Observation of trapped-hole diffusion on the surfaces of CdS nanorods

Utterback, James K.; Grennell, Amanda N.; Wilker, Molly B.; Pearce, Orion M.; Eaves, Joel D.; Duković, Gordana

doi:10.1038/nchem.2566

Cited by 105 publications

(283 citation statements)

References 49 publications

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“…We show that the rates are related to an anisotropic diffusion coefficient, and from the rate theory, propose a lower bound on the reorganization energy for hole hopping that is consistent with the experimental data reported in Ref. 26.…”

supporting

confidence: 90%

On the Nature of Trapped-Hole States in CdS Nanocrystals and the Mechanism of Their Diffusion

Cline

Utterback

Strong

et al. 2018

J. Phys. Chem. Lett.

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Recent transient absorption experiments on CdS nanorods suggest that photoexcited holes rapidly trap to the surface of these particles and then undergo diffusion along the rod surface. In this Letter, we present a semiperiodic density functional theory model for the CdS nanocrystal surface, analyze it, and comment on the nature of both the hole-trap states and the mechanism by which the holes diffuse. Hole states near the top of the valence band form an energetic near continuum with the bulk and localize to the nonbonding sp orbitals on surface sulfur atoms. After localization, the holes form nonadiabatic small polarons that move between the sulfur orbitals on the surface of the particle in a series of uncorrelated, incoherent, thermally activated hops at room temperature. The surface-trapped holes are deeply in the weak-electronic coupling limit and, as a result, undergo slow diffusion.

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supporting

confidence: 90%

On the Nature of Trapped-Hole States in CdS Nanocrystals and the Mechanism of Their Diffusion

Cline

Utterback

Strong

et al. 2018

J. Phys. Chem. Lett.

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“…Fort he unmodified CdSe NCs,t wo time constants, t 1 = 1.05 ps and t 2 = 34.6 ns,w ere needed for as atisfactory fit of the data. [14,15] This change is observed across all CdSe/PyAn complexes as the same functional group is involved. [14] Thet ime constants extracted are in good agreement with previous reports.…”

Section: Angewandte Chemiementioning

confidence: 88%

“…[14] Analysis of the ESA of the CdSe NC photosensitizers functionalized with pyridine bidentate ligands with at riexponential fit given the longest component fixed, yielded two other decay components with similar timescales of about 40 ps and approximately 1nsf or all three ligands.W en ote that the fastest decay process, t trap % 40 ps,isslower than that for the pristine CdSe NCs and may correspond to charge trapping to deeper defects that were created during ligand exchange and cleaning. [14,15] This change is observed across all CdSe/PyAn complexes as the same functional group is involved. In the presence of atransmitter ligand, the new decay constant, t q ,w ith at imescale of approximately 1ns, corresponds to an additional decay pathway introduced by surface-bound PyAn transmitters, which is most probably due to TET from F =AE 2("dark" state on NC) to T L1 (the triplet state on anthracene) or other decay processes induced by the disruption of the original ligand shell.…”

mentioning

confidence: 88%

Complementary Lock‐and‐Key Ligand Binding of a Triplet Transmitter to a Nanocrystal Photosensitizer

Fast

Huang

et al. 2017

Angewandte Chemie

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Owing to the difficulty in comprehensively characterizing nanocrystal (NC) surfaces,c lear guidance for ligand design is lacking. In this work, as eries of bidentate bis-(pyridine) anthracene isomers (2,3-PyAn, 3,3-PyAn, 2,2-PyAn) that differ in their binding geometries were designed to find the best complementary fit to the NC surface.T he efficiency of triplet energy transfer (TET) from the CdSe NC donor to ad iphenylanthracene (DPA) acceptor mediated by these isomers was used as ap roxy for the efficacy of orbital overlap and therefore ligand binding. 2,3-PyAn, with an intramolecular N-N distance of 8.2 ,p rovided the best matcht ot he surface of CdSe NCs.W hen serving as at ransmitter for photon upconversion, 2,3-PyAn yielded the highest upconversion quantum yield (QY) of 12.1 AE 1.3 %, followed by 3,3-PyAn and 2,2-PyAn. The TET quantum efficiencies determined by ultrafast transient absorption measurements showed the same trend.

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“…Photoelectrochemical (PEC) water splitting offers a feasible approach for solar-to-hydrogen conversion to realize the utilization of solar energy, which is also one of the most promising strategies to solve the energy crisis. [6][7][8][9] The PEC application of CdS has been intensively studied. [3][4][5] As a narrow bandgap n-type semiconductor (2.4 eV), CdS has been widely studied as a typical PEC photoanode, owing to its visible-light absorption, high charge mobility, appropriate band position for water redox reaction.…”

Section: Introductionmentioning

confidence: 99%

“…[3][4][5] As a narrow bandgap n-type semiconductor (2.4 eV), CdS has been widely studied as a typical PEC photoanode, owing to its visible-light absorption, high charge mobility, appropriate band position for water redox reaction. [6][7][8][9] The PEC application of CdS has been intensively studied. [10][11][12][13][14][15][16][17] However, many studies have revealed that the PEC activity of pure CdS is severely limited because of the highly photogenerated carrier recombination.…”

Section: Introductionmentioning

confidence: 99%

Structure and Band Alignment Engineering of CdS/TiO₂/Bi₂WO₆ Trilayer Nanoflake Array for Efficient Photoelectrochemical Water Splitting

Chen

Tian

et al. 2019

ChemElectroChem

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Designing photoanode materials with desirable architecture and band alignment is essential for boosting photoelectrochemical (PEC) water splitting performance. Herein, a trilayer CdS/TiO 2 /Bi 2 WO 6 guest-host photoanode is designed and fabricated, in which highly-porous Bi 2 WO 6 nanoflake array serves as the host skeleton, while CdS nanoparticles function as superb visible light absorber. An ultrathin TiO 2 interlayer is rationally inserted between Bi 2 WO 6 and CdS, which not only assists the uniform growth of CdS, but also serves as a band-matching semiconductor to promote the charge transport. By optimizing the thickness of TiO 2 layer, the resulting trilayer photoanode exhibits higher PEC performance (2.62/4.91 mA cm À 2 at 1.23 V vs. reversible hydrogen electrode without/with the presence of hole scavenger) under AM 1.5G illumination compared with pristine CdS film. The enhancement of PEC performance is attributed to the enlarged surface area and superior light harvesting ability of the 3D nanoflake nanostructure, and improved charge transport efficiency resulting from the cascaded energy level structure.[a] C.

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Observation of trapped-hole diffusion on the surfaces of CdS nanorods

Cited by 105 publications

References 49 publications

On the Nature of Trapped-Hole States in CdS Nanocrystals and the Mechanism of Their Diffusion

On the Nature of Trapped-Hole States in CdS Nanocrystals and the Mechanism of Their Diffusion

Complementary Lock‐and‐Key Ligand Binding of a Triplet Transmitter to a Nanocrystal Photosensitizer

Structure and Band Alignment Engineering of CdS/TiO₂/Bi₂WO₆ Trilayer Nanoflake Array for Efficient Photoelectrochemical Water Splitting

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Observation of trapped-hole diffusion on the surfaces of CdS nanorods

Cited by 105 publications

References 49 publications

On the Nature of Trapped-Hole States in CdS Nanocrystals and the Mechanism of Their Diffusion

On the Nature of Trapped-Hole States in CdS Nanocrystals and the Mechanism of Their Diffusion

Complementary Lock‐and‐Key Ligand Binding of a Triplet Transmitter to a Nanocrystal Photosensitizer

Structure and Band Alignment Engineering of CdS/TiO2/Bi2WO6 Trilayer Nanoflake Array for Efficient Photoelectrochemical Water Splitting

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Structure and Band Alignment Engineering of CdS/TiO₂/Bi₂WO₆ Trilayer Nanoflake Array for Efficient Photoelectrochemical Water Splitting