Design of the nanoarray pattern Fe–Ni bi-metal nanoparticles@M13 virus for the enhanced reduction of p-chloronitrobenzene through the micro-electrolysis effect

Zhang, Shuai; Yu, Huimin; Yang, Jian; Shen, Zhongyao

doi:10.1039/c7en00120g

Cited by 6 publications

(4 citation statements)

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“…The research dataunderpinning this publication can be accessed at https://doi.org/10.17630/6f2acc8f-95ed-47d3-b218-71358b06503e. [45]…”

Section: Conflict Of Interestmentioning

confidence: 99%

Enhanced CO₂ Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes

Zhang,

Naden,

Zhang

et al. 2024

Advanced Materials

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In this work, the ligand‐to‐metal charge transition and Förster resonance energy transfer process is exploited to derive lanthanide organic framework (Tb‐cpon) modified perovskite solar cells (PSCs) with enhanced performance under UV irradiation. Tb‐cpon‐modified PSCs exhibit rapid response and reduced degradation due to energy down‐conversion facilitated by effective coupling of UV‐sensitive chromophores to lanthanide luminescent centers, enhancing the spectral response range of the composite films. Furthermore, the characteristic changes of precursor particle sizes suggest formation of Tb‐cpon adducts as intermediate products, leading to enhanced crystallinity and reduced defect concentrations in the Tb‐cpon‐perovskite hybrid film. Accordingly, the Tb‐cpon modified PSC devices obtained a champion efficiency up to 23.72% as well as a sensitive photovoltaic conversion even under pure UV irradiation. Moreover, the unencapsulated devices maintained more than 80% of the initial efficiency after continuous irradiation under a 310 nm UV lamp for 24 h (from the Au electrode side), compared to 21% for the control devices.This article is protected by copyright. All rights reserved

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“…The research dataunderpinning this publication can be accessed at https://doi.org/10.17630/6f2acc8f-95ed-47d3-b218-71358b06503e. [45]…”

Section: Conflict Of Interestmentioning

confidence: 99%

Enhanced CO₂ Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes

Zhang,

Naden,

Zhang

et al. 2024

Advanced Materials

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“…determined the adsorption of different metal ions on an M13 phage and demonstrated that increasing the electronegativity of the pVIII protein can further increase the adsorption of metal ions on the M13 phage . These structure features have enabled the M13 virus to be great templates for different applications, such as nanowire synthesis, energy development, pollutant degradation, biomedicine preparation, and biosensors. − Thus, we continuously focused on the varied binding specificity of the pVIII peptides toward different metal cations and further explored their applications based on the M13 phage in mimic-free-enzyme and pollution treatment. ,, …”

Section: Introductionmentioning

confidence: 99%

“…38−46 Thus, we continuously focused on the varied binding specificity of the pVIII peptides toward different metal cations and further explored their applications based on the M13 phage in mimic-free-enzyme and pollution treatment. 42,44,45 In this paper, a method for mild, universal, and convenient MSA self-assembled synthesis was developed using the delicate M13 virus as a biotemplate. Based on the highly dispersed pVIII peptides and their extremely strong binding specificity toward Fe 2+ , we creatively designed a universal route to fabricate different MSAs such as Ag, Pt, Pd, Zn, Cu, and Ni under mild conditions.…”

Section: Introductionmentioning

confidence: 99%

Designing M13 Bacteriophage and Fe-Nanonest Self-Assembly System for Universal and Facile Preparation of Metal Single Atoms as Stable Mimicking Enzymes

Qi,

Song,

Wang

et al. 2023

ACS Nano

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“…[ 11 ] In a simplified analogy, modular viral building molecules are similar to LEGO blocks that fit together in a unique way, which can then be used to design complex architectures in terms of both structure and function. Due to these unique properties, M13 bacteriophage has been explored for various functional devices and applications ranging from catalysts to energy harvesting devices, engineering sophisticated functional helical‐twisted structures [ 12 ] and labels in imaging‐based diagnosis, [ 13 ] through photovoltaics, [ 14 ] and onto biological imaging. [ 15 ] While M13‐based scaffolds have been investigated for directing the assembly of nanoparticles at specific molecular binding sites, for molecular‐fuel machines [ 16 ] and nanostructures for drug delivery, [ 17 ] the potential for quasi 3D viral nanotemplates for the synthesis of inorganic materials still remains mainly untapped.…”

Section: Introductionmentioning

confidence: 99%

Development of Unconventional Nano‐Metamaterials from Viral Nano‐Building Blocks

Passaretti

Schofield

Rickard

et al. 2022

Advanced Optical Materials

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example is the invisibility cloak, just like in the Harry Potter movies. Once it is slipped over something, it makes the object vanish. A possible real-world implementation of this "magical" garment is based on optical metamaterials, which are periodic structures at the nanoscale. Correctly designed nanostructures can guide light waves around an object, reminiscent of a rock diverting water in a stream, and effectively making it invisible. Additionally, nanostructures with periodicities that are comparable to the light wavelength, typically 200-1000 nm, i.e., photonic bandgap (PBG) materials, can trap certain colors of light. On the other hand, photonic metamaterials are based on the periodically arranged structures on the sub-100-nm length scale, which have the capability to modulate electromagnetic waves in an unusual fashion and are predicted to produce super-lenses, stealth or cloaking devices. [1] PBG metamaterials are another class of dielectric nanostructures which have patterning at the wavelength as well as sub-wavelength scale or just the latter but create a photonic band gap as well as result in negative refraction or other unusual effects. [2] They have a wavelength band gap in which light propagation is forbidden. Selective trapping and control of light propagation enables engineering the fundamental properties Structured metamaterials are periodically arranged nanostructures in which the dielectric constant is periodically modulated on a length-scale comparable to the desired wavelength of operation. Interactions of the electric fields of light waves with the sub-wavelength unit structures can produce effects that are impossible in natural materials. Here, a technique to construct three-dimensional (3D) metamaterials using self-assembling M13 viral building-blocks as templates which are then replicated into a metal quasi-3D nanostructure is developed. By correct fit of virus fragments, it is possible to employ them in a LEGO-like way to build up well-defined structures on the nanoscale. The virus blocks are designed to spontaneously assemble into 3D-periodic network structures with interesting optical properties. Subsequently, templating of these nanostructures into inorganic materials allows the replication of their network into an inverse periodic metal structure, which has the appropriate architecture for optical metamaterials. Establishing such a technique provides an important link toward the realization of applied metamaterials potentially heralding a new era for developing novel types of bio-synthetic optical materials. These materials have a wide range of potential uses including cloaking materials, light-storage devices, high-speed optical computers and nano-lasers, and will offer numerous applications in transformation optics.

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Design of the nanoarray pattern Fe–Ni bi-metal nanoparticles@M13 virus for the enhanced reduction of p-chloronitrobenzene through the micro-electrolysis effect

Abstract: Novel M13 virus-supported nanoarray patterns of bi-metal nanoparticles (NPs) were designed, synthesized and used for the enhanced reduction of p-chloronitrobenzene (p-CNB) based on the micro-electrolysis effect.

Cited by 6 publications

References 39 publications

Enhanced CO₂ Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes

Enhanced CO₂ Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes

Designing M13 Bacteriophage and Fe-Nanonest Self-Assembly System for Universal and Facile Preparation of Metal Single Atoms as Stable Mimicking Enzymes

Development of Unconventional Nano‐Metamaterials from Viral Nano‐Building Blocks

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Design of the nanoarray pattern Fe–Ni bi-metal nanoparticles@M13 virus for the enhanced reduction of p-chloronitrobenzene through the micro-electrolysis effect

Abstract: Novel M13 virus-supported nanoarray patterns of bi-metal nanoparticles (NPs) were designed, synthesized and used for the enhanced reduction of p-chloronitrobenzene (p-CNB) based on the micro-electrolysis effect.

Cited by 6 publications

References 39 publications

Enhanced CO2 Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes

Enhanced CO2 Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes

Designing M13 Bacteriophage and Fe-Nanonest Self-Assembly System for Universal and Facile Preparation of Metal Single Atoms as Stable Mimicking Enzymes

Development of Unconventional Nano‐Metamaterials from Viral Nano‐Building Blocks

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Enhanced CO₂ Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes

Enhanced CO₂ Electrolysis Through Mn Substitution Coupled with Ni Exsolution in Lanthanum Calcium Titanate Electrodes