Multifunctional Reversible Self‐Assembled Structures of Cellulose‐Derived Phase‐Change Nanocrystals

Wang, Yonggui; Qiu, Zhe; Lang, Zhen; Xie, Yanjun; Xiao, Zefang; Wang, Haigang; Liang, Daxin; Li, Jian; Zhang, Kai

doi:10.1002/adma.202005263

Cited by 22 publications

(12 citation statements)

References 43 publications

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“…Inspired by and benefiting from this regular nanostructure, extensive efforts have been devoted to the development of CNC-based chiral photonics for diverse applications, such as in cosmetics, sensors, and flexible displays. [119][120][121][122][123] In this context, the origin of structural color in CNCs, chirality manipulation of CNC films, and development of novel CNC composites that can produce flexible photonic films in this field are discussed.…”

Section: Nanocellulose-based Chiral Photonic Filmsmentioning

confidence: 99%

Nanocellulose‐Based Functional Materials: From Chiral Photonics to Soft Actuator and Energy Storage

Wang

et al. 2021

Adv Funct Materials

142

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Nanocellulose is currently in the limelight of extensive research from fundamental science to technological applications owing to its renewable and carbon-neutral nature, superior biocompatibility, tailorable surface chemistry, and unprecedented optical and mechanical properties. Herein, an up-to-date account of the recent advancements in nanocellulose-derived functional materials and their emerging applications in areas of chiral photonics, soft actuators, energy storage, and biomedical science is provided. The fundamental design and synthesis strategies for nanocellulose-based functional materials are discussed. Their unique properties, underlying mechanisms, and potential applications are highlighted. Finally, this review provides a brief conclusion and elucidates both the challenges and opportunities of the intriguing nanocellulose-based technologies rooted in materials and chemistry science. This review is expected to provide new insights for nanocellulose-based chiral photonics, soft robotics, advanced energy, and novel biomedical technologies, and promote the rapid development of these highly interdisciplinary fields, including nanotechnology, nanoscience, biology, physics, synthetic chemistry, materials science, and device engineering.

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Section: Nanocellulose-based Chiral Photonic Filmsmentioning

confidence: 99%

Nanocellulose‐Based Functional Materials: From Chiral Photonics to Soft Actuator and Energy Storage

Wang

et al. 2021

Adv Funct Materials

142

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“…The phase transition of the shell conferred on the flaky structures superior thermoinduced self-healing and thermoreversible properties (Figure 7d). [126] Figure 6. Functionalization of films of CNFs.…”

Section: Available Reactive Groups and Functionalization Routesmentioning

confidence: 99%

“…The inset in (a) shows the dyed water droplets on the surface of the C 18 -UCNCs film. c) SAXS curves of a C 18 -UCNCs film measured under different conditions: as-prepared films at 25 °C, heated at 80 °C and cooled from 80 to 25 °C and aging for 24 h. d) Schematic of the formation of a thermoreversible flaky structure.Reproduced with permission [126]. Copyright 2020, Wiley-VCH.…”

mentioning

confidence: 99%

Nanocellulose and Its Interface: On the Road to the Design of Emerging Materials

Bettotti

Scarpa

2021

Adv Materials Inter

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The interest in the hierarchical structure, the multi-scale organization, and the properties of cellulose has long been the prerogative of botanists and plant physiologists. The last decade has witnessed the potential of a top-down approach to take apart cellulose-based raw materials into their micro-and nano-sized building blocks and to use them to design and fabricate functional materials and devices with new and, in some cases, outstanding properties. At present, cellulose is not only one of the main constituents of the plant and bacterial kingdom, it is also an important component of materials and manufactured goods, such as paper, textiles, or food additives. Depending on the extent of the scale down process, the fragments have variable size and in this review are collectively indicated as nanocellulose (NC). Although the interfacial properties of NC are always mentioned and recognized to contribute significantly to NC behavior, there is still room for reviewing the several recent reports highlighting the role of the interaction at the interface. In this scenario, the interface driven performances of some advanced NC-based materials are gaining in importance. This review aims at providing an overview of the most advanced of them, such as the Pickering emulsions, the supercapacitors, the drug crystallizing capsules, the nanowood.In nature, cellulose is synthesized by plants and also by some bacterial strains which can polymerize the glucose residues into linear β − 1, 4 −glucan chains. Once extracellularly secreted, the chains assemble, crystallize (the degree of crystallinity is up to 90%), and form nanostructures called bacterial nanocellulose (BNC) which in turn assemble forming microfibrils. Different from plant tissues where cellulose is embedded in a heterogeneous macrostructure, bacterial secretions are made of pure cellulose and are considered an excellent source of NC. [2] However, due to the large availability of cellulose from wood or other lowcost vegetable sources such as agriculture wastes, plant cellulose is the most common material for NC production. Several strategies for the preparation of NC have been reported. [3] A popular production route uses a pretreatment to introduce negative charges by 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO) mediated oxidation followed by a mechanical disintegration. [4] The behavior of NC has been largely studied, and it is well assessed that when NC colloidal suspensions are dried, they form flexible and transparent films with multifunctional properties. [5] These properties, first of all, depend on the degree of fibrillation of the colloidal NC. [6] Conversely, in aqueous solutions, NC Nanocellulose has several unique properties that render it a versatile mate rial with possible uses in a broad spectrum of applications. Nanocellulose is proved to form stable colloidal suspensions with interesting rheological properties, assemble in soft hydrogels of tunable porosity, compact dried films. Suggested or already current applications of these systems are in the f...

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“…( Kumar et al., 2020 ; Shao et al., 2021a ), and porous encapsulation (MOFs, EG, etc.) ( Chen et al., 2020e , 2020h , 2021 ; Huang et al., 2020 ; Kashyap et al., 2019 ; Liu et al., 2021d ; Wang et al., 2021b ). Unfortunately, the shape-stabilized composite PCMs usually exhibit strong rigidity and poor flexibility, resulting in difficult installation, easy brittle failure and poor surface contact ( Abdelrazik et al., 2020 ; Ashraf et al., 2017 ; Graham et al., 2020 ; Liu et al., 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Flexible engineering of advanced phase change materials

et al. 2022

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Multifunctional Reversible Self‐Assembled Structures of Cellulose‐Derived Phase‐Change Nanocrystals

Cited by 22 publications

References 43 publications

Nanocellulose‐Based Functional Materials: From Chiral Photonics to Soft Actuator and Energy Storage

Nanocellulose‐Based Functional Materials: From Chiral Photonics to Soft Actuator and Energy Storage

Nanocellulose and Its Interface: On the Road to the Design of Emerging Materials

Flexible engineering of advanced phase change materials

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