of J > 100 A/cm² was required to achieve the circular polarization of P ~ 0.95. Operation with J > 100 A/cm², however, often resulted in irreversible breakdown and short-lived spin-LED. In order to suppress this breakdown, we have studied fabrication of LT-spin-LED devices incorporating x-AlO_x/AlAs hybrid tunneling barriers. With AlAs layers that are inserted between the x-AlO_x layer and a top n-GaAs layer of LT-spin-LED, we aim at reinforcing electrical robustness of x-AlO_x tunneling barriers that are formed by oxidation of Al epilayers at RT. Consequently, we achieved EL with nearly pure CP with significantly reduced current densities and the yield of device fabrication is significantly improved.