Synthetic Melanin Hybrid Patchy Nanoparticle Photocatalysts

Zou, Yuan; Wang, Zhao; Chen, Zhan; Zhang, Jian Ping; Zhang, Qiujing; Tian, Yu; Ren, Shijie; Li, Yiwen

doi:10.1021/acs.jpcc.8b10469

Cited by 43 publications

(24 citation statements)

References 46 publications

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“…[49] Besides the intrinsic affinity to various metal ions, the mild reducing capability of PDA toward noble metal ions favors the in situ nucleation and growth of metallic nanomaterials, a process that is known otherwise as electroless metallization. We have currently developed four types of PDA-metal hybrid materials with varying compositions and properties, namely, PDA-M n+ , [247] PDA-M, [248] and PDA-M x O y [88] /PDA-M x S y [249] and PDA-MOF. [250][251] These hybrids, with strong coordination between PDA and metals, can have greater stability and functionality for applications in energy, catalysis, and others.…”

Section: Immobilization Of Inorganic Speciesmentioning

confidence: 99%

Strategic Advances in Spatiotemporal Control of Bioinspired Phenolic Chemistries in Materials Science

Jia

Wen

Cheng

et al. 2021

Adv Funct Materials

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Nature-inspired phenolic chemistries have substantially nourished the engineering of advanced materials for widespread applications in energy, catalysis, and biomedicine, among others. To achieve predictable yet adaptable material structures and properties, the spatial and/or temporal control over the phenolic chemistries per se is increasingly demanded. In this review, a systematic overview of recent strategical advances in the spatiotemporal control of phenolic chemistries in materials science is given. The chemical diversity and reactivity of catechols and polyphenols are first introduced as phenolic building blocks. With a main focus on catechols (especially dopamine), renewed insights into their mechanisms of polymerization/assembly, adhesion, and cohesion are provided. The conditions for tuning phenolic polymerization/assembly are also outlined. This paper focuses on the latest strategies for imparting controlled manipulation of phenolic chemistries in terms of many aspects: growth kinetics, chemical compositions and structures, dimensions and architectures, spatial patterns, and surface functionality. Finally, critical issues facing this field with perspectives delivered on future research are discussed. As envisaged, this review will provide helpful guidance to orchestrate state-of-the-art phenolic chemistries and materials science for producing materials with intended, application-oriented properties and functions.

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Section: Immobilization Of Inorganic Speciesmentioning

confidence: 99%

Strategic Advances in Spatiotemporal Control of Bioinspired Phenolic Chemistries in Materials Science

Jia

Wen

Cheng

et al. 2021

Adv Funct Materials

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“…From this viewpoint, research focusing on the structure-function relationship between natural melanin and PDA is progressing [ 49 ]. Inspired by the functionality of natural melanin, PDA-based functional materials such as free radical scavengers [ 50 ], UV absorbers [ 51 ], metal ion probes [ 52 ], catalyst [ 53 , 54 ], and antioxidants [ 55 ] have been developed.…”

Section: Characteristics Of Polydopamine As a Melanin Mimetic Materiamentioning

confidence: 99%

Progress in polydopamine-based melanin mimetic materials for structural color generation

Kohri

2020

Science and Technology of Advanced Materials

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Structural color is a color derived from optical interaction between light and a microstructure and is often seen in nature. Natural melanin plays an important role in bright structural coloration. For example, the vivid colors of peacock feathers are due to structural colors. The periodic arrangement of melanin granules inside the feathers leads to light interference, and the black granules absorb scattered light well, resulting in bright structural color. In recent years, polydopamine (PDA) has attracted attention as a melanin mimetic material. This review article summarizes recent research on structural coloration using PDAbased artificial melanin materials. It also outlines possible applications using bright structural colors realized by artificial melanin materials and future perspectives.

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“…[90] Further opportunities may derive by the clever use of melanin-containing hybrid systems based on for example, nanostructures,s ilica, halloysite,a nd zeolites. [91][92][93][94][95] Notably, PDAc an be exploited as am ultifunctional melanin-type system serving as an anoscale spacer to afford controllable nanogap sizes,ar edox-active coating to promote metal shell growth, or generating reactive oxygen species for antimicrobial applications, [96] as well as ar eactive scaffold to lock molecular probes inside the nanogap. [97] Several recent reviews may provide additional information as to the present and future of melanin-based materials.…”

Section: Angewandte Chemiementioning

confidence: 99%

Melanin Biopolymers: Tailoring Chemical Complexity for Materials Design

et al. 2020

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Melanins, a group of dark insoluble pigments found widespread in nature, have become the focus of growing interest in materials science for various biomedical and technological applications, including opto‐bioelectronics, nanomedicine and mussel‐inspired surface coating. Recent progress in the understanding of melanin optical, paramagnetic redox, and conductivity properties, including photoconductivity, would point to a revision of the traditional concept of structural disorder in terms of more sophisticated and interrelated levels of chemical complexity which however have never been defined and codified. Herein, we bring to focus the various levels of structural disorder that emerged from spectral and chemical signatures over the past decade. A revised approach to structure–property relationships in terms of intermolecular interactions is also provided that may pave the way towards the rational design of next‐generation melanin‐based functional materials.

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Synthetic Melanin Hybrid Patchy Nanoparticle Photocatalysts

Cited by 43 publications

References 46 publications

Strategic Advances in Spatiotemporal Control of Bioinspired Phenolic Chemistries in Materials Science

Strategic Advances in Spatiotemporal Control of Bioinspired Phenolic Chemistries in Materials Science

Progress in polydopamine-based melanin mimetic materials for structural color generation

Melanin Biopolymers: Tailoring Chemical Complexity for Materials Design

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