Oriented Built-in Electric Field Introduced by Surface Gradient Diffusion Doping for Enhanced Photocatalytic H<sub>2</sub> Evolution in CdS Nanorods

Huang, Hengming; Dai, Baoying; Wang, Wei; Lu, Chunhua; Kou, Jiahui; Ni, Yaru; Wang, Luyao; Xu, Zhongzi

doi:10.1021/acs.nanolett.7b01147

Cited by 232 publications

(140 citation statements)

References 28 publications

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“…Both pristine CdS QDs and Ni:CdS QDs exhibit photoluminescence (PL) around 600 nm (Figure 3a). [10,11,14] Here,N i doping can enhance the PL around 600 nm ( Figure S8), as more photoexcited electrons are transferred to the surface This argument is supported by the PL spectra collected in the presence of methyl viologen (MV 2+ ), an agent to sacrifice surface electrons of QDs,w hich display aw eak emission peak for radiative recombination in the bulk at 500-550 nm (Figure 3b).…”

mentioning

confidence: 78%

“…[10,11,14] In ap ractical photocatalytic CO 2 reduction, the photoexcited electrons trapped at surface Ni sites would participate in reactions with Ni atoms as the catalytic centers. [10,11,14] In ap ractical photocatalytic CO 2 reduction, the photoexcited electrons trapped at surface Ni sites would participate in reactions with Ni atoms as the catalytic centers.…”

Section: Angewandte Chemiementioning

confidence: 99%

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Enabling Visible‐Light‐Driven Selective CO₂ Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H₂ Evolution

et al. 2018

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Quantum dots (QDs), ac lass of promising candidates for harvesting visible light, generally exhibit low activity and selectivity towards photocatalytic CO 2 reduction. Functionalizing QDs with metal complexes (or metal cations through ligands) is aw idely used strategy for improving their catalytic activity;h owever,t he resulting systems still suffer from lowselectivity and stability in CO 2 reduction. Herein, we report that doping CdS QDs with transition-metal sites can overcome these limitations and provideasystem that enables highly selective photocatalytic reactions of CO 2 with H 2 O (100 %s electivity to CO and CH 4 ), with excellent durability over 60 h. Doping Ni sites into the CdS lattice leads to effective trapping of photoexcited electrons at surface catalytic sites and substantial suppression of H 2 evolution. The method reported here can be extended to various transition-metal sites,a nd offers new opportunities for exploring QD-based earth-abundant photocatalysts.

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confidence: 78%

Section: Angewandte Chemiementioning

confidence: 99%

Enabling Visible‐Light‐Driven Selective CO₂ Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H₂ Evolution

et al. 2018

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“…In spite of great progresses, it is complicated to fabricate composite electronic transport layers (ETLs) with matched crystal lattices and energy levels, otherwise the newly formed interface in the composite may bring about large amounts of defects which act as trap sites and recombination centers.Spatially graded composition (bandgap) is an effective route to continuously tune energy levels and bandgap in semiconductors, [20,21] in which the interfacial recombination is alleviated or removed and a graded built-in potential through the whole bulk is produced, enabling stronger separation capability of photogenerated electron-hole pairs. In spite of great progresses, it is complicated to fabricate composite electronic transport layers (ETLs) with matched crystal lattices and energy levels, otherwise the newly formed interface in the composite may bring about large amounts of defects which act as trap sites and recombination centers.…”

mentioning

confidence: 99%

“…Spatially graded composition (bandgap) is an effective route to continuously tune energy levels and bandgap in semiconductors, [20,21] in which the interfacial recombination is alleviated or removed and a graded built-in potential through the whole bulk is produced, enabling stronger separation capability of photogenerated electron-hole pairs. This concept provides a new platform for designing high-performance optoelectronic devices.…”

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confidence: 99%

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

et al. 2019

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possess lower dark currents and higher detectivities. In spite of great progresses, it is complicated to fabricate composite electronic transport layers (ETLs) with matched crystal lattices and energy levels, otherwise the newly formed interface in the composite may bring about large amounts of defects which act as trap sites and recombination centers.Spatially graded composition (bandgap) is an effective route to continuously tune energy levels and bandgap in semiconductors, [20,21] in which the interfacial recombination is alleviated or removed and a graded built-in potential through the whole bulk is produced, enabling stronger separation capability of photogenerated electron-hole pairs. This concept provides a new platform for designing high-performance optoelectronic devices. For example, Krol and co-workers fabricated the gradient W-doped BiVO 4 as a photoanode of photoelectrochemical cell. [22] Compared to the homogeneously doped BiVO 4 , the continuous built-in band bending induces the directional transfer of photogenerated holes from core to surface and thus increases the carrier separation efficiency to 60%. Tailoring the gradient bandgap from 0.35 to 1.42 eV, Pan and co-workers synthesized InAs x P 1-x nanosheets for band-selective infrared photodetectors. [23] We reported graded CdS x Se 1-x nanobelt solar cells by utilizing continuous stepped energy levels to drive electrons and holes toward opposite direction. [24] In p-i-n structured devices, [25][26][27][28] graded composition (bandgap) is basically used in the main photosensitive layer, for which the narrow bandgap region increases the absorption wavelength range, the large bandgap results in a high voltage output, and graded bandgap structure promotes the carriers transport. Inspired by previous results, with the introduction of gradient built-in band bending at the charge extraction layer/perovskite interface, the energy band offset is expected to provide the driving force for enhanced carrier separation, suppressed electron reflux, and reduced recombination, boosting the performance of perovskite photodetectors.In this work, we present a high-performance self-powered photodetector by integrating perovskite with gradient O-doped CdS nanorod array. For the first time, the continuous builtin band bending is introduced at the charge extraction layer/ perovskite interface to manipulate the transfer behavior of carriers in perovskite photodetectors. The optoelectronic measurements reveal that both the responsivity and the response speed of devices strongly depend on the structure of energy band bending. The optimum gradient O-doped CdS/perovskite Self-powered photodetectors are highly desired to meet the great demand in applications of sensing, communication, and imaging. Manipulating the carrier separation and recombination is critical to achieve high performance. In this paper, a self-powered photodetector based on the integrated gradient O-doped CdS nanorod array and perovskite is presented. Through optimizing the degree of continuous built-in ba...

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“…[6][7][8][9] The PEC application of CdS has been intensively studied. [20] Numerous modification methods have been employed to enhance the PEC activity and stability of CdS photoanode, including morphology manipulation, [23][24][25] doping [15,26] and heterojunction construction. Moreover, CdS suffers from serious photocorrosion under illumination because the photogenerated holes induce the self-oxidization of S 2À .…”

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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Oriented Built-in Electric Field Introduced by Surface Gradient Diffusion Doping for Enhanced Photocatalytic H₂ Evolution in CdS Nanorods

Cited by 232 publications

References 28 publications

Enabling Visible‐Light‐Driven Selective CO₂ Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H₂ Evolution

Enabling Visible‐Light‐Driven Selective CO₂ Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H₂ Evolution

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

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

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Oriented Built-in Electric Field Introduced by Surface Gradient Diffusion Doping for Enhanced Photocatalytic H2 Evolution in CdS Nanorods

Cited by 232 publications

References 28 publications

Enabling Visible‐Light‐Driven Selective CO2 Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H2 Evolution

Enabling Visible‐Light‐Driven Selective CO2 Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H2 Evolution

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

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

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Resources

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Oriented Built-in Electric Field Introduced by Surface Gradient Diffusion Doping for Enhanced Photocatalytic H₂ Evolution in CdS Nanorods

Enabling Visible‐Light‐Driven Selective CO₂ Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H₂ Evolution

Enabling Visible‐Light‐Driven Selective CO₂ Reduction by Doping Quantum Dots: Trapping Electrons and Suppressing H₂ Evolution

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