Enhanced Photoelectrochemical Water Splitting by Surface Modified Electrodeposited n‐Cu<sub>2</sub>O Thin Films

Kafi, F. S. B.; Wijesundera, R.P.; Siripala, W.

doi:10.1002/pssa.202000330

Cited by 8 publications

(9 citation statements)

References 30 publications

(49 reference statements)

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“…[ 125–128 ] Semiconductor films like Fe 2 O 3 , TiO 2 , BiVO 4, and Cu 2 O are widely utilized in photoelectrochemical (PEC) water splitting electrodes due to their high light‐harvesting ability. [ 129–136 ] Facile control of thickness and morphology through the electrodeposition method can effectively adjust the dynamics of film appropriate for boosting PEC performance. For instance, Lee et al.…”

Section: Applicationsmentioning

confidence: 99%

“…[125][126][127][128] Semiconductor films like Fe 2 O 3 , TiO 2 , BiVO 4, and Cu 2 O are widely utilized in photoelectrochemical (PEC) water splitting electrodes due to their high light-harvesting ability. [129][130][131][132][133][134][135][136] Facile control of thickness and morphology through the electrodeposition method can effectively adjust the dynamics of film appro-priate for boosting PEC performance. For instance, Lee et al reported the effect of electrodeposited NiO x /Ni nanoparticles coverage and crystallinity on the PEC characteristics of NiO x /Ni/n-Si photoanodes.…”

Section:  Photoelectrodesmentioning

confidence: 99%

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Nanoscale electrodeposition: Dimension control and 3D conformality

et al. 2021

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Electrodeposition with a long history has been considered one of the important synthesis techniques for applying various applications. It is a feasible route for fabricating nanostructures using diverse materials due to its simplicity, cost‐effectiveness, flexibility, and ease of reaction control. Herein, we mainly focus on the nanoscale electrodeposition with respect to dimension control and three‐dimensional (3D) conformality. The principles of electrodeposition, dimensional design of materials, and uniform coatings on various substrates are presented. We introduce that manipulating synthesis parameters such as precursors, applied current/voltage, and additives affect the synthesis reaction, resulting in not only dimensional control of materials from three‐dimensional structures to zero‐dimensional atomic‐level but also conformal coatings on complicated substrates. Various cases regarding morphology control of metal (hydro)oxides, metals, and metal–organic frameworks according to electrodeposition conditions are summarized. Lastly, recent studies of applications such as batteries, photoelectrodes, and electrocatalysts using electrodeposited materials are summarized. This review represents significant advances in the nanoscale design of materials through methodological approaches, which are highly attractive from both academic and commercial aspects.

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Section: Applicationsmentioning

confidence: 99%

Section:  Photoelectrodesmentioning

confidence: 99%

Nanoscale electrodeposition: Dimension control and 3D conformality

et al. 2021

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“…Titanium and copper were studied here; TiO 2 is a prototypical n‐type oxide, whereas Cu 2 O is one of the few p‐type oxides that forms spontaneously on metals. [ 1 ] However, Cu 2 O formed in the presence of chloride, [ 34,35 ] very thin films in chloride‐free NaOH, [ 36 ] or electrodeposited films [ 37 ] may also become n‐type. Experimentally, anodizing was used to grow oxides anatase TiO 2 and cuprite Cu 2 O with different thickness based on literature procedures (see Supporting Information).…”

Section: Introductionmentioning

confidence: 99%

“…Titanium and copper were studied here; TiO 2 is a prototypical n-type oxide, whereas Cu 2 O is one of the few p-type oxides that forms spontaneously on metals. [1] However, Cu 2 O formed in the presence of chloride, [34,35] very thin films in chloride-free NaOH, [36] or electrodeposited films [37] may also become n-type.…”

Section: Introductionmentioning

confidence: 99%

Photocorrosion of n‐ and p‐Type Semiconducting Oxide‐Covered Metals: Case Studies of Anodized Titanium and Copper

Wilson

Rooij

Jenewein

et al. 2022

Physica Status Solidi (a)

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“…In addition, it offers excellent advantages of diverse morphology, high natural abundance, and a suitable bandgap of 2.2 eV. , However, the photocurrent response of most semiconductors is weaker than that of compound semiconductor materials. Many strategies have been developed to improve the photocurrent response of PEC immunosensors, such as surface modification, surface passivation, morphology control, formation of heterojunction structures, , and metal doping . Among them, heterojunction and metal doping are the foci of semiconductor modification.…”

Section: Introductionmentioning

confidence: 99%

Photoelectrochemical Immunosensor Based on a 1D Fe₂O₃/3D Cd-ZnIn_2.2S_y Heterostructure as a Sensing Platform for Ultrasensitive Detection of Neuron-Specific Enolase

et al. 2022

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Lung cancer is a high-mortality cancer related to the concentration of neuron-specific enolase (NSE). In this work, a sandwich-type photoelectrochemical (PEC) immunosensor was constructed for ultrasensitive detection of NSE, which is based on iron trioxide/indium zinc cadmium sulfide (Fe2O3/Cd-ZnIn2.2S y ) as a sensing platform and Ag-modified polyaniline (Ag@PANI) as a signal amplification label. The 1D Fe2O3 porous nanorods with a large specific surface area were synthesized by calcination of Fe-MIL-88A and etching of NaOH. To improve the photocurrent response, the 3D architecture Cd-ZnIn2.2S y was combined with the 1D Fe2O3 porous nanorods to form a 1D Fe2O3/3D Cd-ZnIn2.2S y heterostructure. Specifically, the Fe2O3/Cd-ZnIn2.2S y heterostructure with a good energy level matching (the two can form a stepped energy level matching, which accelerates the transfer rate of electrons) can improve the separation efficiency of electron–hole pairs (e–/h+) under visible light irradiation, which enhances the photocurrent response. Ag@PANI has a strong electron transport capability and can be used as a secondary antibody marker for the signal amplification of the immunosensor. The sensor exhibits a good linear detection range of 100 fg/mL to 100 ng/mL with a low detection limit of 33.5 fg/mL. Moreover, the constructed sandwich-type PEC immunosensor shows good performance and possesses excellent specificity, selectivity, and stability over a period of 4 weeks for NSE detection. With these excellent properties, the immunosensor can be extended to analyze and diagnose other disease biomarkers.

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Enhanced Photoelectrochemical Water Splitting by Surface Modified Electrodeposited n‐Cu₂O Thin Films

Cited by 8 publications

References 30 publications

Nanoscale electrodeposition: Dimension control and 3D conformality

Nanoscale electrodeposition: Dimension control and 3D conformality

Photocorrosion of n‐ and p‐Type Semiconducting Oxide‐Covered Metals: Case Studies of Anodized Titanium and Copper

Photoelectrochemical Immunosensor Based on a 1D Fe₂O₃/3D Cd-ZnIn_2.2S_y Heterostructure as a Sensing Platform for Ultrasensitive Detection of Neuron-Specific Enolase

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Enhanced Photoelectrochemical Water Splitting by Surface Modified Electrodeposited n‐Cu2O Thin Films

Cited by 8 publications

References 30 publications

Nanoscale electrodeposition: Dimension control and 3D conformality

Nanoscale electrodeposition: Dimension control and 3D conformality

Photocorrosion of n‐ and p‐Type Semiconducting Oxide‐Covered Metals: Case Studies of Anodized Titanium and Copper

Photoelectrochemical Immunosensor Based on a 1D Fe2O3/3D Cd-ZnIn2.2Sy Heterostructure as a Sensing Platform for Ultrasensitive Detection of Neuron-Specific Enolase

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Product

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Enhanced Photoelectrochemical Water Splitting by Surface Modified Electrodeposited n‐Cu₂O Thin Films

Photoelectrochemical Immunosensor Based on a 1D Fe₂O₃/3D Cd-ZnIn_2.2S_y Heterostructure as a Sensing Platform for Ultrasensitive Detection of Neuron-Specific Enolase