Ultrasensitive and fast single wavelength plasmonic hydrogen sensing with anisotropic nanostructured Pd films

TL;DR

This paper presents a highly sensitive, rapid, single-wavelength optical hydrogen sensor using anisotropic nanostructured Pd films that detect hydrogen concentrations down to 10 ppm within a second.

Contribution

It introduces a novel anisotropic nanostructured Pd film sensor combined with a differential optical technique for real-time, quantitative hydrogen detection at a single visible wavelength.

Findings

Detection limit of 10 ppm H2 in Ar.

Response time below one second for 0.25% H2.

Optical anisotropy evolution matches effective medium theory.

Abstract

Anisotropic nanostructured porous Pd films are fabricated using oblique angle deposition in vacuum on a glass substrate. They display a dichroic response, due to localised surface plasmon resonances (LSPR) within the nanoparticles forming the film, dependent on the incident light polarisation. Ultrasensitive hydrogen sensing is reached by using these films in conjunction with a differential optical technique derived from the reflectance anisotropy spectroscopy. The evolution of the samples optical responses is monitored during the formation of Pd hydride in both the dilute alpha-phase and the dense beta-phase, whilst the samples are exposed to different concentration of H2 in Ar (from 100 percent H2 to a few ppm). The measurements are performed at a single wavelength in the visible range and at 22 deg C. The results show that a quantitative measurement of the hydrogen concentration in a carrier gas can be measured throughout the concentration range. The limit of detection is 10 ppm and the time for detecting the presence of H2 in the carrying gas is below one second at concentration down to 0.25 percent of H2 in Ar. Furthermore, the optical anisotropy of the samples and its evolution with exposure to H2 are correctly reproduced with an effective medium theory.