Super Sensitization: Grand Charge (Hole/Electron) Separation in ATC Dye Sensitized CdSe, CdSe/ZnS Type‐I, and CdSe/CdTe Type‐II Core–Shell Quantum Dots

Debnath, Tushar; Ghosh, Hirendra N.

doi:10.1002/chem.201403267

Cited by 27 publications

(52 citation statements)

References 46 publications

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“…In our previous investigation, we have demonstrated ultrafast interfacial electron‐transfer dynamics with a series of TPM dyes with different molecular structures and coupling . We have also reported CT dynamics with TPM‐dye‐sensitized CdSe and CdS QDs and found that a TPM‐dye–QD composite can act as a super‐sensitizer in a QD solar cell …”

Section: Introductionmentioning

confidence: 92%

Effect of Molecular Coupling on Ultrafast Electron‐Transfer and Charge‐Recombination Dynamics in a Wide‐Gap ZnS Nanoaggregate Sensitized by Triphenyl Methane Dyes

2015

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Wide-band-gap ZnS nanocrystals (NCs) were synthesized, and after sensitizing the NCs with series of triphenyl methane (TPM) dyes, ultrafast charge-transfer dynamics was demonstrated. HRTEM images of ZnS NCs show the formation of aggregate crystals with a flower-like structure. Exciton absorption and lumimescence, due to quantum confinement of the ZnS NCs, appear at approximately 310 and 340 nm, respectively. Interestingly, all the TPM dyes (pyrogallol red, bromopyrogallol red, and aurin tricarboxylic acid) form charge-transfer complexes with the ZnS NCs, with the appearance of a red-shifted band. Electron injection from the photoexcited TPM dyes into the conduction band of the ZnS NCs is shown to be a thermodynamically viable process, as confirmed by steady-state and time-resolved emission studies. To unravel charge-transfer (both electron injection and charge recombination) dynamics and the effect of molecular coupling, femtosecond transient absorption studies were carried out in TPM-sensitized ZnS NCs. The electron-injection dynamics is pulse-width-limited in all the ZnS/TPM dye systems, however, the back electron transfer differs, depending on the molecular coupling of the sensitizers (TPM dyes). The detailed mechanisms for the above-mentioned processes are discussed.

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Section: Introductionmentioning

confidence: 92%

Effect of Molecular Coupling on Ultrafast Electron‐Transfer and Charge‐Recombination Dynamics in a Wide‐Gap ZnS Nanoaggregate Sensitized by Triphenyl Methane Dyes

2015

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“…In addition to that lower QD loading on TiO 2 surface (as compared to dye loading in DSSC) resulting direct electron transfer from TiO 2 film to the oxidized redox couple in photo anode. However exciton dissociation through hole transfer is not widely reported in literature except few recent reports by us [26][27][28][29] and Kamat & co-workers 30 . Electron injection is much faster as compared to hole transfer, so for efficient devices hole has to extracted from QD surface as fast as possible 20 .…”

Section: Introductionmentioning

confidence: 96%

Cascading electron and hole transfer dynamics in a CdS/CdTe core–shell sensitized with bromo-pyrogallol red (Br-PGR): slow charge recombination in type II regime

2015

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Ultrafast cascading hole and electron transfer dynamics have been demonstrated in a CdS/CdTe type II core-shell sensitized with Br-PGR using transient absorption spectroscopy and the charge recombination dynamics have been compared with those of CdS/Br-PGR composite materials. Steady state optical absorption studies suggest that Br-PGR forms strong charge transfer (CT) complexes with both the CdS QD and CdS/CdTe core-shell. Hole transfer from the photo-excited QD and QD core-shell to Br-PGR was confirmed by both steady state and time-resolved emission spectroscopy. Charge separation was also confirmed by detecting electrons in the conduction band of the QD and the cation radical of Br-PGR as measured from femtosecond transient absorption spectroscopy. Charge separation in the CdS/Br-PGR composite materials was found to take place in three different pathways, by transferring the photo-excited hole of CdS to Br-PGR, electron injection from the photo-excited Br-PGR to the CdS QD, and direct electron transfer from the HOMO of Br-PGR to the conduction band of the CdS QD. However, in the CdS/CdTe/Br-PGR system hole transfer from the photo-excited CdS to Br-PGR and electron injection from the photo-excited Br-PGR to CdS take place after cascading through the CdTe shell QD. Charge separation also takes place via direct electron transfer from the Br-PGR HOMO to the conduction band of CdS/CdTe. Charge recombination (CR) dynamics between the electron in the conduction band of the CdS QD and the Br-PGR cation radical were determined by monitoring the bleach recovery kinetics. The CR dynamics were found to be much slower in the CdS/CdTe/Br-PGR system than in the CdS/Br-PGR system. The formation of the strong CT complex and the separation of charges cascading through the CdTe shell help to slow down charge recombination in the type II regime.

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“…Also, in the case of CdSe/CdTet ype II coreshell particles, emission quenching takes place in the presence of 4NP (electron quencher), in which electrons are supposed to localize in the CdSe core (Figure 4f and f'). In our earlier investigation, we have observed that both electron and hole transfer processes from photoexcited QDs to the molecular adsorbatesc an take place on an ultrafast timescale, [24,44,45] which cannot be accounted for by time-resolved emissionq uenching studies. The emission spectrum of the CdSe/ CdTet ype II core-shell particles is broader,r elative to that of CdSe/CdSq uasi-type II core-shell particles, which showse mission maximaa tl = 575 nm with as houlder at l = 555 nm.…”

Section: Scheme2a)mentioning

confidence: 96%

“…[44] It shouldb en oted that, althoughe lectrons are delocalized throughout the CBs of both CdSe and CdS in the NC, electron wavefunction overlap between CdSe and 4-NP will be much higher than that of CdSe/CdS and 4-NP composite. B) Schematic illustration of cascading hole transfer from the CdTeshell to 4MP and also cascading from the CdSe core to the CdTes hell and finally to 4MP,and electron transfer from the CdTes hell to 4NP and also leaking from the CdSe core through the CdTes hell to 4NP.…”

Section: Scheme2a)mentioning

confidence: 99%

“…Charge separation has also been demonstrated in type II coreshell nanostructures, in whicho ne of the carrierl eakages to the shell leads to charge separation. [44,45] In QDs, ah igh fraction of atoms reside on the surface ( % 56 %a toms for 3nmQ Ds), which interacts with the surroundings. [42,43] Exciton dissociation in the core-shell structure in the presence of am olecular adsorbate has also been reported by us.…”

Section: Introductionmentioning

confidence: 99%

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Tuning Hole and Electron Transfer from Photoexcited CdSe Quantum Dots to Phenol Derivatives: Effect of Electron‐Donating and ‐Withdrawing Moieties

Debnath

Sebastian

Maiti

et al. 2017

Chemistry A European J

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Charge-transfer processes from photoexcited CdSe quantum dots (QDs) to phenol derivatives with electron- donating (4-methoxy) and -withdrawing (4-nitro) moieties have been demonstrated by using steady-state and time- resolved emission and femtosecond transient absorption spectroscopy. Steady-state and time-resolved emission studies suggest that in the presence of both 4-nitrophenol (4NP) and 4-methoxyphenol (4MP) CdSe QDs luminescence is quenched. Stern-Volmer analysis suggests both static and dynamic mechanisms are active for both the QD/phenol composites. Cyclic voltammetric analysis recommends that photoexcited CdSe QDs can donate electrons to 4NP and holes to 4MP. To reconfirm both electron- and hole-transfer mechanisms, CdSe/CdS quasi-type II and CdSe/CdTe type II core-shell nanocrystals were synthesized and photoluminescence quenching was monitored in the absence and presence of both 4NP and 4MP, for which hole and electron transfer were systematically restricted. Results suggest that indeed electron and hole transfer take place from photoexcited CdSe to 4NP and 4MP, respectively. To monitor the charge-transfer dynamics in both systems on an early timescale, femtosecond transient absorption spectroscopic techniques have been employed. Electron and hole transfer and charge-recombination dynamics are discussed and the effect of electron-donating and -withdrawing groups has been demonstrated.

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Super Sensitization: Grand Charge (Hole/Electron) Separation in ATC Dye Sensitized CdSe, CdSe/ZnS Type‐I, and CdSe/CdTe Type‐II Core–Shell Quantum Dots

Cited by 27 publications

References 46 publications

Effect of Molecular Coupling on Ultrafast Electron‐Transfer and Charge‐Recombination Dynamics in a Wide‐Gap ZnS Nanoaggregate Sensitized by Triphenyl Methane Dyes

Effect of Molecular Coupling on Ultrafast Electron‐Transfer and Charge‐Recombination Dynamics in a Wide‐Gap ZnS Nanoaggregate Sensitized by Triphenyl Methane Dyes

Cascading electron and hole transfer dynamics in a CdS/CdTe core–shell sensitized with bromo-pyrogallol red (Br-PGR): slow charge recombination in type II regime

Tuning Hole and Electron Transfer from Photoexcited CdSe Quantum Dots to Phenol Derivatives: Effect of Electron‐Donating and ‐Withdrawing Moieties

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