Cellulose Nanofibers from Softwood, Hardwood, and Tunicate: Preparation–Structure–Film Performance Interrelation

Zhao, Yadong; Moser, C. M.; Lindström, Mikael; Henriksson, Gunnar; Li, Jiebing

doi:10.1021/acsami.7b01738

Cited by 164 publications

(96 citation statements)

References 69 publications

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“…This structure yields linear polymeric chains with high polar surface due to the multiple hydroxyl groups . Mechanical, chemical/mechanical, or enzymatic/mechanical treatment of cellulose fibers produce cellulose nanofibers with nano‐size diameter known as microfibrillated cellulose (MFC) and nanofibrillated cellulose (NFC) . In addition to the nanofibers, acid hydrolysis of cellulose can lead to formation of another kind of nanocellulose, eg, cellulose nanocrystals, highly crystalline, and rod‐shape particles .…”

Section: Introductionmentioning

confidence: 99%

Electrical conductivity and dielectric properties of nanofibrillated cellulose thin films from bagasse

Abdel-karim

Salama

Hassan

2018

J of Physical Organic Chem

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Nanocelluloses are potential candidates for applications in flexible electronic due to their unique physical and mechanical properties. However, electrical properties of these materials have not investigated thoroughly to study their electrical properties. In the current work, electrical properties of nanocellulose films prepared from bagasse pulp were studied and compared with those of bagasse pulp fibers. Two kinds of nanocelluloses were used in the current study: microfibrillated cellulose (MFC) and TEMPO-oxidized nanofibrillated cellulose (NFC). The crystallinity, grain size, and morphology of the different nanocelluloses were studied using X-ray diffraction and transmission electron microscopy techniques. The dc-, ac-electrical conductivity, dielectric constant ɛ′, and dielectric loss ɛ″ of non-plasticized and glycerol-plasticized nanocellulose films were studied in the temperature range from 298 to 373 K and in the frequency range from 0.1 KHz to 5 MHz. The results showed that the dc-electrical conductivity verifies Arrhenius equation and the activation energies varied in the range of 0.9 to 0.42 eV. Ac-electrical conductivity increased with frequency and fitted with power law equation, which ensures that the conduction goes through hopping mechanism. The dielectric constant decreased with increasing frequency and increased with increasing temperature, probably due to the free movement of dipole molecular chains within the cellulose fiber. Glycerolplasticized NFC (NFC-G) film had the highest dielectric constant and acelectrical conductivity values of 79 800 and 2.80× 10 −3 ohm −1 cm −1 , respectively. The high values of dielectric constant and conductivity of the prepared films support their use in electronic components.

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Section: Introductionmentioning

confidence: 99%

Electrical conductivity and dielectric properties of nanofibrillated cellulose thin films from bagasse

Abdel-karim

Salama

Hassan

2018

J of Physical Organic Chem

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“…Based on the XRD profile of the nanocellulose we assign the structure as cellulose I. Generally, the XRD pattern of cellulose with high crystallinity consists of three lattice peaks corresponding to 1 i 0, 1 1 0 and 2 0 0 reflections between 15.0 and 15.6 , 16.3 and 16.5 and 22.3 and 22.6 , respectively (Zhao, Moser, Lindstrom, Henriksson, & Li, 2017). This high crystallinity pattern was seen in nano-sized bacterial cellulose, which had three corresponding peaks in its XRD profile.…”

Section: Resultsmentioning

confidence: 99%

Nanocellulose-based fibres derived from palm oil by-products and theirin vitrobiocompatibility analysis

Fahma

Lisdayana

Abidin

et al. 2019

The Journal of The Textile Institute

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Fibres with nanocellulose isolated from oil palm empty fruit bunches (OPEFBs) were produced. Nanocellulose and PVA-nanocellulose fibres were prepared by wet spinning in an acetone coagulation bath without drawing. The addition of nanocellulose was varied from 10% to 30%, to reveal the beneficial effects of nanocellulose content on the properties of produced spun-fibres. Higher concentration of nanocellulose increased the stiffness of spun-fibres. PVA and PVA-bacterial cellulose fibres were also produced as a control and for comparison, respectively. The nanocellulose fibre formed a compact structure, while PVA fibres had hollow structures. The effect of the produced spun-fibres on the biocompatibility of calf pulmonary artery endothelial cells was assayed by an MTT test. Based on the MTT assay the addition of nanocellulose increased the percentage of cell viability of the obtained spunfibres slightly. These results point towards the use of sustainable sources of nanocellulose as a beneficial and biocompatible fibre material. ARTICLE HISTORY

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“…[5b] As the only animal source of cellulose, tunicate cellulose is superior to wood cellulose in terms of parameters such as molecular mass, crystallinity,c rystal size, and specific surface area. [17] In this study,c ellulose membranes rather than pulp were purified from Ciona intestinalis tunics. First, the mechanical separation of the internal organs of the tunicatea nd the cellulose-rich tunic was conducted with the aid of as calpel.…”

Section: Resultsmentioning

confidence: 99%

Transparent Composites Made from Tunicate Cellulose Membranes and Environmentally Friendly Polyester

2018

Self Cite

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A series of optically transparent composites were made by using tunicate cellulose membranes, in which the naturally organized cellulose microfibrillar network structure of tunicate tunics was preserved and used as the template and a solution of glycerol and citric acid at different molar ratios was used as the matrix. Polymerization through ester bond formation occurred at elevated temperatures without any catalyst, and water was released as the only byproduct. The obtained composites had a uniform and dense structure. Thus, the produced glycerol citrate polyester improved the transparency of the tunicate cellulose membrane while the cellulose membrane provided rigidity and strength to the prepared composite. The interaction between cellulose and polyester afforded the composites high thermal stability. Additionally, the composites were optically transparent and their shape, strength, and flexibility were adjustable by varying the formulation and reaction conditions. These composites of cellulose, glycerol, and citric acid are renewable and biocompatible and have many potential applications as structural materials in packaging, flexible displays, and solar cells.

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Cellulose Nanofibers from Softwood, Hardwood, and Tunicate: Preparation–Structure–Film Performance Interrelation

Cited by 164 publications

References 69 publications

Electrical conductivity and dielectric properties of nanofibrillated cellulose thin films from bagasse

Electrical conductivity and dielectric properties of nanofibrillated cellulose thin films from bagasse

Nanocellulose-based fibres derived from palm oil by-products and theirin vitrobiocompatibility analysis

Transparent Composites Made from Tunicate Cellulose Membranes and Environmentally Friendly Polyester

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