Mid-infrared time-resolved photoconduction in black phosphorus

TL;DR

This study demonstrates black phosphorus's potential for mid-infrared optoelectronic applications by characterizing its fast, sensitive, room-temperature photoconduction response across 1.56 to 3.75 micrometers.

Contribution

It provides the first detailed characterization of black phosphorus photoconduction in the mid-infrared range, revealing fast response times and nonlinear photoresponse behavior.

Findings

Response time of 65 ps for photoconduction

Sublinear photocurrent nonlinearity observed

Noise-equivalent power of 530 pW/√Hz measured

Abstract

Black phosphorus has attracted interest as a material for use in optoelectronic devices due to many favorable properties such as a high carrier mobility, field-effect, and a direct bandgap that can range from 0.3 eV in its bulk crystalline form to 2 eV for a single atomic layer. The low bandgap energy for bulk black phosphorus allows for direct transition photoabsorption that enables detection of light out to mid-infrared frequencies. In this work we characterize the room temperature optical response of a black phosphorus photoconductive detector at wavelengths ranging from 1.56 $\mu$m to 3.75 $\mu$m. Pulsed autocorrelation measurements in the near-infrared regime reveal a strong, sub-linear photocurrent nonlinearity with a response time of 1 ns, indicating that gigahertz electrical bandwidth is feasible. Time resolved photoconduction measurements covering near- and mid-infrared frequencies show a fast 65 ps rise time, followed by a carrier relaxation with a time scale that matches the intrinsic limit determined by autocorrelation. The sublinear photoresponse is shown to be caused by a reduction in the carrier relaxation time as more energy is absorbed in the black phosphorus flake and is well described by a carrier recombination model that is nonlinear with excess carrier density. The device exhibits a measured noise-equivalent power of 530 pW/$\sqrt{\text{Hz}}$ which is the expected value for Johnson noise limited performance. The fast and sensitive room temperature photoresponse demonstrates that black phosphorus is a promising new material for mid-infrared optoelectronics.