Themed collection Nanocatalysis

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Minireview

Single and dual-atom catalysts towards electrosynthesis of ammonia and urea: a review

Illustration of atomic catalysts in five different reactions: nitrogen reduction, nitrate reduction, nitrite reduction, nitric oxide reduction and urea synthesis. Advantages of diatom catalysts include those of single atom catalysts.

Graphical abstract: Single and dual-atom catalysts towards electrosynthesis of ammonia and urea: a review
From the themed collection: Recent Review Articles
Minireview

Light switching for product selectivity control in photocatalysis

Artificial switchable catalysis is a new, rapidly expanding field that offers great potential advantages for both homogeneous and heterogeneous catalytic systems.

Graphical abstract: Light switching for product selectivity control in photocatalysis
From the themed collection: Recent Review Articles
Minireview

Recent advances in photoelectrochemical hydrogen production using I–III–VI quantum dots

This minireview covers recent advances in photoelectrochemical hydrogen production using I–III–VI QDs, detailing the material design strategies.

Graphical abstract: Recent advances in photoelectrochemical hydrogen production using I–III–VI quantum dots
From the themed collection: Recent Review Articles
Open Access Minireview

Atomically precise Au and Ag nanoclusters doped with a single atom as model alloy catalysts

This minireview focuses on single-atom doping effects on thermal catalysis, electrocatalysis, and photocatalysis of atomically precise gold or silver nanoclusters.

Graphical abstract: Atomically precise Au and Ag nanoclusters doped with a single atom as model alloy catalysts
From the themed collection: Recent Review Articles
Open Access Review Article

Structurally and surficially activated TiO2 nanomaterials for photochemical reactions

This review highlights recent advancements in TiO2 photocatalysts, emphasizing key strategies to enhance their performance for environmental remediation and energy conversion technologies.

Graphical abstract: Structurally and surficially activated TiO2 nanomaterials for photochemical reactions
From the themed collection: Recent Review Articles
Review Article

Recent advances in developing nanoscale electro-/photocatalysts for hydrogen production: modification strategies, charge-carrier characterizations, and applications

For clean hydrogen (H2) production, electrocatalysis and photocatalysis are widely regarded as promising technologies to counter the increasing energy crisis.

Graphical abstract: Recent advances in developing nanoscale electro-/photocatalysts for hydrogen production: modification strategies, charge-carrier characterizations, and applications
From the themed collection: Recent Review Articles
Review Article

Advances in MXene surface functionalization modification strategies for CO2 reduction

Progress in the study of MXenes for electrocatalytic carbon dioxide reduction.

Graphical abstract: Advances in MXene surface functionalization modification strategies for CO2 reduction
From the themed collection: Recent Review Articles
Review Article

High-entropy-based nano-materials for sustainable environmental applications

A comprehensive overview of high entropy materials (HEMs), encompassing their sustainable energy and environmental applications.

Graphical abstract: High-entropy-based nano-materials for sustainable environmental applications
From the themed collection: Recent Review Articles
Communication

Unravelling the origin of reaction-driven aggregation and fragmentation of atomically dispersed Pt catalyst on ceria support

CO-induced fragmentation of platinum nanoparticles on undercoordinated ceria support.

Graphical abstract: Unravelling the origin of reaction-driven aggregation and fragmentation of atomically dispersed Pt catalyst on ceria support
From the themed collection: Nanocatalysis
Communication

Chemically synthesized poly(3,4-ethylenedioxythiophene) conducting polymer as a robust electrocatalyst for highly efficient dye-sensitized solar cells

PEDOT counter electrodes, optimized via spin-coating a DMSO-dispersed solution from scalable synthesis, were evaluated for cobalt reduction in dye-sensitized solar cells. PEDOT was a superior electrocatalyst compared to Pt.

Graphical abstract: Chemically synthesized poly(3,4-ethylenedioxythiophene) conducting polymer as a robust electrocatalyst for highly efficient dye-sensitized solar cells
From the themed collection: Nanocatalysis
Open Access Communication

Controlling nanoparticle placement in Au/TiO2 inverse opal photocatalysts

Nanoparticle placement in gold-loaded titania (Au/TiO2) inverse opals impacts photocatalytic activity and stability.

Graphical abstract: Controlling nanoparticle placement in Au/TiO2 inverse opal photocatalysts
From the themed collection: Nanocatalysis
Communication

Cu–Pd bimetal-decorated siloxene nanosheets for semi-hydrogenation of acetylene

High-surface-area siloxene enables alloying between Pd and Cu via room-temperature reduction with Si–H bonds. This catalyst preparation strategy outperformed the traditional impregnation method for catalytic semi-hydrogenation of acetylene.

Graphical abstract: Cu–Pd bimetal-decorated siloxene nanosheets for semi-hydrogenation of acetylene
From the themed collection: Nanocatalysis
Communication

Universal pH electrocatalytic hydrogen evolution with Au-based high entropy alloys

The synthesis of AuPdFeNiCo high entropy alloy nanoparticles is reported. These nanoparticles exhibit robust hydrogen evolution activity quantified over a broad pH range, with higher activity than any of the unary metal counterparts.

Graphical abstract: Universal pH electrocatalytic hydrogen evolution with Au-based high entropy alloys
From the themed collection: Nanocatalysis
Communication

Atomically thin iridium nanosheets for oxygen evolution electrocatalysis

A one-pot solvothermal synthesis route to prepare freestanding ultrathin Ir nanosheets with atomic thickness for oxygen evolution electrocatalysis was developed.

Graphical abstract: Atomically thin iridium nanosheets for oxygen evolution electrocatalysis
From the themed collection: Nanocatalysis
Open Access Communication

Consecutive one-pot alkyne semihydrogenation/alkene dioxygenation reactions by Pt(II)/Cu(II) single-chain nanoparticles in green solvent

Bimetallic single-chain nanoparticles allow two consecutive one-pot (incompatible) reactions to be performed at room temperature in N-butylpyrrolidone.

Graphical abstract: Consecutive one-pot alkyne semihydrogenation/alkene dioxygenation reactions by Pt(ii)/Cu(ii) single-chain nanoparticles in green solvent
From the themed collection: Nanocatalysis
Open Access Accepted Manuscript - Paper

Biomass-derived substrates hydrogenation over Rhodium Nanoparticles Supported on Functionalized Mesoporous Silica

From the themed collection: Nanocatalysis
Paper

Tuning the product selectivity of single-atom catalysts for CO2 reduction beyond CO formation by orbital engineering

Orbital engineering by axial ligands offers promising strategies to tune the catalytic activity and product selectivity of single-atom catalysts (SACs) with 3d transition metal dopants (Fe, Co, Ni) for CO2 reduction reaction.

Graphical abstract: Tuning the product selectivity of single-atom catalysts for CO2 reduction beyond CO formation by orbital engineering
From the themed collection: Nanocatalysis
Open Access Paper

Hydrothermal synthesis of metal nanoparticles@hydrogels and statistical evaluation of reaction conditions’ effects on nanoparticle morphologies

We report a hydrothermal one-pot approach using polysaccharides and salt precursors to synthesize and selectively localize metal nanoparticles in hydrogels, leveraging multivariate regression fits to further evaluate synthesis parameter effects.

Graphical abstract: Hydrothermal synthesis of metal nanoparticles@hydrogels and statistical evaluation of reaction conditions’ effects on nanoparticle morphologies
From the themed collection: Nanocatalysis
Open Access Paper

The influence of bulk stoichiometry on near-ambient pressure reactivity of bare and Pt-loaded rutile TiO2(110)

The stoichiometry of rutile TiO2 supports determines whether platinum particles will become encapsulated, and drastically affects the TiO2 reactivity even in the absence of platinum.

Graphical abstract: The influence of bulk stoichiometry on near-ambient pressure reactivity of bare and Pt-loaded rutile TiO2(110)
From the themed collection: Nanocatalysis
Paper

Nanostructured electroless Ni deposited SnO2 for solar hydrogen production

Herein, Ni-decorated SnO2 (Ni@SnO2) nanostructures have been synthesized over SnO2 nanoparticles via a simple electroless deposition method for the generation of hydrogen, a potent near-future fuel.

Graphical abstract: Nanostructured electroless Ni deposited SnO2 for solar hydrogen production
From the themed collection: Nanocatalysis
Paper

A silver cluster-assembled material as a matrix for enzyme immobilization towards a highly efficient biocatalyst

This study reports the designed construction of a novel (3,6)-connected two-dimensional silver cluster-assembled material leveraged, for the first time, as a support matrix for enzyme immobilization.

Graphical abstract: A silver cluster-assembled material as a matrix for enzyme immobilization towards a highly efficient biocatalyst
From the themed collection: Nanocatalysis
Open Access Paper

Atomically dispersed Co-based species containing electron withdrawing groups for electrocatalytic oxygen reduction reactions

A new hybrid material, composed of atomically dispersed Co species containing electron-withdrawing CF3 groups and N-doped reduced graphene oxide, shows excellent electrocatalytic properties for electrochemical oxygen reduction reaction.

Graphical abstract: Atomically dispersed Co-based species containing electron withdrawing groups for electrocatalytic oxygen reduction reactions
From the themed collection: Nanocatalysis
Paper

Achieving a balance of rapid Zn2+ desolvation and hydrogen evolution reaction inertia at the interface of the Zn anode

It is difficult to achieve fast kinetics of Zn2+(H2O)6 desolvation as well as HER inertia at the same electrolyte/Zn interface during long-term cycling of Zn plating/stripping in aqueous Zn-ion batteries.

Graphical abstract: Achieving a balance of rapid Zn2+ desolvation and hydrogen evolution reaction inertia at the interface of the Zn anode
From the themed collection: Nanocatalysis
Open Access Paper

Support effect on Ni-based mono- and bimetallic catalysts in CO2 hydrogenation

Zirconia- and ceria-supported Ni,Fe catalysts show higher activity than MgO-supported catalysts in CO2 hydrogenation. This effect is due to differences in reducibility and oxygen vacancy formation resulting in modified metal-support interactions.

Graphical abstract: Support effect on Ni-based mono- and bimetallic catalysts in CO2 hydrogenation
From the themed collection: Nanocatalysis
Paper

Amino-functionalization enhanced CO2 reduction reaction in pure water

Amino groups can enhance the adsorption of CO2 and also be protonated to adsorb protons, this property makes amino-modification highly effective in improving the CO2RR performance of the catalyst in zero-gap CO2 electrolyzers utilizing pure water.

Graphical abstract: Amino-functionalization enhanced CO2 reduction reaction in pure water
From the themed collection: Nanocatalysis
Paper

Aminotriazine derived N-doped mesoporous carbon with a tunable nitrogen content and their improved oxygen reduction reaction performance

Mesoporous N-doped carbon with a tunable nitrogen content showed excellent performance for oxygen reduction due to the pyridinic/graphitic nitrogen and structural defects, offering a promising strategy for designing electrocatalysts.

Graphical abstract: Aminotriazine derived N-doped mesoporous carbon with a tunable nitrogen content and their improved oxygen reduction reaction performance
From the themed collection: 2024 Nanoscale HOT Article Collection
Paper

Surface effects on functional amyloid formation

Fibril nucleation during protein aggregation is a heterogeneous process highly dependent on the surfaces present during the process.

Graphical abstract: Surface effects on functional amyloid formation
From the themed collection: Nanocatalysis
Paper

Improved electrochemical reduction of CO2 to syngas with a highly exfoliated Ti3C2Tx MXene–gold composite

Transforming carbon dioxide (CO2) into valuable chemicals via electroreduction presents a sustainable and viable approach to mitigating excess CO2 in the atmosphere.

Graphical abstract: Improved electrochemical reduction of CO2 to syngas with a highly exfoliated Ti3C2Tx MXene–gold composite
From the themed collection: Nanocatalysis
Paper

Mechanistic study of the competition between carbon dioxide reduction and hydrogen evolution reaction and selectivity tuning via loading single-atom catalysts on graphitic carbon nitride

We computationally screened metal-single-atom catalysts (M-SAC) on carbon nitride for selective CO2 reduction. NiCN significantly lowered the rate-determining potential for CO2 conversion to formic acid via the *OCHO key intermediate.

Graphical abstract: Mechanistic study of the competition between carbon dioxide reduction and hydrogen evolution reaction and selectivity tuning via loading single-atom catalysts on graphitic carbon nitride
From the themed collection: Nanocatalysis
Paper

Effect of design parameters in nanocatalyst synthesis on pyrolysis for producing diesel-like fuel from waste lubricating oil

Synthesis parameters in catalyst preparation indirectly affect catalytic processes in pyrolysis. Some parameters and their interactions impact product quality and quantity, while others do not.

Graphical abstract: Effect of design parameters in nanocatalyst synthesis on pyrolysis for producing diesel-like fuel from waste lubricating oil
From the themed collection: Nanocatalysis
Open Access Paper

Fluorinated polymer zwitterions on gold nanoparticles: patterned catalyst surfaces guide interfacial transport and electrochemical CO2 reduction

We report the use of fluorinated polymer zwitterions to build hybrid systems for efficient CO2 electroreduction.

Graphical abstract: Fluorinated polymer zwitterions on gold nanoparticles: patterned catalyst surfaces guide interfacial transport and electrochemical CO2 reduction
From the themed collection: Nanocatalysis
Open Access Paper

In situ evolution of bulk-active γ-CoOOH with immobilized Gd dopants enabling efficient oxygen evolution electrocatalysis

Immobilized Gd dopants induced deep reconstruction of α-Co(OH)2 during alkaline OER into γ-CoOOH with modified crystallinity and electronic structure. Thus, the bulk and intrinsic activity was enhanced, boosting the resulting OER performance.

Graphical abstract: In situ evolution of bulk-active γ-CoOOH with immobilized Gd dopants enabling efficient oxygen evolution electrocatalysis
From the themed collection: Nanocatalysis
Paper

Design and fabrication of intermetallic NiCo electrocatalysts for the alkaline HER

The intermetallic L10-NiCo electrocatalysts play a crucial role in reducing energy consumption, improving hydrogen production rates, and prolonging the service life of alkaline electrolyzers.

Graphical abstract: Design and fabrication of intermetallic NiCo electrocatalysts for the alkaline HER
From the themed collection: Nanocatalysis
Paper

A seed-like structured Mo@ZrS2 catalyst on graphene nanosheets for boosting the performance of rechargeable Zn–air batteries

A seed-like structured Mo@ZrS2 catalyst was synthesised on graphene nanosheets by a simple hydrothermal and annealing method to achieve the ORR and high performance Zn–air batteries.

Graphical abstract: A seed-like structured Mo@ZrS2 catalyst on graphene nanosheets for boosting the performance of rechargeable Zn–air batteries
From the themed collection: Nanocatalysis
Open Access Paper

Iron oxide nanozymes enhanced by ascorbic acid for macrophage-based cancer therapy

This study reveals unique pH-dependent behaviors of IONPs and ascorbic acid, paving the way for a macrophage-based cell therapy.

Graphical abstract: Iron oxide nanozymes enhanced by ascorbic acid for macrophage-based cancer therapy
From the themed collection: Nanocatalysis
Paper

Novel nitrogen-doped carbon-coated SnSe2 based on a post-synthetically modified MOF as a high-performance anode material for LIBs and SIBs

Carbon-coated SnSe2/C–N composites with optimized hetero-atom doping and electrical conductivity exhibit superior electrochemical performance in lithium-ion batteries and sodium-ion batteries.

Graphical abstract: Novel nitrogen-doped carbon-coated SnSe2 based on a post-synthetically modified MOF as a high-performance anode material for LIBs and SIBs
From the themed collection: Nanocatalysis
Paper

Ferroelectric modulation of CuCo2O4 nanorods for controllable alkaline water electrolysis

Polarized CuCo2O4 nanorods exhibit excellent electrocatalytic water-splitting performance due to their large surface areas and fast electron transfer.

Graphical abstract: Ferroelectric modulation of CuCo2O4 nanorods for controllable alkaline water electrolysis
From the themed collection: Nanocatalysis
Paper

ZIF-67-derived Co–N–C supported nickel cobalt sulfide as a bifunctional electrocatalyst for sustainable hydrogen production via alkaline electrolysis

This study introduces two efficient electrode materials, NF@ZIF-67@NiCo2S4 and NF@Co–N–C@NiCo2S4, for H2 production, achieving excellent OER, HER and overall water splitting activities with remarkable durability in an alkaline electrolyzer.

Graphical abstract: ZIF-67-derived Co–N–C supported nickel cobalt sulfide as a bifunctional electrocatalyst for sustainable hydrogen production via alkaline electrolysis
From the themed collection: Nanocatalysis
Paper

Polyoxometalate-HKUST-1 composite derived nanostructured Na–Cu–Mo2C catalyst for efficient reverse water gas shift reaction

Transforming CO2 to CO via reverse water–gas shift (RWGS) reaction is widely regarded as a promising technique for improving the efficiency and economics of CO2 utilization processes.

Graphical abstract: Polyoxometalate-HKUST-1 composite derived nanostructured Na–Cu–Mo2C catalyst for efficient reverse water gas shift reaction
From the themed collection: Nanocatalysis
Paper

Conductivity-mediated in situ electrochemical reconstruction of CuOx for nitrate reduction to ammonia

CP/CuOx with suitable copper valence states obtained by fine-tuning the conductivity of electrochemical reconstruction may provide a competitive cathode catalyst for achieving excellent activity and selectivity of NO3-to-NH3 conversion.

Graphical abstract: Conductivity-mediated in situ electrochemical reconstruction of CuOx for nitrate reduction to ammonia
From the themed collection: Nanocatalysis
Paper

Determining the orderliness of carbon materials with nanoparticle imaging and explainable machine learning

We propose a set of features for the ordered arrangement of palladium nanoparticles that are consistent with the intuitive understanding of researchers and allow quantification of the data in terms of easily interpretable physical parameters.

Graphical abstract: Determining the orderliness of carbon materials with nanoparticle imaging and explainable machine learning
From the themed collection: Nanocatalysis
Open Access Paper

Efficient plasmonic water splitting by heteroepitaxial junction-induced faceting of gold nanoparticles on an anatase titanium(IV) oxide nanoplate array electrode

Faceting of Au NPs is induced by a heteroepitaxial junction on anatase TiO2(001) nanoplate array. Light irradiation of the plasmonic electrode generates current for water oxidation at λ < 900 nm with a maximum efficiency of 0.39% at λ = 600 nm.

Graphical abstract: Efficient plasmonic water splitting by heteroepitaxial junction-induced faceting of gold nanoparticles on an anatase titanium(iv) oxide nanoplate array electrode
From the themed collection: Nanocatalysis
Paper

Efficient CO2 electroreduction to ethanol enabled by tip-curvature-induced local electric fields

A CuO nanoflower catalyst with tip curvature exhibited remarkable performance toward CO2 to ethanol conversion. The exceptional ethanol selectivity was attributed to the enhanced *OH adsorption due to the tip-curvature-induced local electric fields.

Graphical abstract: Efficient CO2 electroreduction to ethanol enabled by tip-curvature-induced local electric fields
From the themed collection: Nanocatalysis
Paper

Theoretical insights into single-atom catalysts for improved charging and discharging kinetics of Na–S and Na–Se batteries

Density functional theory simulations were employed to investigate the charging and discharging kinetics of Na–S and Na–Se electrodes by utilizing single transition metal atoms supported on reduced graphitic carbon nitride surfaces.

Graphical abstract: Theoretical insights into single-atom catalysts for improved charging and discharging kinetics of Na–S and Na–Se batteries
From the themed collection: Nanocatalysis
Paper

Electron repulsion tuned electronic structure of TiO2 by fluorination for efficient and selective photocatalytic ammonia generation

Through the regulation of electronic structure and optimization of hydrophobicity, two types of fluorine modification (fluorine doping and surface fluorination) have respectively enhanced nitrogen activation and selectivity during nitrogen fixation.

Graphical abstract: Electron repulsion tuned electronic structure of TiO2 by fluorination for efficient and selective photocatalytic ammonia generation
From the themed collection: Nanocatalysis
Open Access Paper

Tuneable C3 product selectivity of glycerol electrooxidation on cubic and dendritic Pt nanocatalysts

The glycerol electrooxidation reaction's C3 product selectivity and glycerol conversion in an alkaline medium are more efficient on PtCUBE than on PtDEND, with lactate selectivity reaching up to 68%.

Graphical abstract: Tuneable C3 product selectivity of glycerol electrooxidation on cubic and dendritic Pt nanocatalysts
From the themed collection: Nanocatalysis
Paper

Nanostructured cobalt/copper catalysts for efficient electrochemical carbon dioxide reduction

Self-supported Co/Cu nanodendrites with high catalytic activity were designed for electrochemical reduction of CO2. The influences of the composition and structure on their efficiency as well as the reduction reaction mechanism were studied.

Graphical abstract: Nanostructured cobalt/copper catalysts for efficient electrochemical carbon dioxide reduction
From the themed collection: Nanocatalysis
Paper

g-C3N4 nanosheet supported NiCo2O4 nanoparticles for boosting degradation of tetracycline under visible light and ultrasonic irradiation

High-energy ball milling enables the integration of NiCo2O4 nanoparticles with g-C3N4 nanosheets for boosting catalytic degradation of tetracycline under visible light and ultrasonic irradiation.

Graphical abstract: g-C3N4 nanosheet supported NiCo2O4 nanoparticles for boosting degradation of tetracycline under visible light and ultrasonic irradiation
From the themed collection: Nanocatalysis
Paper

Ru doping and interface engineering synergistically boost the electrocatalytic performance of a WP/WP2 nanosheet array for an efficient hydrogen evolution reaction

The surface electronic structure and morphology of catalysts have a crucial impact on the electrocatalytic hydrogen evolution reaction performance.

Graphical abstract: Ru doping and interface engineering synergistically boost the electrocatalytic performance of a WP/WP2 nanosheet array for an efficient hydrogen evolution reaction
From the themed collection: Nanocatalysis
Open Access Paper

Engineering high-valence metal-enriched cobalt oxyhydroxide catalysts for an enhanced OER under near-neutral pH conditions

Optimized two-dimensional Mo–Co(OH)2 nanosheets undergoing operando transformation into oxyhydroxide active species demonstrated high oxygen evolution reaction (OER) performance in a near-neutral-pH electrolyte.

Graphical abstract: Engineering high-valence metal-enriched cobalt oxyhydroxide catalysts for an enhanced OER under near-neutral pH conditions
From the themed collection: Nanocatalysis
Open Access Paper

Dehydrogenative oxidation of hydrosilanes using gold nanoparticle deposited on citric acid-modified fibrillated cellulose: unveiling the role of molecular oxygen

We developed an efficient and environmentally friendly catalyst, Au:F-CAC, for the dehydrogenative oxidation of hydrosilanes. Detailed analyses revealed that the cationic Au sites generated via the adsorption of oxygen play an important role.

Graphical abstract: Dehydrogenative oxidation of hydrosilanes using gold nanoparticle deposited on citric acid-modified fibrillated cellulose: unveiling the role of molecular oxygen
From the themed collection: Nanocatalysis
Paper

Neodymium niobate nanospheres on functionalized carbon nanofibers: a nanoengineering approach for highly sensitive vanillin detection

Vanillin (VAN), the primary aroma compound in vanilla, contributes significantly to sensory delight; however, its unrestrained presence poses notable health risks.

Graphical abstract: Neodymium niobate nanospheres on functionalized carbon nanofibers: a nanoengineering approach for highly sensitive vanillin detection
From the themed collection: Nanocatalysis
Paper

A novel GO hoisted SnO2–BiOBr bifunctional catalyst for the remediation of organic dyes under illumination by visible light and electrocatalytic water splitting

A novel GO-hoisted SnO2–BiOBr bifunctional catalyst for the remediation of organic dyes under illumination by visible light and electrocatalytic water splitting.

Graphical abstract: A novel GO hoisted SnO2–BiOBr bifunctional catalyst for the remediation of organic dyes under illumination by visible light and electrocatalytic water splitting
Paper

Multifunctional tunable Cu2O and CuInS2 quantum dots on TiO2 nanotubes for efficient chemical oxidation of cholesterol and ibuprofen

(a) TEM image of TNTs decorated with Cu2O and CuInS2 QDs. (b) Amperometric response of different configurations of biosensing electrodes. (c) Cholesterol oxidation mechanism on the surface of the CuInS2/Cu2O/TNT electrode.

Graphical abstract: Multifunctional tunable Cu2O and CuInS2 quantum dots on TiO2 nanotubes for efficient chemical oxidation of cholesterol and ibuprofen
From the themed collection: Nanocatalysis
Paper

Hand-crafted potent hydroxyl-rich husk succoured Fe3O4 @ Cu, Mn, Ni, Co – tetra-metallic heterogenous nanocomposite as a catalytic accelerant

Recoverable ternary nanocomposite (NC) made of Fe3O4 supported on Oryza sativa Husk (OSH) and ornamented with 3d tetra-metals (M = Mn, Co, Ni, Cu) is proposed using a manual grinding method.

Graphical abstract: Hand-crafted potent hydroxyl-rich husk succoured Fe3O4 @ Cu, Mn, Ni, Co – tetra-metallic heterogenous nanocomposite as a catalytic accelerant
From the themed collection: Nanocatalysis
Open Access Paper

Hydrodeoxygenation of anisole over SBA-15-supported Ni, Pd, and Pt mono- and bimetallic catalysts: effect of the metal's nature on catalytic activity and selectivity

NiPt/SBA-15 and NiPd/SBA-15 catalysts were active for hydrodeoxygenation of anisole to cyclohexane, while PdPt/SBA-15 was active for hydrogenation of anisole to cyclohexyl methyl ether.

Graphical abstract: Hydrodeoxygenation of anisole over SBA-15-supported Ni, Pd, and Pt mono- and bimetallic catalysts: effect of the metal's nature on catalytic activity and selectivity
From the themed collection: Nanocatalysis
Paper

Enhanced stability of boron modified NiFe hydroxide for oxygen evolution reaction

The introduction of boron into NiFe hydroxide enhances activity and stability for oxygen evolution reaction as it maintains a uniform distribution of Fe species on the active surface through facilitated dissolution and redeposition cycles.

Graphical abstract: Enhanced stability of boron modified NiFe hydroxide for oxygen evolution reaction
From the themed collection: Nanocatalysis
Paper

A suitably fabricated ternary nanocomposite (Cu-CuO@rGO-SiO2) as a sustainable and common heterogeneous catalyst for C–S, C–O and C–N coupling reactions

A unique nanocomposite, Cu-CuO@rGO-SiO2, exhibits enhanced catalytic activity in C–X (X = S, N, O) coupling reactions. The high performance presumably originates from synergism of different co-existing copper species spread over rGO-SiO2 matrices.

Graphical abstract: A suitably fabricated ternary nanocomposite (Cu-CuO@rGO-SiO2) as a sustainable and common heterogeneous catalyst for C–S, C–O and C–N coupling reactions
From the themed collection: Nanocatalysis
Paper

Enhancing the electronic structure of Ni-based electrocatalysts through N element substitution for the hydrogen evolution reaction

The notion of orbital-regulated electronic levels on Ni sites introduces a distinctive methodology for the systematic development of catalysts used in hydrogen evolution and other applications.

Graphical abstract: Enhancing the electronic structure of Ni-based electrocatalysts through N element substitution for the hydrogen evolution reaction
From the themed collection: Nanocatalysis
Paper

Donor–acceptor type triphenylamine-based porous aromatic frameworks (TPA-PAFs) for photosynthesis of benzimidazoles

Two donor–acceptor type triphenylamine-based porous aromatic frameworks (TPA-PAFs) were constructed, which achieved the photocatalytic synthesis of benzimidazoles and their derivatives in high yields under mild conditions.

Graphical abstract: Donor–acceptor type triphenylamine-based porous aromatic frameworks (TPA-PAFs) for photosynthesis of benzimidazoles
From the themed collection: Nanocatalysis
Paper

Lattice capacity-dependent activity for CO2 methanation: crafting Ni/CeO2 catalysts with outstanding performance at low temperatures

A series of Ca2+-doped CeO2 solid solutions with 10 wt% Ni loading (named Ni/CaxCe1−xOy) was used for effective CO2 methanation.

Graphical abstract: Lattice capacity-dependent activity for CO2 methanation: crafting Ni/CeO2 catalysts with outstanding performance at low temperatures
From the themed collection: Nanocatalysis
Open Access Paper

Troubleshooting the influence of trace chemical impurities on nanoparticle growth kinetics via electrochemical measurements

Real-time electrochemical measurements of the solution potential of colloidal nanoparticle syntheses provide a tool for identifying the influence of trace contaminants in nanoparticle growth and shape development.

Graphical abstract: Troubleshooting the influence of trace chemical impurities on nanoparticle growth kinetics via electrochemical measurements
From the themed collection: Nanocatalysis
Paper

Perovskite CoSn(OH)6 nanocubes with tuned d-band states towards enhanced oxygen evolution reactions

An Fe3+ doping strategy is used to optimize the d-band state of the CoSn(OH)6 perovskite hydroxide, which promotes the OER performance of materials.

Graphical abstract: Perovskite CoSn(OH)6 nanocubes with tuned d-band states towards enhanced oxygen evolution reactions
From the themed collection: Nanocatalysis
Paper

Superhydrophobic MOF/polymer composite with hierarchical porosity for boosting catalytic performance in an humid environment

The superhydrophobic nanocomposite with hierarchical porosity was prepared by growing ZIF-8 nanocrystals within PDVB-vim to form ZIF-8/PDVB-vim composite. In an humid environment, the composite exhibits enhanced catalytic activity in Friedel–Crafts reaction.

Graphical abstract: Superhydrophobic MOF/polymer composite with hierarchical porosity for boosting catalytic performance in an humid environment
From the themed collection: Nanocatalysis
Paper

Reactivity control of nitrate-incorporating octadecavanadates by changing the oxidation state and metal substitution

Local structure change of the vanadium-oxygen cluster with nitrate at the center controls the catalytic performance in selective oxidation.

Graphical abstract: Reactivity control of nitrate-incorporating octadecavanadates by changing the oxidation state and metal substitution
From the themed collection: Nanocatalysis
Paper

Easily constructed porous silver films for efficient catalytic CO2 reduction and Zn–CO2 batteries

Porous silver films on a commercial carbon paper with a commercial waterproofer (p-Ag/CP) could be easily fabricated on a large scale and serve as efficient electrocatalysts as well as Zn–CO2 batteries for CO2 reduction to CO.

Graphical abstract: Easily constructed porous silver films for efficient catalytic CO2 reduction and Zn–CO2 batteries
From the themed collection: Nanocatalysis
Paper

Ferroelectric field enhanced tribocatalytic hydrogen production and RhB dye degradation by tungsten bronze ferroelectrics

The BSNT ferroelectric submicron powder tribocatalytic water splitting for hydrogen with rate of 200 μmol/h/g and tribocatalytic degradation of RhB dyes with efficiency 96% in 2 hours, •OH and •O2 play crucial roles in tribocatalysis.

Graphical abstract: Ferroelectric field enhanced tribocatalytic hydrogen production and RhB dye degradation by tungsten bronze ferroelectrics
From the themed collection: Nanocatalysis
Paper

An oxygen vacancy-rich BiO2−x/COF heterojunction for photocatalytic degradation of diclofenac

BiO2−x/COF has abundant oxygen vacancies and photocatalyzes the degradation of diclofenac by forming heterojunctions with ˙O2 and h+ active substances.

Graphical abstract: An oxygen vacancy-rich BiO2−x/COF heterojunction for photocatalytic degradation of diclofenac
From the themed collection: Nanocatalysis
Paper

Bi-directional charge transfer channels in highly crystalline carbon nitride enabling superior photocatalytic hydrogen evolution

Crystalline carbon nitride with bi-directional charge transfer channel (TCCN-K) is prepared. Donor–acceptor units and K intercalation set up a bi-directional charge transfer channel, endowing TCCN-K with a superior photocatalytic hydrogen evolution activity.

Graphical abstract: Bi-directional charge transfer channels in highly crystalline carbon nitride enabling superior photocatalytic hydrogen evolution
From the themed collection: Nanocatalysis
Paper

Catalytic NH3 oxidation affected by the nanometric roughness of the platinum overlayer

The nanometric smoothness of the Pt overlayer achieved more than 10-fold greater TOF compared to the rough Pt surface.

Graphical abstract: Catalytic NH3 oxidation affected by the nanometric roughness of the platinum overlayer
From the themed collection: Nanocatalysis
80 items - Showing page 1 of 2

About this collection

Guest edited by Professor In Young Kim (Ewha Womans University, South Korea), Professor Michelle Personick (University of Virginia, USA), and Professor Zhiqun Lin (National University of Singapore, Singapore).

Nanocatalysis represents an exciting subfield in nanoscience and nanotechnology which involves the use of nanomaterials and subnano-sized materials (nanoclusters, diatoms, single atoms) as catalysts for a wide variety of homogeneous and heterogeneous catalytic applications. Along with significant advances in nanomaterial design and synthesis assisted by machine learning, in-situ/ex-situ characterization techniques, and computational chemistry, the past several decades have witnessed a flood of research activities in this rapidly evolving area with most of the studies focusing on the effects of size, shape, chemical composition and morphology on catalytic properties and performance. This has led to the development of highly effective catalysts with enhanced activity, selectivity, and stability.

This special themed collection aims to provide a platform to showcase the recent progress and challenges in the field of nanocatalysis. The scope of the collection is broad covering novel design and synthesis strategies, homogeneous and heterogeneous catalysis, theoretical understanding of the catalytic mechanisms, reaction pathway optimization, nanointerface engineering, support effects, dynamic evolution of active sites, advanced characterization techniques and covers applications in electrocatalysis, photocatalysis, photoelectrocatalysis, and thermocatalysis. We hope that readers find this themed collection informative and useful for the rational design and construction of highly efficient nanocatalysts to enable sustainable technologies for catalysis.

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