Polarization control in nitride quantum well light emitters enabled by bottom tunnel-junctions

Abstract

The frozen internal polarization-induced electric fields due to broken inversion symmetry in all conventional blue and green nitride semiconductor light-emitting semiconductor quantum well heterostructures point in a direction opposite to what is desired for efficient flow of electrons and holes. This state of affairs has persisted because of the desire to have p-type hole injectors on top of the quantum well active region. Because of the internal polarization fields in nitride heterostructures, there exist four permutations of doping and polarization for the realization of such light emitters. Which permutation is the most desirable for efficient light emission? In this work, we answer this question by demonstrating a fundamentally new approach toward efficient light emission with "bottom-tunnel junctions." The bottom-tunnel junction design aligns the polarization fields in the desired direction in the quantum well while simultaneously eliminating the need for p-type contacts and allowing efficient current spreading. By preventing electron overshoot past quantum wells, it disables carrier recombination in undesired regions of the quantized heterostructures and opens up the possibility for new geometries of integrating and stacking multiple light emitters.