Solid state nanofibers based on self-assemblies: from cleaving from self-assemblies to multilevel hierarchical constructs

Ikkala, Olli; Ras, Robin H. A.; Houbenov, Nikolay; Ruokolainen, Janne; Pääkkö, Marjo; Laine, Janne; Leskelä, Markku; Berglund, Lars A.; Lindström, Tom; Brinke, G. ten; Iatrou, Hermis; Hadjichristidis, Nikos; Faul, Charl F. J.

doi:10.1039/b905204f

Cited by 33 publications

(18 citation statements)

References 63 publications

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“…Simply, the polymer chains assemble into fibrils by multiple hydrogen bonds between them, and the fibrils are further grouped to realize well‐organized hierarchical microfibers. The natural fibrous cellulose‐rich matters are generally from plant cell walls, and their structures and components are dependent on the sources and cleaving methods adopted . The cellulose‐rich fibers possess a hierarchical structure ranging from the cellulose crystal, fibrils (square cross‐section 4–8 nm), fibril aggregates (square cross‐section ca.…”

Section: Introductionmentioning

confidence: 99%

Cellulose‐Rich Nanofiber‐Based Functional Nanoarchitectures

Huang

2015

Advanced Materials

114

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Surface self-assembly of functional molecules or nanoscale building blocks is an effective strategy for the syntheses of advanced materials. Natural cellulose-rich substances have unique macro-to-nano hierarchical structural features. The fabrication of nanoarchitectures, employing specific guest species on the surfaces of the fine structures of such substances, results in corresponding artificial nanomaterials that possess the chemical functionalities and physical properties of both sides. Metal oxide thin film coatings with nanometer precision on the nanofibers of bulk cellulose-rich substances not only yield replicas of nanostructured materials, but also make it possible for further assemblies of functional units on the surfaces. Hence, nanostructured metal oxides and further composites, as well as surface-functionalized cellulose-based composites are fabricated by employing cellulose-rich substances as templates or scaffolds. The three-dimensional cross-linked porous structures, with the high surface area of the resultant nanomaterials or composites, lead to superior performance when employed as photocatalysts, electrode materials, and sensing matrices, on which this report is focused.

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Section: Introductionmentioning

confidence: 99%

Cellulose‐Rich Nanofiber‐Based Functional Nanoarchitectures

Huang

2015

Advanced Materials

114

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“…(v) Polymers-as expected for molecules at the border between ''molecular'' and ''nano''-were components of many discussions, including those of Piñol 36 (structures formed from block copolymers), Hayes 37 (self-healing structures) and Ikkala 38 (fibrils).…”

Section: Research Interests Of the Attendees Of This Faraday Discussionmentioning

confidence: 99%

“…(vi) Synthesis of molecules and aggregates showed the continuing skill of chemists in connecting atoms-both covalently and non-covalently-in new ways. Discussions including an important component of synthetic methods were those of Huskens 39 (templated molecular recognition), Mao 35 (DNA-based synthesis), Ikkala 38 (hierarchical self-assembly), Woolfson 40 (synthesis exploiting alpha-helices), Aida 41 (templated self-assembly), and van Esch 42 (self-assembly based on orthogonal interactions).…”

Section: Research Interests Of the Attendees Of This Faraday Discussionmentioning

confidence: 99%

Soft nanotechnology: “structure”vs.“function”

Whitesides

Lipomi

2009

Faraday Discuss.

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This paper offers a perspective on "soft nanotechnology"; that is, the branch of nanotechnology concerned with the synthesis and properties of organic and organometallic nanostructures, and with nanofabrication using techniques in which soft components play key roles. It begins with a brief history of soft nanotechnology. This history has followed a path involving a gradual shift from the promise of revolutionary electronics, nanorobotics, and other futuristic concepts, to the realization of evolutionary improvements in the technology for current challenges in information technology, medicine, and sustainability. Soft nanoscience is an area that is occupied principally by chemists, and is in many ways indistinguishable from "nanochemistry". The paper identifies the natural tendency of its practitioners--exemplified by the speakers at this Faraday Discussion--to focus on synthesis and structure, rather than on function and application, of nanostructures. Soft nanotechnology has the potential to apply to a wide variety of large-scale applied (information technology, healthcare cost reduction, sustainability, energy) and fundamental (molecular biochemistry, cell biology, charge transport in organic matter) problems.

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“…Under static or low shear conditions, gel structures may exhibit very different rheological behaviour depending on the mechanism of gelation . In the case of high aspect ratio rod‐like particulate nanofibrillated cellulose, a similar water trapping mechanism constructs the gel, and the application of strain under low shear for continued periods can lead to structure ensemble orientation .…”

Section: Introductionmentioning

confidence: 99%

Defining a strain‐induced time constant for oriented low shear‐induced structuring in high consistency MFC/NFC‐filler composite suspensions

Dimić-Mišić

Maloney

Gane

2015

J of Applied Polymer Sci

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Micro and nanofibrillated cellulose is an essentially one-dimensional high aspect-ratio particle material, which can undergo two-dimensional layer (band) structuring under shear. Controlling the evolving rheological properties in aqueous suspension is essential for industrial applications in composite materials. This study focuses on an as yet considered to be unreported phenomenon of structure hardening under low shear. The timescale of the quasi gelation-controlled structure formation under low shear is studied using the large gap vane-in-cup geometry of the Brookfield viscometer. It is proposed that localized structure forms within continuous shear bands, similar to quasi liquid-crystal formation. By extrapolating a characteristic structure growth parameter to the rotation speed at which it becomes zero, the strain-induced structure time constant, t gel , can be obtained as _ c(5 f (X)) 5 1/t gel for the range X 5 10-100/min. The time constant of low shear structure formation is shown to be separable from the static viscoelastic structure build under oscillation in concentrated composite suspension using plate-plate geometry, which is manifest by a Weissenberg normal force response on switching to applied shear, when the time constant of structuration t gel is long.

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Solid state nanofibers based on self-assemblies: from cleaving from self-assemblies to multilevel hierarchical constructs

Cited by 33 publications

References 63 publications

Cellulose‐Rich Nanofiber‐Based Functional Nanoarchitectures

Cellulose‐Rich Nanofiber‐Based Functional Nanoarchitectures

Soft nanotechnology: “structure”vs.“function”

Defining a strain‐induced time constant for oriented low shear‐induced structuring in high consistency MFC/NFC‐filler composite suspensions

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