Bioinspired hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers

Gao, Huai‐Ling; Zhao, Ran; Cui, Chen; Zhu, YinBo; Chen, Siming; Pan, Zhao; Meng, Yu‐Feng; Wen, Shao‐Meng; Liu, Chuang; Wu, Huan

doi:10.1093/nsr/nwz077

Cited by 82 publications

(40 citation statements)

References 53 publications

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“…Regarding colloidal wet spinning, aqueous electrolytes have been investigated as coagulants, such as acidic solution including HCl, CH3COOH, H2SO4, and H3PO4 (Mittal et al 2017;Nechyporchuk et al 2017;Hagström et al 2018), and salt electrolytes including CaCl2 (Kafy et al 2017;Kim et al 2019a;Gao et al 2020) and FeCl3 (Wan et al 2019;Mittal et al 2019;Chen et al 2020). In all these processes, the possibility for continuous wet-spinning have been demonstrated, which is challenged in wet-spinning with organic coagulants.…”

Section: Electrolyte Coagulantsmentioning

confidence: 99%

Mesoporous Carbon Microfibers for Electroactive Materials Derived from Lignocellulose Nanofibrils

Borghei

Ishfaq

Lahtinen

et al. 2020

ACS Sustainable Chem. Eng.

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This work was carried out during 2016-2020, under the supervision of Professor Orlando J. Rojas. This dissertation was completed under the framework of the DWoC project funded by Business Finland, the "High-value Products from Lignin" (LIFT) project under the NordForsk program and the "BioELCell" (788489) program under the European Commission H2020-ERC-2017-Advanced Grant. Additional acknowledgement goes to the Paper Engineer's Association and Walter Ahlström foundation for their financial support for conference travels. I like to give my deepest appreciation to Professor Orlando J. Rojas for providing me the opportunity to challenge myself for the duration of my doctoral degree. I feel so lucky to become your student. The process was not that smooth, but you are always there to help me. The trust, freedom, knowledge and patience you have given, were all crucial to get me to this stage. The positive influences do not only go to my scientific research, but also to my attitude to life. I am extremely grateful for all your support and guidance. These words cannot express all my feelings, nor my thanks for all your helps. A special thank you to my thesis advisors Dr. Maryam Borghei and Professor Mariko Ago. Maryam, it was great to work alongside you and discover the topic of my doctoral thesis. As an advisor, you are always there for me. Thank you for helping me fix all the issues on both experiments and writings. Mariko, you were with me during the first two years of my doctoral studies, which was a very important time for growth. In order to find my research topic, we tried numerous experiments together; it was a great experience. I also want to thank Gisela Cunha and Julio Arboleda who were my advisors for a short term but gave me good suggestions and inspirations. My gratitude also goes to the project members in DWoC and LIFT. I am especially thankful to Hannes Orelma for managing the WP6 team with such a wonderful and creative atmosphere. A great thanks goes to Meri Lundhal, who introduced spinning to me and acted as an advisor during the whole PhD process. Thank you for all the training and advices you have given and the introduction to Teraloop. Thanks also go to

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Section: Electrolyte Coagulantsmentioning

confidence: 99%

Mesoporous Carbon Microfibers for Electroactive Materials Derived from Lignocellulose Nanofibrils

Borghei

Ishfaq

Lahtinen

et al. 2020

ACS Sustainable Chem. Eng.

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“…Furthermore, the two key structural properties-strength and toughness-tend to be mutually exclusive in structural material design, in which strong materials are usually brittle, whereas tough materials are frequently weak. [11,12] To address this challenge, tremendous efforts have been devoted in developing www.advmat.de www.advancedsciencenews.com was made with a linear cut to remove the inner node sections, softened with high-pressure steam, and flattened into a bulk bamboo material using a horizontal pressing apparatus. The flattened bulk bamboo was then chemically treated to partially remove the lignin and hemicellulose from its lignocellulosic cell walls, leading to swelling and softening of the well-aligned structure of the cellulose fibers.…”

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confidence: 99%

A Strong, Tough, and Scalable Structural Material from Fast‐Growing Bamboo

et al. 2020

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Lightweight structural materials with high strength are desirable for advanced applications in transportation, construction, automotive, and aerospace. Bamboo is one of the fastest growing plants with a peak growth rate up to 100 cm per day. Here, a simple and effective top‐down approach is designed for processing natural bamboo into a lightweight yet strong bulk structural material with a record high tensile strength of ≈1 GPa and toughness of 9.74 MJ m−3. More specifically, bamboo is densified by the partial removal of its lignin and hemicellulose, followed by hot‐pressing. Long, aligned cellulose nanofibrils with dramatically increased hydrogen bonds and largely reduced structural defects in the densified bamboo structure contribute to its high mechanical tensile strength, flexural strength, and toughness. The low density of lignocellulose in the densified bamboo leads to a specific strength of 777 MPa cm3 g−1, which is significantly greater than other reported bamboo materials and most structural materials (e.g., natural polymers, plastics, steels, and alloys). This work demonstrates a potential large‐scale production of lightweight, strong bulk structural materials from abundant, fast‐growing, and sustainable bamboo.

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“…Inspired by natural biosynthesized fibers featuring strong and stiff fibers embedded in soft and energy dissipating matrices, Gao and co‐workers [ 67 ] proposed a hierarchical helical and nanocomposite structure design for fabricating cellulose‐based macrofibers with exceptional tensile strength and toughness (Figure 9). They obtained bacterial cellulose/alginate gel filaments by wet‐spinning and braided them using a multilevel wet‐twisting process.…”

Section: Bioinspiration and Mineralization Approachmentioning

confidence: 99%

High‐Strength and Tough Crystalline Polysaccharide‐Based Materials^†

2020

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Due to the increasing public awareness of environmental issues and the shortage of resources, the focus on products made from renewable sources to fulfill the sustainable development of modern society has intensified. Natural crystalline polysaccharides have been studied for a long time and are among the most abundant renewable resources in the world. High‐performance materials have been fabricated using crystalline polysaccharides such as cellulose and chitin. For practical applications, the mechanical performance of polysaccharide‐based materials is critical. In this review, we focus on the methods for constructing high‐strength and high‐toughness crystalline polysaccharide‐based materials. This review elucidates the three approaches of aggregate structure regulation, bioinspiration and mineralization, and the use of crystalline polysaccharides as matrices for reinforcing the mechanical properties of nanocomposites.

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Bioinspired hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers

Cited by 82 publications

References 53 publications

Mesoporous Carbon Microfibers for Electroactive Materials Derived from Lignocellulose Nanofibrils

Mesoporous Carbon Microfibers for Electroactive Materials Derived from Lignocellulose Nanofibrils

A Strong, Tough, and Scalable Structural Material from Fast‐Growing Bamboo

High‐Strength and Tough Crystalline Polysaccharide‐Based Materials^†

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Bioinspired hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers

Cited by 82 publications

References 53 publications

Mesoporous Carbon Microfibers for Electroactive Materials Derived from Lignocellulose Nanofibrils

Mesoporous Carbon Microfibers for Electroactive Materials Derived from Lignocellulose Nanofibrils

A Strong, Tough, and Scalable Structural Material from Fast‐Growing Bamboo

High‐Strength and Tough Crystalline Polysaccharide‐Based Materials†

Contact Info

Product

Resources

About

High‐Strength and Tough Crystalline Polysaccharide‐Based Materials^†