Abstract
The quantum confinement effect and photoenhancement of photoluminescence (PL) of lead sulphide (PbS) quantum dots (QDs) and lead sulphide/manganese sulphide (PbS/MnS) core shell QDs capped with thiol ligands in aqueous solution were investigated. From PL results, the presence of MnS shells gives a strong confinement effect which translates to higher emission energy in PbS/MnS core shell QDs. Increasing MnS shell thickness from 0.3 to 1.5 monolayers (ML) causes a blueshift of PL peak energies as the charge carriers concentrated in the PbS core region. Enhancement of the PL intensity of colloidal PbS and PbS/MnS core shell QDs has been observed when the samples are illuminated above the band gap energy, under continuous irradiation for 40 min. Luminescence from PbS QDs and PbS/MnS core shell QDs can be strongly influenced by the interaction of water molecules and oxygen present in aqueous solution adsorbed on the QD surface. However, PbS/MnS core shell QDs with a shell thickness of 1.5 ML did not show a PL peak energy stability as it was redshifted after 25 min, probably due to wider size distribution of the QDs.
Highlights
Colloidal quantum dots (QDs) have attracted great attention over the last decades because of their unique optical properties related to quantum confinement effects where their band gap can be tuned by adjusting their particle size [1,2]
We investigated the quantum confinement effect and photoenhancement of colloidal PbS QDs and PbS/MnS core shell QDs with various shell thicknesses after they were irradiated with continuous laser light for 40 min
At the beginning of the PL measurement, it was found that the PL peak energy was gradually increased with shell thickness due to the presence of MnS shells which confined charge carriers inside the core of PbS
Summary
Colloidal quantum dots (QDs) have attracted great attention over the last decades because of their unique optical properties related to quantum confinement effects where their band gap can be tuned by adjusting their particle size [1,2]. PbS may offer unique opportunities to study the fundamental physics of quantum confinement due to the fact that it has a large exciton Bohr radius (~18 nm) which can achieve a strong quantum confinement effect with a small QD diameter (
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