Themed collection Nanomaterials for a sustainable future: From materials to devices and systems

55 items
Accepted Manuscript - Review Article

Advances in Direct Optical Lithography of Nanomaterials

Review Article

Boosting the efficiency of electrocatalytic water splitting via in situ grown transition metal sulfides: a review

This review provides an in-depth analysis of the key aspects related to in situ grown TMS electrodes, including the selection of TMS active materials, various substrates, and materials engineering.

Graphical abstract: Boosting the efficiency of electrocatalytic water splitting via in situ grown transition metal sulfides: a review
From the themed collection: Journal of Materials Chemistry A HOT Papers
Review Article

Biocompatible triboelectric energy generators (BT-TENGs) for energy harvesting and healthcare applications

Bio-implantable triboelectric nanogenerators for future medical applications.

Graphical abstract: Biocompatible triboelectric energy generators (BT-TENGs) for energy harvesting and healthcare applications
Review Article

Engineered diatomic catalyst empowered electro-Fenton processes for advanced water purification

This work introduces the selection and preparation of DACs for the 2 + 1e ORR EF process and concludes with a discussion on challenges and future directions for the intelligent design of electrodes and reactors in EF purification technologies.

Graphical abstract: Engineered diatomic catalyst empowered electro-Fenton processes for advanced water purification
Review Article

Improving supercapacitor electrode performance with electrospun carbon nanofibers: unlocking versatility and innovation

Electrospun carbon nanofibers provide electrode materials with customizable structures for supercapacitors.

Graphical abstract: Improving supercapacitor electrode performance with electrospun carbon nanofibers: unlocking versatility and innovation
Review Article

Nanoscale halide perovskites for photocatalytic CO2 reduction: product selectivity, strategies implemented, and charge-carrier separation

This review summarizes recent advances and provides a comprehensive discussion on nanoscale halide perovskites (NHPs) CO2 photocatalysis, including product selectivity, retrofitting strategies, and charge transport mechanism characterization.

Graphical abstract: Nanoscale halide perovskites for photocatalytic CO2 reduction: product selectivity, strategies implemented, and charge-carrier separation
Communication

Frustrated van der Waals heterostructures

Geometrical frustration results from the packing of constituents in a lattice, where the constituents have conflicting forces.

Graphical abstract: Frustrated van der Waals heterostructures
Communication

Repurposing an antimicrobial peptide for the development of a dual ion channel/molecular receptor-like platform for metal ion detection

A system is proposed for inorganic Hg2+ sensing, based on modified alamethicin tethered with a thymine-rich peptide nucleic acid moiety, capable of generating ion channel oligomers whose activity is thymine–Hg2+–thymine complexation dependent.

Graphical abstract: Repurposing an antimicrobial peptide for the development of a dual ion channel/molecular receptor-like platform for metal ion detection
Accepted Manuscript - Paper

2-D Transition Metal Trichalophosphogenide FePS3 Against Multi-Drug Resistant Microbial Infections

Accepted Manuscript - Paper

Enhanced Electrocatalytic Activity and Stability for Symmetrical Solid Oxide Fuel Cells with Praseodymium-Doped SrCo0.2Fe0.8O3-δ Electrodes

Accepted Manuscript - Paper

Construction of Co/Co2P/VN Heterointerfaces Enhances Trifunctional Hydrogen and Oxygen Catalytic Reactions

Open Access Paper

Balancing Ge de-intercalation and Si re-insertion rates stabilizes hydrolytically labile germanosilicate zeolites

Balanced deintercalation and reinsertion of framework atoms was used to stabilize water-sensitive germanosilicate zeolites. They become resistant to structural degradation and thus available for modification and use.

Graphical abstract: Balancing Ge de-intercalation and Si re-insertion rates stabilizes hydrolytically labile germanosilicate zeolites
From the themed collection: Journal of Materials Chemistry A HOT Papers
Paper

Crystal structure, magnetotransport properties, and electronic band structure of V1−xTixSe2 single crystals

The electrical properties of V1−xTixSe2 are highly tunable, suggesting a promising application in future electronic devices. This work reports the weak localization in VSe2 and TiSe2 single crystals, which can be modulated by the defect density.

Graphical abstract: Crystal structure, magnetotransport properties, and electronic band structure of V1−xTixSe2 single crystals
Open Access Paper

Perylene diimide functionalized nano-silica: green emissive material for selective probing and remediation of 4-nitrocatechol, Ru3+, and Cu2+ with biosensing applications

A novel nano-silica functionalized material developed for dual functions of sensing and remediation of specific analytes, offering benefits of sensitive detection, high adsorption capacity with recyclability & biosensing capability.

Graphical abstract: Perylene diimide functionalized nano-silica: green emissive material for selective probing and remediation of 4-nitrocatechol, Ru3+, and Cu2+ with biosensing applications
Paper

Exploring reaction mechanisms for CO2 reduction on carbides

The electrocatalytic conversion of carbon dioxide (CO2) into valuable fuels offers immense promise in pursuing sustainable energy solutions.

Graphical abstract: Exploring reaction mechanisms for CO2 reduction on carbides
Paper

An advanced passive radiative cooling emitter with ultrahigh sub-ambient cooling performance

This study develops a state-of-the-art passive radiative cooling emitter with 95.5% reflectance and 97.9% emissivity, achieving an average temperature reduction of 20.1 °C and a cooling power of 121.0 W m−2 under intense sunlight.

Graphical abstract: An advanced passive radiative cooling emitter with ultrahigh sub-ambient cooling performance
Paper

One-pot spatial engineering of multi-enzymes in metal–organic frameworks for enhanced cascade activity

A one-pot strategy was developed for the first time to achieve the precise spatial arrangement of multiple enzymes in MOFs, improving multi-enzyme cascade efficiency.

Graphical abstract: One-pot spatial engineering of multi-enzymes in metal–organic frameworks for enhanced cascade activity
Paper

Unlocking the Zn storage performance of ammonium vanadate nanoflowers as high-capacity cathodes for aqueous zinc-ion batteries via potassium ion and ethylene glycol co-intercalation engineering

K+ and ethylene glycol are co-inserted into the intermediate layer of NH4V4O10 to regulate the interplanar spacing, oxygen deficiency, redox activity and micromorphology, boosting the zinc storage activity of the material.

Graphical abstract: Unlocking the Zn storage performance of ammonium vanadate nanoflowers as high-capacity cathodes for aqueous zinc-ion batteries via potassium ion and ethylene glycol co-intercalation engineering
Paper

Preparation of supercapacitor electrode materials from e-waste: eco-friendly Cu recovery from printed circuit board waste using reduced graphene oxide and upcycling to Cu/CuO@C

Copper (Cu) was recovered from e-waste using reduced graphene oxide (rGO), and the recovered material was further upcycled into Cu/CuO@C. This upcycled material was then evaluated for its potential as an electrode material in supercapacitors.

Graphical abstract: Preparation of supercapacitor electrode materials from e-waste: eco-friendly Cu recovery from printed circuit board waste using reduced graphene oxide and upcycling to Cu/CuO@C
Open Access Paper

Regulating NO2 adsorption at ambient temperature by manipulating copper species as binding sites in copper-modified SSZ-13 zeolites

A Cu-modified SSZ-13 zeolite for enhanced NO2 adsorption at ambient temperature.

Graphical abstract: Regulating NO2 adsorption at ambient temperature by manipulating copper species as binding sites in copper-modified SSZ-13 zeolites
Open Access Paper

Tailoring a hierarchical porous carbon electrode from carbon black via 3D diatomite morphology control for enhanced electrochemical performance

Carbon black, a nano-porous material usually derived from the pyrolysis of waste tyres possesses varied particle sizes and morphology making it a viable material for several engineering applications.

Graphical abstract: Tailoring a hierarchical porous carbon electrode from carbon black via 3D diatomite morphology control for enhanced electrochemical performance
Paper

Strategic cation exchange induced 2D nickel sulphide nanoplates with enhanced oxygen evolution reaction performance

A cation exchange method enables the synthesis of highly crystalline 2D NixS nanoplates with fine-tuned morphology. These nanoplates exhibit excellent OER performance, achieving a 329 mV overpotential at 10 mA cm−2 and a 52 mV dec−1 Tafel slope.

Graphical abstract: Strategic cation exchange induced 2D nickel sulphide nanoplates with enhanced oxygen evolution reaction performance
Paper

A regenerative dual-functional platform combining dendritic silica and anthraquinone amide: advancing seawater lithium detection and recovery with biosensing capabilities

A novel material with a dendritic silica substrate and anthraquinone amide ligand enables simultaneous lithium detection and adsorption in water, offering green-emissive sensing, high adsorption capacity, fast kinetics, and biosensing.

Graphical abstract: A regenerative dual-functional platform combining dendritic silica and anthraquinone amide: advancing seawater lithium detection and recovery with biosensing capabilities
Paper

A 2D layered semiconducting (LCu3I3)n coordination polymer for energy storage through dual ion intercalation

Semiconducting polymer, [(Cu3I3L)n], having a layered structure, shows efficient supercapattery performance with excellent stability. The performance is attributed to the Cu/Cu2+ redox couple accompanying dual ion (de)intercalation.

Graphical abstract: A 2D layered semiconducting (LCu3I3)n coordination polymer for energy storage through dual ion intercalation
Paper

Condensation heat transfer enhancement through durable, self-propelling fluorine-free silane-treated anodized surfaces

When two or more adjacent droplets coalesce, excess surface energy is generated, which can be converted into the kinetic energy of the merged droplet through a suitable nanostructure and the superhydrophobicity of the surface.

Graphical abstract: Condensation heat transfer enhancement through durable, self-propelling fluorine-free silane-treated anodized surfaces
Open Access Paper

Active site engineering of intermetallic nanoparticles by the vapour–solid synthesis: carbon black supported nickel tellurides for hydrogen evolution

The intermetallic phases Ni3Te2, NiTe, NiTe2−x & NiTe2 were synthesized as carbon-black supported nanoparticles using the vapour–solid synthesis approach and were characterized for their performance in electrocatalytic hydrogen evolution.

Graphical abstract: Active site engineering of intermetallic nanoparticles by the vapour–solid synthesis: carbon black supported nickel tellurides for hydrogen evolution
Paper

An eco-friendly polycaprolactone/graphite composite as a robust freestanding electrode platform for supercapacitive energy storage

A novel eco-friendly composite electrode/current collector made from polycaprolactone and graphite filler offers bulk conductivity, is freestanding, cost-effective, and shows supercapacitive energy storage potential with electrodeposited polyaniline.

Graphical abstract: An eco-friendly polycaprolactone/graphite composite as a robust freestanding electrode platform for supercapacitive energy storage
Paper

Bifunctional interface stabilizer for promoting preferential crystal face adsorption and inducing planar Zn growth

A unique kind of organic small molecules with two zincophilic sites is demonstrated as the bifunctional interface stabilizer (BIS) for promoting uniform Zn deposition and suppressing dendrite formation.

Graphical abstract: Bifunctional interface stabilizer for promoting preferential crystal face adsorption and inducing planar Zn growth
From the themed collection: Journal of Materials Chemistry A HOT Papers
Paper

Ultrafast degradation of organic pollutants enabled by nanofluidic ZIF-67/GO membranes via efficient nanoconfined peroxymonosulfate activation

Nanofluidic catalytic membranes composed of two-dimensional graphene oxide nanosheets and ZIF-67 crystals swiftly eliminate organic pollutants from wastewater.

Graphical abstract: Ultrafast degradation of organic pollutants enabled by nanofluidic ZIF-67/GO membranes via efficient nanoconfined peroxymonosulfate activation
Paper

High-load Mg2Ni nanoparticle-carbon nanofiber composites for hydrogen storage

ATEM image of nanoparticles of as-prepared Mg2Ni for hydrogen storage.

Graphical abstract: High-load Mg2Ni nanoparticle-carbon nanofiber composites for hydrogen storage
Paper

Mitigating the volume expansion and enhancing the cycling stability of ferrous fluorosilicate-modified silicon-based composite anodes for lithium-ion batteries

This study introduces an FeSiF6 additive synthesized via the reaction of HF with Si–Fe alloys. It prevents crystalline Li15Si4 formation and promotes stable SEI film, significantly enhancing the cycling stability of silicon-based anodes.

Graphical abstract: Mitigating the volume expansion and enhancing the cycling stability of ferrous fluorosilicate-modified silicon-based composite anodes for lithium-ion batteries
Paper

Metal-free bi-functional cooperative catalysis: amine and quaternary amine-functionalized dendritic fibrous nanosilica as heterogeneous catalysts for the Henry reaction and CO2 conversion

This study explores amine-functionalized dendritic fibrous nanosilica (DFNS) as a highly efficient, base-free heterogeneous catalyst for nitro-aldol (Henry) condensation and additive-free CO2 utilization, outperforming existing catalysts.

Graphical abstract: Metal-free bi-functional cooperative catalysis: amine and quaternary amine-functionalized dendritic fibrous nanosilica as heterogeneous catalysts for the Henry reaction and CO2 conversion
Accepted Manuscript - Paper

Unveiling Magnetic Transition-Driven Thermal Conductivity Switching in Semiconducting Monolayer VS2

Paper

Enzyme-mimicking redox-active vitamin B12 functionalized MWCNT catalyst for nearly 100% faradaic efficiency in electrochemical CO2 reduction

Development of highly functional and green electrocatalyst which mimics the natural enzymes for 100% efficiency, selectivity and low-over potential based facile operation is the ultimate aim for the success of the future electrochemical CO2 reduction based carbon net-zero technologies.

Graphical abstract: Enzyme-mimicking redox-active vitamin B12 functionalized MWCNT catalyst for nearly 100% faradaic efficiency in electrochemical CO2 reduction
Paper

α-Graphyne with ultra-low diffusion barriers as a promising sodium-ion battery anode and a computational scheme for accurate estimation of theoretical specific capacity

We propose α-graphyne, with a low diffusion barrier and excellent thermodynamical stability, as a promising anode host for Na-ion batteries. We developed a new computational scheme to accurately calculate theoretical specific capacity (TSC).

Graphical abstract: α-Graphyne with ultra-low diffusion barriers as a promising sodium-ion battery anode and a computational scheme for accurate estimation of theoretical specific capacity
Paper

Yttrium doping stabilizes the structure of Ni3(NO3)2(OH)4 cathodes for application in advanced Ni–Zn batteries

The Y-Ni3(NO3)2(OH)4 material is used for zinc-based alkaline batteries. The constructed Zn-Ni batteries offer a high energy density (379 Wh kg−1) with a power density of 1749 W kg−1.

Graphical abstract: Yttrium doping stabilizes the structure of Ni3(NO3)2(OH)4 cathodes for application in advanced Ni–Zn batteries
Paper

Converting the covalent organic framework linkage from hydrazone to thiadiazole toward blue light-powered selective conversion of organic sulfides

TDA-COF, a triazine-based COF with an irreversible thiadiazole linkage, swiftly carries out the blue light-powered selective conversion of thioanisoles with O2.

Graphical abstract: Converting the covalent organic framework linkage from hydrazone to thiadiazole toward blue light-powered selective conversion of organic sulfides
From the themed collection: Journal of Materials Chemistry A HOT Papers
Paper

A dynamically stable self-assembled CoFe (oxy)hydroxide-based nanocatalyst with boosted electrocatalytic performance for the oxygen-evolution reaction

A self-assembled CoFe (oxy)hydroxide nanocatalyst exhibits high mass activity and dynamic stability and overcomes the inherent defects of CoFe LDH for OER catalysis.

Graphical abstract: A dynamically stable self-assembled CoFe (oxy)hydroxide-based nanocatalyst with boosted electrocatalytic performance for the oxygen-evolution reaction
Paper

2D metal–organic framework derived ultra-thin nitrogen-doped oxygen rich porous carbon nanosheets for zinc-ion hybrid supercapacitors

2D MOF derived ultra-thin carbon nanosheets with high reactivity, super-hydrophilicity and hierarchical porosity are prepared. The corresponding Zn-ion hybrid supercapacitor delivers exceptional energy storage capability with long cycling stability.

Graphical abstract: 2D metal–organic framework derived ultra-thin nitrogen-doped oxygen rich porous carbon nanosheets for zinc-ion hybrid supercapacitors
Open Access Paper

Alkali-promoted indium oxide as a highly active and selective catalyst for photo-thermal CO2 hydrogenation

Cs-promoted In2O3 has demonstrated excellent catalytic activity and selectivity in photo-thermal CO2 hydrogenation. Mechanistic studies suggest that non-thermal effects prevail, particularly at low reaction temperatures and high light intensities.

Graphical abstract: Alkali-promoted indium oxide as a highly active and selective catalyst for photo-thermal CO2 hydrogenation
From the themed collection: Journal of Materials Chemistry A HOT Papers
Open Access Paper

Understanding the evolution of ternary alloyed nanoparticles during reversible exsolution from double perovskite oxides

This work unveils the mechanism of FeCoNi alloy reversible exsolution from double perovskites via in situ synchrotron-based NAP-XPS and time-resolved XRD.

Graphical abstract: Understanding the evolution of ternary alloyed nanoparticles during reversible exsolution from double perovskite oxides
Paper

Nickel-doped Li2MoO4 as a high-performance anode material for rechargeable lithium-ion batteries

A nickel doping strategy has been developed to prepare Li2NixMo1−xO4 as an anode for LIBs. The as-prepared Ni-doped Li2Ni0.05Mo0.95O4 shows a stable lithium storage capacity of 686.6 mA h g−1, much higher than 365 mA h g−1 for a Li2MoO4 anode.

Graphical abstract: Nickel-doped Li2MoO4 as a high-performance anode material for rechargeable lithium-ion batteries
Paper

Constructing sodiophilic interconnected ion-transport channels towards a stable Na-metal anode

Tuning the electrochemical behaviors of Na metal anodes via building Na+-conducting channels through a facile rolling and folding method.

Graphical abstract: Constructing sodiophilic interconnected ion-transport channels towards a stable Na-metal anode
Paper

Tuning the surface charge and pore size of IPNs arrests covalent organic nanostructures through in situ exchangeable bonds for the removal of persistent contaminants

Novel SH-COF and exchangeable bonds enabled recyclable IPN membrane for effective molecular sieving and water remediation via pore size reduction and surface charge enhancement.

Graphical abstract: Tuning the surface charge and pore size of IPNs arrests covalent organic nanostructures through in situ exchangeable bonds for the removal of persistent contaminants
From the themed collection: Journal of Materials Chemistry A HOT Papers
Paper

Biomass-derived B/N/P co-doped porous carbons as bifunctional materials for supercapacitors and sodium-ion batteries

B/N/P co-doped biomass carbons with optimized pore structure and electrical conductivity exhibited supervisor electrochemical performance in supercapacitors and sodium-ion batteries.

Graphical abstract: Biomass-derived B/N/P co-doped porous carbons as bifunctional materials for supercapacitors and sodium-ion batteries
Paper

Surface chemistry altering electronic behaviour of liquid metal-derived tin oxide nanosheets

Interactions between solvents with surface Sn atoms are unravelled experimentally and theoretically for impacting the electronic properties of 2D SnO2 nanosheets.

Graphical abstract: Surface chemistry altering electronic behaviour of liquid metal-derived tin oxide nanosheets
Paper

Facile and scalable fabrication of flexible micro-supercapacitor with high volumetric performance based on ultrathin Co(OH)2 nanosheets

Flexible and in-plane micro-supercapacitor with high volumetric capacitance based on ultrathin Co(OH)2 nanosheets.

Graphical abstract: Facile and scalable fabrication of flexible micro-supercapacitor with high volumetric performance based on ultrathin Co(OH)2 nanosheets
Paper

Unlocking enhanced electrochemical performance through oxygen–nitrogen dual functionalization of iron–nickel–sulfide for efficient energy storage systems

This study showcases a supercapacitor device with oxygen–nitrogen dual functionalized and sulfurized iron–nickel hydroxysulfide, demonstrating high performance and stability for energy storage.

Graphical abstract: Unlocking enhanced electrochemical performance through oxygen–nitrogen dual functionalization of iron–nickel–sulfide for efficient energy storage systems
Paper

Disparity among cyclic alkyl carbonates associated with the cathode–electrolyte interphase at high voltage

The schematic of CEI evolution.

Graphical abstract: Disparity among cyclic alkyl carbonates associated with the cathode–electrolyte interphase at high voltage
Paper

Fully solution-processed red tandem quantum dot light-emitting diodes with an EQE exceeding 35%

By balancing carrier injection and improving charge generation efficiency, the EQE of red tandem QLEDs obtained by all-solution processing exceeds 35%.

Graphical abstract: Fully solution-processed red tandem quantum dot light-emitting diodes with an EQE exceeding 35%
Paper

A single-atom iron catalyst on hierarchical N-doped carbon for highly efficient oxygen reduction in Zn–air batteries

Single-atom iron electrocatalysts have emerged as up-and-coming alternatives to platinum-based catalysts for the oxygen reduction reaction.

Graphical abstract: A single-atom iron catalyst on hierarchical N-doped carbon for highly efficient oxygen reduction in Zn–air batteries
Paper

Rational electrolyte design for Li-metal batteries operated under extreme conditions: a combined DFT, COSMO-RS, and machine learning study

We developed a computational protocol combining DFT, COSMO-RS, and machine learning to investigate the thermodynamic properties of 190 binary solvent mixtures. This approach demonstrates high potential for guiding electrolyte design.

Graphical abstract: Rational electrolyte design for Li-metal batteries operated under extreme conditions: a combined DFT, COSMO-RS, and machine learning study
Paper

Ruthenium supported on zirconia–carbon nanocomposites derived by using UiO-66 for efficient photothermal catalytic CO2 reduction

Ru–ZrO2/C with effective light-to-heat conversion and low-valence Ru achieves 504.1 mmol g−1 h−1 of rate and 98.9% selectivity for photothermal CO2 methanation.

Graphical abstract: Ruthenium supported on zirconia–carbon nanocomposites derived by using UiO-66 for efficient photothermal catalytic CO2 reduction
Paper

Blue ZnSeTe quantum dot light-emitting diodes with low efficiency roll-off enabled by an in situ hybridization of ZnMgO nanoparticles and amino alcohol molecules

In situ amino alcohol hybrid ZMO NPs have been developed, which not only reduces exciton quenching at the QDs/ETL interface, but also enhances electron injection. In the end, a peak EQE of 8.6% and an extremely low efficiency roll-off were achieved.

Graphical abstract: Blue ZnSeTe quantum dot light-emitting diodes with low efficiency roll-off enabled by an in situ hybridization of ZnMgO nanoparticles and amino alcohol molecules
Paper

Surface passivation with an electron-donating sulfonate group for high-performance and stable perovskite solar cells

A new passivator, 4-aminophenyl sulfone (APS), containing a Lewis base group (S[double bond, length as m-dash]O), could interact with the uncoordinated Pb2+ on perovskite surface, which not only reduces trap state density but also induces a more p-type surface of perovskite film.

Graphical abstract: Surface passivation with an electron-donating sulfonate group for high-performance and stable perovskite solar cells
55 items

About this collection

As modern society’s demand for energy continues to grow, the development of nanomaterials for reducing energy consumption and generating and storing energy is becoming increasingly important. With advances in synthesis methods and theoretical simulations of nanomaterials, attention has turned to how nanomaterials can be rationally designed and synthesized, transformed into energy devices, and ultimately, how devices (such as solar cells, batteries, fuel cells, supercapacitors, light-emitting diodes, photodetectors etc.) can be integrated into systems to tackle real global challenges.

Guest edited by Professor Guohua Jia (Curtin University, Australia), Professor Hongxia Wang (Queensland University of Technology, Australia), Professor Xuyong Yang (Shanghai University, China), Professor Lina Quan (Virginia Tech, USA) and Professor Yun Liu (Australian National University, Australia), this Journal of Materials Chemistry A, Journal of Materials Chemistry C and Nanoscale collection will capture the cutting-edge innovations in nanomaterials synthesis, simulation, device fabrication, and system integration that are driving this field forward.

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