Optically Cooling Cesium Lead Tribromide Nanoparticles

TL;DR

This paper demonstrates for the first time that colloidal cesium lead trihalide nanocrystals can be optically cooled through up-conversion photoluminescence, verified by Raman thermometry showing a temperature decrease during laser excitation.

Contribution

It introduces the novel concept of optical cooling using colloidal semiconductor nanocrystals via up-conversion photoluminescence.

Findings

Achieved local temperature decrease of up to 25°C during optical pumping.

Verified cooling effect using Raman thermometry.

First demonstration of optical cooling with colloidal semiconductor nanocrystals.

Abstract

One photon up-conversion photoluminescence is an optical phenomenon whereby the thermal energy of a fluorescent material increases the energy of an emitted photon compared with the energy of the photon that was absorbed. When this occurs with near unity efficiency, the emitting material undergoes a net decrease in temperature--so called optical cooling. Because the up-conversion mechanism is thermally activated, the yield of up-converted photoluminescence is also a reporter of the temperature of the emitter. Taking advantage of this optical signature, cesium lead trihalide nanocrystals are shown to cool during the up-conversion of 532 nm CW laser excitation. Raman thermometric analysis of a substrate the nanocrystals were deposited on further verifies the decrease in the local environmental temperature by as much as 25 degrees during optical pumping. This is the first demonstration of optical cooling driven by colloidal semiconductor nanocrystal up-conversion.