Search for: All records

From the past research results, it is evident that high-energy blue emission requires higher applied voltage in a blue nanowire light-emitting diode (LED) due to which difficulties such as self-heating and poor efficiency are developed. While designing a nanowire LED with III-nitride materials, the radiative recombination rate is reduced as the internal field of polarization inside the existing Ga-polar LEDs will tilt the energy band. But with the involvement of N-polar characteristics, the polarization field direction is reversed which eventually brings higher efficiency and lower turn-on voltage across the wavelength range. The subject of this work is to design and simulate an N-polar tunnel junction (TJ) blue nanowire LED to obtain better thermal as well as opto-electronic performances with minimal turn-on voltage. Moreover, TJ-LEDs show linear increases in light output powers (LOP) with varying current densities due to lower Auger recombination rates in their multi-quantum wells (MQWs). Within a temperature range of 30–150 , the proposed device obtains a lower thermal droop of 5.2 % at a current density of 40 A/cm2 which is 2.2 times less than the conventional one.