Near-infrared intersubband photodetection in GaN/AlN nanowires

TL;DR

This paper demonstrates the first intersubband photodetection in GaN/AlN nanowires, showing potential for ultrafast, sensitive IR detectors and quantum cascade devices with enhanced stability.

Contribution

It reports the pioneering fabrication and characterization of nanowire-based intersubband photodetectors using GaN/AlN superlattices, enabling new IR detection capabilities.

Findings

Successful detection at 1.55 μm wavelength.

Photocurrent scales linearly with incident power.

Supports potential for ultrafast, ultrasensitive devices.

Abstract

Intersubband optoelectronic devices rely on transitions between quantum-confined electron levels in semiconductor heterostructures, which enables infrared (IR) photodetection in the 1-30 $\mu$m wavelength window with picosecond response times. Incorporating nanowires as active media could enable an independent control over the electrical cross-section of the device and the optical absorption cross-section. Furthermore, the three-dimensional carrier confinement in nanowire heterostructures opens new possibilities to tune the carrier relaxation time. However, the generation of structural defects and the surface sensitivity of GaAs nanowires have so far hindered the fabrication of nanowire intersubband devices. Here, we report the first demonstration of intersubband photodetection in a nanowire, using GaN nanowires containing a GaN/AlN superlattice absorbing at 1.55 $\mu$m. The combination of spectral photocurrent measurements with 8-band k$\cdot$p calculations of the electronic structure supports the interpretation of the result as intersubband photodetection in these extremely short-period superlattices. We observe a linear dependence of the photocurrent with the incident illumination power, which confirms the insensitivity of the intersubband process to surface states and highlights how architectures featuring large surface-to-volume ratios are suitable as intersubband photodetectors. Our analysis of the photocurrent characteristics points out routes for an improvement of the device performance. This first nanowire based intersubband photodetector represents a technological breakthrough that paves the way to a powerful device platform with potential for ultrafast, ultrasensitive photodetectors and highly-efficient quantum cascade emitters with improved thermal stability.