posted on 2024-03-11, 14:10authored byAugustin Caillas, Philippe Guyot-Sionnest
Using a metal/insulator/metal (MIM) structure with a
gold nanoantenna
array made by electron beam lithography, the responsivity of a HgTe
colloidal quantum dot film is enhanced in the mid-infrared. Simulations
indicate that the spatially averaged peak spectral absorption of an
80 nm film is 60%, enhanced 23-fold compared to that of the same film
on a bare sapphire substrate. The field intensity enhancement is focused
near the antenna tips, being 20-fold 100 nm away, which represents
only 1% of the total area and up to 1000-fold at the tips. The simulated
polarized absorption spectra are in good agreement with the experiments,
with a strong resonance around 4 μm. A responsivity of 0.6 A/W
is obtained at a 1 V bias. Noise measurements separate the 1/f noise
from the generation–recombination white noise and give a spatially
averaged photoconductive gain of 0.3 at 1 V bias. The spatially averaged
peak detectivity is improved 15-fold compared to the same film on
a sapphire substrate without an MIM structure. The experimental peak
detectivity reaches 9 × 109 Jones at 2650 cm–1 and 80 kHz, decreasing at lower frequencies. The MIM structure also
enhances the spatially averaged peak photoluminescence of the CQD
film by 16-fold, which is a potential Purcell enhancement. The good
agreement between simulations and measurements confirms the viability
of lithographically designed nanoantenna structures for vastly improving
the performance of mid-IR colloidal quantum dot photoconductors. Further
improvements will be possible by matching the optically enhanced and
current collection areas.