Probing temperature with lattice matched HgTe/CdTe core/shell nanoparticles

TL;DR

This paper introduces lattice-matched HgTe/CdTe core/shell nanoparticles that exhibit high luminescence and reversible temperature-dependent photoluminescence, enabling highly precise optical thermometry.

Contribution

It reports a novel lattice-matched, durable HgTe/CdTe core/shell nanoparticle with high luminescence and reversible PL changes suitable for efficient luminescence thermometry.

Findings

High luminescence quantum yield in UV range

Reversible PL change with temperature

Temperature resolution of 0.32% per Kelvin

Abstract

Studies of photoluminescence (PL) can provide fundamental insight into the optical properties of semiconductor nanoparticles (NPs) but the same is being limited by NP size distribution and low luminescence yield. Inorganic semiconductor core/shell structures have added advantage of durability, high luminescence quantum yield (LQY), 10-80% in the visible range and useful in biological labeling, LED and luminescence thermometry application. However, luminescence thermometry requires narrow PL line width, intense luminescence and should change with temperature linearly and reversibly which are difficult to achieve from lattice mismatched (3.9%-10.6%) core/shell structures. Here, we report a lattice matched, durable and very small (2.8nm) HgTe/CdTe core/shell NPs whose optical activities are shown to be in the UV range and have yielded very high luminescence. The reversible change of PL with temperature of the core/shell NPs is used as an optical probe temperature sensor with resolution 0.32% per degree Kelvin which deemed to be one of the efficient luminescence thermometers reported till date.