Ultrafast exciton decay in PbS quantum dots through simultaneous electron and hole recombination with a surface-localized ion pair

Edme, Kedy; Homan, Stephanie Bettis; Nepomnyashchii, Alexander B.; Weiss, Emily A.

doi:10.1016/j.chemphys.2015.09.012

Cited by 5 publications

(8 citation statements)

References 25 publications

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“…Weiss and co-workers “p-doped” the surfaces of PbS and CdSe QDs by treating them with tetracyanoquinodimethane (TCNQ), which spontaneously oxidizes surface chalcogenides but does not oxidize the core (Figure ). They observed a similar surface doping upon addition of ferrocenium to oleate-capped PbS QDs …”

Section: Role Of Molecules In the Electronic Structure Of Colloidal Qdsmentioning

confidence: 99%

“…They observed a similar surface doping upon addition of ferrocenium to oleate-capped PbS QDs. 160 Gamelin, Mayer, and co-workers used a dimethylcobaltocene/ dimethylcobaltocenium (CoCp* + /CoCp*) redox indicator to demonstrate the effect of pH on the band-edge positions of colloidal ZnO QDs. 100,161,162 They noted that in more acidic conditions, the ZnO was reduced at less negative potentials and oxidized at more positive potentials.…”

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Electronic Processes within Quantum Dot-Molecule Complexes

et al. 2016

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The subject of this review is the colloidal quantum dot (QD) and specifically the interaction of the QD with proximate molecules. It covers various functions of these molecules, including (i) ligands for the QDs, coupled electronically or vibrationally to localized surface states or to the delocalized states of the QD core, (ii) energy or electron donors or acceptors for the QDs, and (iii) structural components of QD assemblies that dictate QD-QD or QD-molecule interactions. Research on interactions of ligands with colloidal QDs has revealed that ligands determine not only the excited state dynamics of the QD but also, in some cases, its ground state electronic structure. Specifically, the article discusses (i) measurement of the electronic structure of colloidal QDs and the influence of their surface chemistry, in particular, dipolar ligands and exciton-delocalizing ligands, on their electronic energies; (ii) the role of molecules in interfacial electron and energy transfer processes involving QDs, including electron-to-vibrational energy transfer and the use of the ligand shell of a QD as a semipermeable membrane that gates its redox activity; and (iii) a particular application of colloidal QDs, photoredox catalysis, which exploits the combination of the electronic structure of the QD core and the chemistry at its surface to use the energy of the QD excited state to drive chemical reactions.

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Section: Role Of Molecules In the Electronic Structure Of Colloidal Qdsmentioning

confidence: 99%

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Electronic Processes within Quantum Dot-Molecule Complexes

et al. 2016

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“…As the applied potential reaches − 0.9 V, the core emission shows a faster decay and a redshifted spectrum relative to that at 0 V. This is attributed to the adsorption of the cations from the electrolyte onto the surfaces of the QDs. As mentioned above, the electron injection into the surface trap states occurs at − 0.9 V. The adsorbed cations serve as counterions to the injected electrons [ 25 , 37 , 38 ] and charge acceptors [ 39 ], giving rise to the dissociation of the exciton by charge transfer and quenching of the PL. As the applied potential is decreased to more negative values, a greater quenching occurs due to the potential difference-induced penetration of cations.…”

Section: Resultsmentioning

confidence: 99%

Reversible Electrochemical Control over Photoexcited Luminescence of Core/Shell CdSe/ZnS Quantum Dot Film

Liu

et al. 2017

Nanoscale Res Lett

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Semiconductor quantum dots (QDs) are widely used in light-emitting diodes and solar cells. Electrochemical modulation is a good way to understand the electrical and optical properties of QDs. In this work, the effects of electrochemical control on photoluminescence (PL) spectra in core/shell CdSe/ZnS QD films are studied. The results show different spectral responses for surface emission and core emission when a negative electrochemical potential is applied: the core emission is redshifted while the surface emission is blueshifted. The former is attributed to the electrostatic expansion of the excitonic wave function, due to the asymmetric distribution of adsorbed cations on the surface of the dots. The latter is attributed to the occupation of lower surface states by the injected electrons, i.e., the photoexcited electrons are more likely to be trapped onto higher surface states, leading to a blueshift of the surface emission. Both the spectral shift and the accompanying PL-quenching processes are reversible by resetting the potential.

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“…PL quenching was also observed through TCNQ doping of PbS CQDs. 55 This could be a showstopper for F4-TCNQ doped Ag 2 Se CQDs as well, as photoexcited carriers would be absorbed by excess F4-TCNQ molecules on the surface of the CQDs instead of being transported to the contacts. Keeping the excess F4-TCNQ to a minimum would therefore be of critical importance; hence, we are devising ways to quench the MWIR peak and enable the SWIR absorbance with controlled amounts of F4-TCNQ.…”

Section: X-ray Photoelectron Spectroscopy (Xps)mentioning

confidence: 99%

“…Additionally, improved performance of CdSe/CdSe nanorod-based LEDs has been observed through F4-TCNQ doping, 56 and electron transfer from CQDs to a molecular dopant has also been shown for the related, but less polar molecule tetracyanoquinodimethane (TCNQ). 54,55,57 A challenge with molecular doping, particularly in organic semiconductors such as poly(3-hexylthiophene) (P3HT), is the low doping efficiency. 58 In some cases, a dopant amount of up to 35−50% F4-TCNQ is necessary to achieve sufficient change in electrical conductivity in organic material.…”

Section: Introductionmentioning

confidence: 99%

Dedoping of Intraband Silver Selenide Colloidal Quantum Dots through Strong Electronic Coupling at Organic/Inorganic Hybrid Interfaces

Mo̷lnås,

Paul,

Scimeca

et al. 2024

Crystal Growth & Design

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Colloidal quantum dot (CQD) infrared (IR) photodetectors can be fabricated and operated with larger spectral tunability, fewer limitations in terms of cooling requirements and substrate lattice matching, and at a potentially lower cost than detectors based on traditional bulk materials. Silver selenide (Ag 2 Se) has emerged as a promising sustainable alternative to current state-of-the-art toxic semiconductors based on lead, cadmium, and mercury operating in the IR. However, an impeding gap in available absorption bandwidth for Ag 2 Se CQDs exists in the short-wave infrared (SWIR) region due to degenerate doping by the environment, switching the CQDs from intrinsic interband semiconductors in the near-infrared (NIR) to intraband absorbing CQDs in the mid-wave infrared (MWIR). Herein, we show that the small molecular p-type dopant 2,3,5,6-tetrafluoro-7,7,8,8tetracyanoquinodimethane (F4-TCNQ) can be used to extract electrons from the 1S e state of MWIR active Ag 2 Se CQDs to activate their intrinsic energy gap in the SWIR window. We demonstrate quenching of the MWIR Ag 2 Se absorbance peak, shifting of nitrile vibrational peaks characteristic of charge-neutral F4-TCNQ, as well as enhanced CQD absorption around ∼2500 nm after doping both in ambient and under air-free conditions. We elucidate the doping mechanism to be one that involves an integer charge transfer akin to doping in semiconducting polymers. These indications of charge transfer are promising milestones on the path to achieving sustainable SWIR Ag 2 Se CQD photodetectors.

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Ultrafast exciton decay in PbS quantum dots through simultaneous electron and hole recombination with a surface-localized ion pair

Cited by 5 publications

References 25 publications

Electronic Processes within Quantum Dot-Molecule Complexes

Electronic Processes within Quantum Dot-Molecule Complexes

Reversible Electrochemical Control over Photoexcited Luminescence of Core/Shell CdSe/ZnS Quantum Dot Film

Dedoping of Intraband Silver Selenide Colloidal Quantum Dots through Strong Electronic Coupling at Organic/Inorganic Hybrid Interfaces

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