In recent years, c-axis-oriented gallium nitride (GaN) based nanorods light-emitting diodes (LEDs) have attracted intensive attention. The reason why GaN nanorod LEDs is so popular can be attributed to the following advantages. First, the area of active regions will increase, while they were grown on three-dimensional (3D) structure nanorods template. Second, the defect density of MQWs grown on nanorods template can be decreased. Third, light extraction performance is greatly enhanced. Fourth, the growth of non-polar and semi-polar multiple quantum well can decrease the polarization-induced effect. In the epitaxial process of the GaN materials in LEDs, the growth rate of multi quantum wells and the indium (In) composition are various in different growth orientations, causing inhomogeneous thickness of the active regions and anisotropic indium distributions in multi quantum wells (MQWs). Furthermore, while re-growing III-nitride materials on the nanorods template, the gradually accumulated materials have a tendency to form pointed tips on the top of each nanorods. This implies a non-uniform electric field distribution will occur on the topmost of nanorod LED. As a result, EL emission wavelength will have a giant blue shift as the injected current increases. These characteristics may make the emission wavelength of nanorod LED deviated from the original design and limit its applications. To conquer the challenges, we propose a novel nanorod LED structure. In our newly designed nanorod LED, the top of nanorod is covered by a dielectric material nano-disk. During the nanorod LED growth, the passivation of dielectric nano-disk on the top can suppress the growth of polar and semi-polar MQWs, leading to a high proportion of non-polar active region. Therefore, the quantum confined stark effect in MQWs can be greatly reduced. Moreover, indium spatially distribution in MQWs may become uniform. On the other hand, with this dielectric material nano-disk, the electric field on the tip of nanorod LED is reduced substantially. Thus, the major of difficulty of the giant blue shift existing in the EL spectra can be avoided. In this work, we have successfully demonstrated that our tip-free core-shell nanorod LEDs indeed possess, the superior features as described above when compared with its conventional counterpart. It is believed that our study shown here will pave a key study for the advancement of high efficient LEDs with excellent performance.