ISSN 0253-2778

CN 34-1054/N

Open AccessOpen Access JUSTC Engineering and Materials Science

Research progress of interfacial mechanical behavior and design of nanocellulose-based sequentially architected materials

Cite this:
https://doi.org/10.52396/JUST-2021-225
  • Received Date: 20 October 2021
  • Rev Recd Date: 28 November 2021
  • Publish Date: 31 October 2021
  • Nanocellulose exhibits superior mechanical properties and is a renewable natural biomass material. Nanocellulose-based sequentially architected materials are expected to become a new generation of environment-friendly high-performance structural and functional materials leading sustainable development. The construction of reasonable multiscale nonlinear coupling relationship between interfacial mechanical behavior and material microstructure is pivotal to the strengthening-toughening design of nanocellulose-based materials. Recent research progress of interfacial mechanical behavior and design of nanocellulose-based sequentially architected materials was reviewed here. The interfacial hydrogen-bonding behavior, multiscale interfacial mechanics, and some design cases of interfaces and microstructures were discussed. At last, the summary and perspective of key points in this field were given. This paper would aim to provide new perspectives for the design and preparation of high-performance nanocellulose-based sequentially architected materials based on micro-nano mechanics and multiscale mechanics.
    Nanocellulose exhibits superior mechanical properties and is a renewable natural biomass material. Nanocellulose-based sequentially architected materials are expected to become a new generation of environment-friendly high-performance structural and functional materials leading sustainable development. The construction of reasonable multiscale nonlinear coupling relationship between interfacial mechanical behavior and material microstructure is pivotal to the strengthening-toughening design of nanocellulose-based materials. Recent research progress of interfacial mechanical behavior and design of nanocellulose-based sequentially architected materials was reviewed here. The interfacial hydrogen-bonding behavior, multiscale interfacial mechanics, and some design cases of interfaces and microstructures were discussed. At last, the summary and perspective of key points in this field were given. This paper would aim to provide new perspectives for the design and preparation of high-performance nanocellulose-based sequentially architected materials based on micro-nano mechanics and multiscale mechanics.
  • loading
  • [1]
    Rochman C M, Browne M A, Halpern B S, et al. Classify plastic waste as hazardous. Nature, 2013, 494(7436): 169-171.
    [2]
    Uhrin A V, Schellinger J. Marine debris impacts to a tidal fringing-marsh in North Carolina. Marine Pollution Bulletin, 2011, 62(12): 2605-2610.
    [3]
    Browne M A, Dissanayake A, Galloway T S, et al. Ingested microscopic plastic translocates to the circulatory system of the mussel, Mytilus edulis (L.). Environmental Science & Technology, 2008, 42(13): 5026-5031.
    [4]
    Lithner D, Larsson A, Dave G. Environmental and health hazard ranking and assessment of plastic polymers based on chemical composition. Science of the Total Environment, 2011, 409(18): 3309-3324.
    [5]
    Teuten E L, Saquing J M, Knappe D R U, et al. Transport and release of chemicals from plastics to the environment and to wildlife. Philosophical Transactions of the Royal Society B-Biological Sciences, 2009, 364(1526): 2027-2045.
    [6]
    Browne M A, Crump P, Niven S J, et al. Accumulation of Microplastic on Shorelines Woldwide: Sources and Sinks. Environmental Science & Technology, 2011, 45(21): 9175-9179.
    [7]
    Pauly J L, Stegmeier S J, Allaart H A, et al. Inhaled cellulosic and plastic fibers found in human lung tissue. Cancer Epidemiology Biomarkers & Prevention, 1998, 7(5): 419-428.
    [8]
    Mettang T, Thomas S, Kiefer T, et al. Uraemic pruritus and exposure to di(2-ethylhexyl)phthalate (DEHP) in haemodialysis patients. Nephrology Dialysis Transplantation, 1996, 11(12): 2439-2443.
    [9]
    Mohanty A K, Vivekanandhan S, Pin J M, et al. Composites from renewable and sustainable resources: Challenges and innovations. Science, 2018, 362(6414): 536-542.
    [10]
    Moon R J, Martini A, Nairn J, et al. Cellulose nanomaterials review: structure, properties and nanocomposites. Chemical Society Reviews, 2011, 40(7): 3941-3994.
    [11]
    Xu Z P, Zheng Q S. Micro- and nano- mechanics in China: A brief review of recent progress and perspectives. Science China-Physics Mechanics & Astronomy, 2018, 61(7): 18-31.
    [12]
    Zhu H L, Luo W, CiesielskI P N, et al. Wood-derived materials for green electronics, biological devices, and energy applications. Chemical Reviews, 2016, 116(16): 9305-9374.
    [13]
    Mayer G. Rigid biological systems as models for synthetic composites. Science, 2005, 310(5751): 1144-1147.
    [14]
    FRatzl P, Weinkamer R. Nature's hierarchical materials. Progress in Materials Science, 2007, 52(8): 1263-1334.
    [15]
    Barthelat F. Biomimetics for next generation materials. Philosophical Transactions of the Royal Society A, Mathematical Physical and Engineering Sciences, 2007, 365(1861): 2907-2919.
    [16]
    Chen P Y, Lin A Y M, Lin Y S, et al. Structure and mechanical properties of selected biological materials. Journal of the Mechanical Behavior of Biomedical Materials, 2008, 1(3): 208-226.
    [17]
    Espinosa H D, Rim J E, Barthelat F, et al. Merger of structure and material in nacre and bone–Perspectives on de novo biomimetic materials. Progress in Materials Science, 2009, 54(8): 1059-1100.
    [18]
    Duan bo, Tu H, Zhang Lina. Material research progress of the sustainable polymer-cellulose. Acta Polymerica Sinica, 2020, 51(1): 66-86(Chinese).
    [19]
    Favier V, Canova G R, Cavaille J Y, et al. Nanocomposite materials from latex and cellulose whiskers. Polymers for Advanced Technologies, 1995, 6(5): 351-355.
    [20]
    Wu Z Y, Liang H W, Chen L F, et al. Bacterial cellulose: A robust platform for design of three dimensional carbon-based functional nanomaterials. Accounts of Chemical Research, 2016, 49(1): 96-105.
    [21]
    Nardecchia S, Carriazo D, Ferrer M L, et al. Three dimensional macroporous architectures and aerogels built of carbon nanotubes and/or graphene: Synthesis and applications. Chemical Society Reviews, 2013, 42(2): 794-830.
    [22]
    Biener J, Stadermann M, Suss M, et al. Advanced carbon aerogels for energy applications. Energy & Environmental Science, 2011, 4(3): 656-667.
    [23]
    Chabot V, Higgins D, Yu A P, et al. A review of graphene and graphene oxide sponge: Material synthesis and applications to energy and the environment. Energy & Environmental Science, 2014, 7(5): 1564-1596.
    [24]
    Huang Y, Zhu C L, Yang J Z, et al. Recent advances in bacterial cellulose. Cellulose, 2014, 21(1): 1-30.
    [25]
    Hu W L, Chen S Y, Yang J X, et al. Functionalized bacterial cellulose derivatives and nanocomposites. Carbohydrate Polymers, 2014, 101: 1043-1060.
    [26]
    Ansell M P. Wood microstructure–A cellular composite. Wood Composites. Woodhead Publishing, 2015: 3-26.
    [27]
    Salmén L. Wood cell wall structure and organisation in relation to mechanics. Plant Biomechanics. Springer, 2018: 3-19.
    [28]
    Li T, Zhang X, Lacey S D, et al. Cellulose ionic conductors with high differential thermal voltage for low-grade heat harvesting. Nature Materials, 2019, 18(6): 608-613.
    [29]
    Martin-Martinez F J. Designing nanocellulose materials from the molecular scale. Proceedings of the National Academy of Sciences of the United States of America, 2018, 115(28): 7174-7175.
    [30]
    Hou Y, Guan Q F, Xia J, et al. Strengthening and toughening hierarchical nanocellulose via humidity-mediated interface. ACS Nano, 2021, 15(1): 1310-1320.
    [31]
    Meng Q H, Wang T J. Mechanics of strong and tough cellulose nanopaper. Applied Mechanics Reviews, 2019, 71(4): 040801.
    [32]
    Dufresne A, Cavaille J Y, Vignon M R. Mechanical behavior of sheets prepared from sugar beet cellulose microfibrils. Journal of Applied Polymer Science, 1997, 64(6): 1185-1194.
    [33]
    Taniguchi T, Okamura K. New films produced from microfibrillated natural fibres. Polymer International, 1998, 47(3): 291-294.
    [34]
    Revol J F, Bradford H, Giasson J, et al. Helicoidal self-ordering of cellulose microfibrils in aqueous suspension. International Journal of Biological Macromolecules, 1992, 14(3): 170-172.
    [35]
    王莎. 高性能纤维素材料的构建与性能研究[D] . 广州:华南理工大学, 2018.
    [36]
    Osullivan A C. Cellulose: the structure slowly unravels. Cellulose, 1997, 4(3): 173-207.
    [37]
    Klemm D, Heublein B, Fink H P, et al. Cellulose: Fascinating biopolymer and sustainable raw material. Angewandte Chemie-International Edition, 2005, 44(22): 3358-3393.
    [38]
    Ishikawa A, Okano T, Sugiyama J. Fine structure and tensile properties of ramie fibres in the crystalline form of cellulose I, II, IIII and IVI. Polymer, 1997, 38(2): 463-468.
    [39]
    Koyama M, Sugiyama J, Itoh T. Systematic survey on crystalline features of algal celluloses. Cellulose, 1997, 4(2): 147-160.
    [40]
    Horikawa Y, Sugiyama J. Localization of crystalline allomorphs in cellulose microfibril. Biomacromolecules, 2009, 10(8): 2235-2239.
    [41]
    Moon R J, Martini A, Nairn J, et al. Cellulose nanomaterials review: Structure, properties and nanocomposites. Chemical Society Reviews, 2011, 40(7): 3941-3994.
    [42]
    Imai T, Putaux J L, Sugiyama J. Geometric phase analysis of lattice images from algal cellulose microfibrils. Polymer, 2003, 44(6): 1871-1879.
    [43]
    Duan B, Chang C Y, Ding B B, et al. High strength films with gas-barrier fabricated from chitin solution dissolved at low temperature. Journal of Materials Chemistry A, 2013, 1(5): 1867-1874.
    [44]
    Lani N S, Ngadi N, Johari A, et al. Isolation, characterization, and application of nanocellulose from oil palm empty fruit bunch fiber as nanocomposites. Journal of Nanomaterials, 2014: 702538.
    [45]
    Bacakova L, Pajorova J, Bacakova M, et al. Versatile application of nanocellulose: From industry to skin tissue engineering and wound healing. Nanomaterials, 2019, 9(2): 164.
    [46]
    Abitbol T, Rivkin A, Cao Y F, et al. Nanocellulose, a tiny fiber with huge applications. Current Opinion in Biotechnology, 2016, 39: 76-88.
    [47]
    Naz S, Ali J S, Zia M. Nanocellulose isolation characterization and applications: A journey from non-remedial to biomedical claims. Bio-Design and Manufacturing, 2019, 2(3): 187-212.
    [48]
    Trache D, Tarchoun A F, Derradji M, et al. Nanocellulose: From fundamentals to advanced applications. Frontiers in Chemistry, 2020, 8: 33.
    [49]
    Guo A F, Sun Z H, Sathitsuksanoh N, et al. A review on the application of nanocellulose in cementitious materials. Nanomaterials, 2020, 10(12): 2476.
    [50]
    Martin-Martinez F J, Jin K, Barreiro D L, et al. The rise of hierarchical nanostructured materials from renewable sources: learning from nature. ACS Nano, 2018, 12(8): 7425-7433.
    [51]
    Djahedi C, Berglund L A, Wohlert J. Molecular deformation mechanisms in cellulose allomorphs and the role of hydrogen bonds. Carbohydrate Polymers, 2015, 130: 175-182.
    [52]
    Hofstetter K, Hinterstoisser B, Salmen L. Moisture uptake in native cellulose—The roles of different hydrogen bonds: a dynamic FT-IR study using Deuterium exchange. Cellulose, 2006, 13(2): 131-145.
    [53]
    Nishiyama Y, Langan P, Wada M, et al. Looking at hydrogen bonds in cellulose. Acta Crystallographica Section D-Biological Crystallography, 2010, 66: 1172-1177.
    [54]
    Djahedi C, Bergenstrahle-Wohlert M, Berglund L A, et al. Role of hydrogen bonding in cellulose deformation: the leverage effect analyzed by molecular modeling. Cellulose, 2016, 23(4): 2315-2323.
    [55]
    Kovalenko V I. Crystalline cellulose: Structure and hydrogen bonds. Russian Chemical Reviews, 2010, 79(3): 231-241.
    [56]
    Kondo T. Hydrogen bonds in regioselectively substituted cellulose derivatives. Journal of Polymer Science Part B-Polymer Physics, 1994, 32(7): 1229-1236.
    [57]
    Roig F, Dantras E, Dandurand J, et al. Influence of hydrogen bonds on glass transition and dielectric relaxations of cellulose. Journal of Physics D-Applied Physics, 2011, 44(4): 045403.
    [58]
    Hou Y, He Z, Zhu Y, et al. Intrinsic kink deformation in nanocellulose. Carbohydrate Polymers, 2021, 273: 118578.
    [59]
    Ciesielski P N, Wagner R, Bharadwaj V S, et al. Nanomechanics of cellulose deformation reveal molecular defects that facilitate natural deconstruction. Proceedings of the National Academy of Sciences of the United States of America, 2019, 116(20): 9825-9830.
    [60]
    Bu L, Himmel M E, Crowley M F. The molecular origins of twist in cellulose I-beta. Carbohydrate Polymers, 2015, 125: 146-152.
    [61]
    Dumitrica T. Intrinsic twist in Ibeta cellulose microfibrils by tight-binding objective boundary calculations. Carbohydrate Polymers, 2020, 230: 115624.
    [62]
    Anggara K, Zhu Y, Fittolani G, et al. Identifying the origin of local flexibility in a carbohydrate polymer. Proceedings of the National Academy of Sciences, 2021, 118(23): e2102168118.
    [63]
    Zhao D Q, Deng Y, Han D L, et al. Exploring structural variations of hydrogen-bonding patterns in cellulose during mechanical pulp refining of tobacco stems. Carbohydrate Polymers, 2019, 204: 247-254.
    [64]
    Kamide K, Okajima K, Kowsaka K. Dissolution of natural cellulose into aqueous alkali solution—Role of super-molecular structure of cellulose. Polymer Journal, 1992, 24(1): 71-86.
    [65]
    Chundawat S P S, Bellesia G, Uppugundla N, et al. Restructuring the crystalline cellulose hydrogen bond network enhances its depolymerization rate. Journal of the American Chemical Society, 2011, 133(29): 11163-11174.
    [66]
    Hosoya T, Sakaki S. Levoglucosan formation from crystalline cellulose: Importance of a hydrogen bonding network in the reaction. Chemsuschem, 2013, 6(12): 2356-2368.
    [67]
    Sinko R, Keten S. Traction-separation laws and stick-slip shear phenomenon of interfaces between cellulose nanocrystals. Journal of the Mechanics and Physics of Solids, 2015, 78: 526-539.
    [68]
    何泽洲. 非共价界面层状纳米复合材料的多尺度力学与设计[D] . 合肥: 中国科学技术大学, 2021.
    [69]
    He Z Z, Zhu Y B, Xia J, et al. Optimization design on simultaneously strengthening and toughening graphene-based nacre-like materials through noncovalent interaction. Journal of the Mechanics and Physics of Solids, 2019, 133: 103706.
    [70]
    Zhu H L, Zhu S Z, Jia Z, et al. Anomalous scaling law of strength and toughness of cellulose nanopaper. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112(29): 8971-8976.
    [71]
    Barthelat F, Yin Z, Buehler M J. Structure and mechanics of interfaces in biological materials. Nature Reviews Materials, 2016, 1(4): 1-16.
    [72]
    Dastjerdi A K, Rabiei R, Barthelat F. The weak interfaces within tough natural composites: Experiments on three types of nacre. Journal of the Mechanical Behavior of Biomedical Materials, 2013, 19: 50-60.
    [73]
    Cox H L. The elasticity and strength of paper and other fibrous materials British Journal of Applied Physics. British Journal of Applied Physics, 1952, 3(3): 72-79.
    [74]
    He Z Z, Zhu Y B, Wu H G. Edge effect on interlayer shear in multilayer two-dimensional material assemblies. International Journal of Solids and Structures, 2020, 204: 128-137.
    [75]
    He Z Z, Zhu Y B, Wu H A. A universal mechanical framework for noncovalent interface in laminated nanocomposites. Journal of the Mechanics and Physics of Solids, 2022, 158: 104560.
    [76]
    Meng Q H, Shi X H. A microstructure-based constitutive model of anisotropic cellulose nanopaper with aligned nanofibers. Extreme Mechanics Letters, 2021, 43: 101158.
    [77]
    Mittal N, Ansari F, Gowda V K, et al. Multiscale control of nanocellulose assembly: Transferring remarkable nanoscale fibril mechanics to macroscale fibers. ACS Nano, 2018, 12(7): 6378-6388.
    [78]
    Meng Q H, Li B, Li T, et al. A multiscale crack-bridging model of cellulose nanopaper. Journal of the Mechanics and Physics of Solids, 2017, 103: 22-39.
    [79]
    Meng Q H, Li B, Li T, et al. Effects of nanofiber orientations on the fracture toughness of cellulose nanopaper. Engineering Fracture Mechanics, 2018, 194: 350-361.
    [80]
    Suksangpanya N, Yaraghi N A, Kisailus D, et al. Twisting cracks in Bouligand structures. Journal of the Mechanical Behavior of Biomedical Materials, 2017, 76: 38-57.
    [81]
    Song Z Q, Ni Y, Cai S Q. Fracture modes and hybrid toughening mechanisms in oscillated/twisted plywood structure. Acta Biomaterialia, 2019, 91: 284-293.
    [82]
    Hou Y Z, Guan Q F, Xia J, et al. Strengthening and toughening hierarchical nanocellulose via humidity-mediated interface. ACS Nano, 2021, 15(1): 1310-1320.
    [83]
    Wang S, Jiang F, Xu X, et al. Super-strong, super-stiff macrofibers with aligned, long bacterial cellulose nanofibers. Advanced Materials, 2017, 29(35): 1702498.
    [84]
    Jia C, Chen C, Kuang Y, et al. From wood to textiles: Top-down assembly of aligned cellulose nanofibers. Advanced Materials, 2018, 30(30): e1801347.
    [85]
    Gao H-L, Zhao R, Cui C, et al. Bioinspired hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers. National Science Review, 2020, 7(1): 73-83.
    [86]
    Mittal N, Benselfelt T, Ansari F, et al. Ion-specific assembly of strong, tough, and stiff biofibers. Angewandte Chemie, 2019, 58(51): 18562-18569.
    [87]
    Wang S, Li T, Chen C, et al. Transparent, anisotropic biofilm with aligned bacterial cellulose nanofibers. Advanced Functional Materials, 2018, 28(24): 1707491.
    [88]
    Ye D, Lei X, Li T, et al. Ultrahigh tough, super clear, and highly anisotropic nanofiber-structured regenerated cellulose films. ACS Nano, 2019, 13(4): 4843-4853.
    [89]
    Chen F, Xiang W, Sawada D, et al. Exploring large ductility in cellulose nanopaper combining high toughness and strength. ACS Nano, 2020, 14(9): 11150-11159.
    [90]
    Zhou Y, Chen C, Zhu S, et al. A printed, recyclable, ultra-strong, and ultra-tough graphite structural material. Materials Today, 2019, 30: 17-25.
    [91]
    Song J, Chen C, Zhu S, et al. Processing bulk natural wood into a high-performance structural material. Nature, 2018, 554(7691): 224-228.
    [92]
    Guan Q F, Yang H B, Han Z M, et al. Lightweight, tough, and sustainable cellulose nanofiber-derived bulk structural materials with low thermal expansion coefficient. Science Advances, 2020, 6(18): eaaz1114.
    [93]
    Guan Q F, Han Z-M, Yang H-B, et al. Regenerated isotropic wood. National Science Review, 2021, 8(7): 132-140.
    [94]
    Guan Q F, Yang H B, Han Z M, et al. An all-natural bioinspired structural material for plastic replacement. Nature Communications, 2020, 11(1): 5401.
    [95]
    Xiao S, Chen C, Xia Q, et al. Lightweight, strong, moldable wood via cell wall engineering as a sustainable structural material. Science, 2021, 374(6566): 465-471.
    [96]
    Yang C, Wu Q, Xie W, et al. Copper-coordinated cellulose ion conductors for solid-state batteries. Nature, 2021, 598(7882): 590-596.
    [97]
    Chen C, Song J, Cheng J, et al. Highly elastic hydrated cellulosic materials with durable compressibility and tunable conductivity. ACS nano, 2020, 14(12): 16723-16734.
    [98]
    Li T, Zhai Y, He S M, et al. A radiative cooling structural material. Science, 2019, 364(6442): 760-763.
    [99]
    Kuang Y, Chen C, He S, et al. A high-performance self-regenerating solar evaporator for continuous water desalination. Advanced Materials, 2019, 31(23): e1900498.
    [100]
    Zhu M, Song J, Li T, et al. Highly anisotropic, highly transparent wood composites. Advanced Materials, 2016, 28(26): 5181-5187.
    [101]
    Mi R, Chen C, Keplinger T, et al. Scalable aesthetic transparent wood for energy efficient buildings. Nature Communications, 2020, 11(1): 1-9.
    [102]
    Ray U, Zhu S Z, Pang Z Q, et al. Mechanics design in cellulose-enabled high-performance functional materials. Advanced Materials, 2021, 33(28): 2002504.
    [103]
    Paakko M, Ankerfors M, Kosonen H, et al. Enzymatic hydrolysis combined with mechanical shearing and high-pressure homogenization for nanoscale cellulose fibrils and strong gels. Biomacromolecules, 2007, 8(6): 1934-1941.
    [104]
    Fang Z Q, Li B, Liu Y, et al. Critical role of degree of polymerization of cellulose in super-strong nanocellulose films. Matter, 2020, 2(4): 1000-1014.
    [105]
    Henriksson M, Berglund L A, Isaksson P, et al. Cellulose nanopaper structures of high toughness. Biomacromolecules, 2008, 9(6): 1579-1585.
    [106]
    Galland S, Berthold F, Prakobna K, et al. Holocellulose nanofibers of high molar mass and small diameter for high-strength nanopaper. Biomacromolecules, 2015, 16(8): 2427-2435.
    [107]
    Ozkan M, Borghei M, Karakoc A, et al. Films based on crosslinked TEMPO-oxidized cellulose and predictive analysis via machine learning. Scientific Reports, 2018, 8(1): 1-9.
    [108]
    Ozkan M, Karakoc A, Borghei M, et al. Machine learning assisted design of Tailor-made nanocellulose films: A combination of experimental and computational studies. Polymer Composites, 2019, 40(10): 4013-4022.
    [109]
    Lamm M E, Li K, Qian J, et al. Recent advances in functional materials through cellulose nanofiber templating. Advanced Materials, 2021, 33(12) : 2005538.
  • 加载中

Catalog

    [1]
    Rochman C M, Browne M A, Halpern B S, et al. Classify plastic waste as hazardous. Nature, 2013, 494(7436): 169-171.
    [2]
    Uhrin A V, Schellinger J. Marine debris impacts to a tidal fringing-marsh in North Carolina. Marine Pollution Bulletin, 2011, 62(12): 2605-2610.
    [3]
    Browne M A, Dissanayake A, Galloway T S, et al. Ingested microscopic plastic translocates to the circulatory system of the mussel, Mytilus edulis (L.). Environmental Science & Technology, 2008, 42(13): 5026-5031.
    [4]
    Lithner D, Larsson A, Dave G. Environmental and health hazard ranking and assessment of plastic polymers based on chemical composition. Science of the Total Environment, 2011, 409(18): 3309-3324.
    [5]
    Teuten E L, Saquing J M, Knappe D R U, et al. Transport and release of chemicals from plastics to the environment and to wildlife. Philosophical Transactions of the Royal Society B-Biological Sciences, 2009, 364(1526): 2027-2045.
    [6]
    Browne M A, Crump P, Niven S J, et al. Accumulation of Microplastic on Shorelines Woldwide: Sources and Sinks. Environmental Science & Technology, 2011, 45(21): 9175-9179.
    [7]
    Pauly J L, Stegmeier S J, Allaart H A, et al. Inhaled cellulosic and plastic fibers found in human lung tissue. Cancer Epidemiology Biomarkers & Prevention, 1998, 7(5): 419-428.
    [8]
    Mettang T, Thomas S, Kiefer T, et al. Uraemic pruritus and exposure to di(2-ethylhexyl)phthalate (DEHP) in haemodialysis patients. Nephrology Dialysis Transplantation, 1996, 11(12): 2439-2443.
    [9]
    Mohanty A K, Vivekanandhan S, Pin J M, et al. Composites from renewable and sustainable resources: Challenges and innovations. Science, 2018, 362(6414): 536-542.
    [10]
    Moon R J, Martini A, Nairn J, et al. Cellulose nanomaterials review: structure, properties and nanocomposites. Chemical Society Reviews, 2011, 40(7): 3941-3994.
    [11]
    Xu Z P, Zheng Q S. Micro- and nano- mechanics in China: A brief review of recent progress and perspectives. Science China-Physics Mechanics & Astronomy, 2018, 61(7): 18-31.
    [12]
    Zhu H L, Luo W, CiesielskI P N, et al. Wood-derived materials for green electronics, biological devices, and energy applications. Chemical Reviews, 2016, 116(16): 9305-9374.
    [13]
    Mayer G. Rigid biological systems as models for synthetic composites. Science, 2005, 310(5751): 1144-1147.
    [14]
    FRatzl P, Weinkamer R. Nature's hierarchical materials. Progress in Materials Science, 2007, 52(8): 1263-1334.
    [15]
    Barthelat F. Biomimetics for next generation materials. Philosophical Transactions of the Royal Society A, Mathematical Physical and Engineering Sciences, 2007, 365(1861): 2907-2919.
    [16]
    Chen P Y, Lin A Y M, Lin Y S, et al. Structure and mechanical properties of selected biological materials. Journal of the Mechanical Behavior of Biomedical Materials, 2008, 1(3): 208-226.
    [17]
    Espinosa H D, Rim J E, Barthelat F, et al. Merger of structure and material in nacre and bone–Perspectives on de novo biomimetic materials. Progress in Materials Science, 2009, 54(8): 1059-1100.
    [18]
    Duan bo, Tu H, Zhang Lina. Material research progress of the sustainable polymer-cellulose. Acta Polymerica Sinica, 2020, 51(1): 66-86(Chinese).
    [19]
    Favier V, Canova G R, Cavaille J Y, et al. Nanocomposite materials from latex and cellulose whiskers. Polymers for Advanced Technologies, 1995, 6(5): 351-355.
    [20]
    Wu Z Y, Liang H W, Chen L F, et al. Bacterial cellulose: A robust platform for design of three dimensional carbon-based functional nanomaterials. Accounts of Chemical Research, 2016, 49(1): 96-105.
    [21]
    Nardecchia S, Carriazo D, Ferrer M L, et al. Three dimensional macroporous architectures and aerogels built of carbon nanotubes and/or graphene: Synthesis and applications. Chemical Society Reviews, 2013, 42(2): 794-830.
    [22]
    Biener J, Stadermann M, Suss M, et al. Advanced carbon aerogels for energy applications. Energy & Environmental Science, 2011, 4(3): 656-667.
    [23]
    Chabot V, Higgins D, Yu A P, et al. A review of graphene and graphene oxide sponge: Material synthesis and applications to energy and the environment. Energy & Environmental Science, 2014, 7(5): 1564-1596.
    [24]
    Huang Y, Zhu C L, Yang J Z, et al. Recent advances in bacterial cellulose. Cellulose, 2014, 21(1): 1-30.
    [25]
    Hu W L, Chen S Y, Yang J X, et al. Functionalized bacterial cellulose derivatives and nanocomposites. Carbohydrate Polymers, 2014, 101: 1043-1060.
    [26]
    Ansell M P. Wood microstructure–A cellular composite. Wood Composites. Woodhead Publishing, 2015: 3-26.
    [27]
    Salmén L. Wood cell wall structure and organisation in relation to mechanics. Plant Biomechanics. Springer, 2018: 3-19.
    [28]
    Li T, Zhang X, Lacey S D, et al. Cellulose ionic conductors with high differential thermal voltage for low-grade heat harvesting. Nature Materials, 2019, 18(6): 608-613.
    [29]
    Martin-Martinez F J. Designing nanocellulose materials from the molecular scale. Proceedings of the National Academy of Sciences of the United States of America, 2018, 115(28): 7174-7175.
    [30]
    Hou Y, Guan Q F, Xia J, et al. Strengthening and toughening hierarchical nanocellulose via humidity-mediated interface. ACS Nano, 2021, 15(1): 1310-1320.
    [31]
    Meng Q H, Wang T J. Mechanics of strong and tough cellulose nanopaper. Applied Mechanics Reviews, 2019, 71(4): 040801.
    [32]
    Dufresne A, Cavaille J Y, Vignon M R. Mechanical behavior of sheets prepared from sugar beet cellulose microfibrils. Journal of Applied Polymer Science, 1997, 64(6): 1185-1194.
    [33]
    Taniguchi T, Okamura K. New films produced from microfibrillated natural fibres. Polymer International, 1998, 47(3): 291-294.
    [34]
    Revol J F, Bradford H, Giasson J, et al. Helicoidal self-ordering of cellulose microfibrils in aqueous suspension. International Journal of Biological Macromolecules, 1992, 14(3): 170-172.
    [35]
    王莎. 高性能纤维素材料的构建与性能研究[D] . 广州:华南理工大学, 2018.
    [36]
    Osullivan A C. Cellulose: the structure slowly unravels. Cellulose, 1997, 4(3): 173-207.
    [37]
    Klemm D, Heublein B, Fink H P, et al. Cellulose: Fascinating biopolymer and sustainable raw material. Angewandte Chemie-International Edition, 2005, 44(22): 3358-3393.
    [38]
    Ishikawa A, Okano T, Sugiyama J. Fine structure and tensile properties of ramie fibres in the crystalline form of cellulose I, II, IIII and IVI. Polymer, 1997, 38(2): 463-468.
    [39]
    Koyama M, Sugiyama J, Itoh T. Systematic survey on crystalline features of algal celluloses. Cellulose, 1997, 4(2): 147-160.
    [40]
    Horikawa Y, Sugiyama J. Localization of crystalline allomorphs in cellulose microfibril. Biomacromolecules, 2009, 10(8): 2235-2239.
    [41]
    Moon R J, Martini A, Nairn J, et al. Cellulose nanomaterials review: Structure, properties and nanocomposites. Chemical Society Reviews, 2011, 40(7): 3941-3994.
    [42]
    Imai T, Putaux J L, Sugiyama J. Geometric phase analysis of lattice images from algal cellulose microfibrils. Polymer, 2003, 44(6): 1871-1879.
    [43]
    Duan B, Chang C Y, Ding B B, et al. High strength films with gas-barrier fabricated from chitin solution dissolved at low temperature. Journal of Materials Chemistry A, 2013, 1(5): 1867-1874.
    [44]
    Lani N S, Ngadi N, Johari A, et al. Isolation, characterization, and application of nanocellulose from oil palm empty fruit bunch fiber as nanocomposites. Journal of Nanomaterials, 2014: 702538.
    [45]
    Bacakova L, Pajorova J, Bacakova M, et al. Versatile application of nanocellulose: From industry to skin tissue engineering and wound healing. Nanomaterials, 2019, 9(2): 164.
    [46]
    Abitbol T, Rivkin A, Cao Y F, et al. Nanocellulose, a tiny fiber with huge applications. Current Opinion in Biotechnology, 2016, 39: 76-88.
    [47]
    Naz S, Ali J S, Zia M. Nanocellulose isolation characterization and applications: A journey from non-remedial to biomedical claims. Bio-Design and Manufacturing, 2019, 2(3): 187-212.
    [48]
    Trache D, Tarchoun A F, Derradji M, et al. Nanocellulose: From fundamentals to advanced applications. Frontiers in Chemistry, 2020, 8: 33.
    [49]
    Guo A F, Sun Z H, Sathitsuksanoh N, et al. A review on the application of nanocellulose in cementitious materials. Nanomaterials, 2020, 10(12): 2476.
    [50]
    Martin-Martinez F J, Jin K, Barreiro D L, et al. The rise of hierarchical nanostructured materials from renewable sources: learning from nature. ACS Nano, 2018, 12(8): 7425-7433.
    [51]
    Djahedi C, Berglund L A, Wohlert J. Molecular deformation mechanisms in cellulose allomorphs and the role of hydrogen bonds. Carbohydrate Polymers, 2015, 130: 175-182.
    [52]
    Hofstetter K, Hinterstoisser B, Salmen L. Moisture uptake in native cellulose—The roles of different hydrogen bonds: a dynamic FT-IR study using Deuterium exchange. Cellulose, 2006, 13(2): 131-145.
    [53]
    Nishiyama Y, Langan P, Wada M, et al. Looking at hydrogen bonds in cellulose. Acta Crystallographica Section D-Biological Crystallography, 2010, 66: 1172-1177.
    [54]
    Djahedi C, Bergenstrahle-Wohlert M, Berglund L A, et al. Role of hydrogen bonding in cellulose deformation: the leverage effect analyzed by molecular modeling. Cellulose, 2016, 23(4): 2315-2323.
    [55]
    Kovalenko V I. Crystalline cellulose: Structure and hydrogen bonds. Russian Chemical Reviews, 2010, 79(3): 231-241.
    [56]
    Kondo T. Hydrogen bonds in regioselectively substituted cellulose derivatives. Journal of Polymer Science Part B-Polymer Physics, 1994, 32(7): 1229-1236.
    [57]
    Roig F, Dantras E, Dandurand J, et al. Influence of hydrogen bonds on glass transition and dielectric relaxations of cellulose. Journal of Physics D-Applied Physics, 2011, 44(4): 045403.
    [58]
    Hou Y, He Z, Zhu Y, et al. Intrinsic kink deformation in nanocellulose. Carbohydrate Polymers, 2021, 273: 118578.
    [59]
    Ciesielski P N, Wagner R, Bharadwaj V S, et al. Nanomechanics of cellulose deformation reveal molecular defects that facilitate natural deconstruction. Proceedings of the National Academy of Sciences of the United States of America, 2019, 116(20): 9825-9830.
    [60]
    Bu L, Himmel M E, Crowley M F. The molecular origins of twist in cellulose I-beta. Carbohydrate Polymers, 2015, 125: 146-152.
    [61]
    Dumitrica T. Intrinsic twist in Ibeta cellulose microfibrils by tight-binding objective boundary calculations. Carbohydrate Polymers, 2020, 230: 115624.
    [62]
    Anggara K, Zhu Y, Fittolani G, et al. Identifying the origin of local flexibility in a carbohydrate polymer. Proceedings of the National Academy of Sciences, 2021, 118(23): e2102168118.
    [63]
    Zhao D Q, Deng Y, Han D L, et al. Exploring structural variations of hydrogen-bonding patterns in cellulose during mechanical pulp refining of tobacco stems. Carbohydrate Polymers, 2019, 204: 247-254.
    [64]
    Kamide K, Okajima K, Kowsaka K. Dissolution of natural cellulose into aqueous alkali solution—Role of super-molecular structure of cellulose. Polymer Journal, 1992, 24(1): 71-86.
    [65]
    Chundawat S P S, Bellesia G, Uppugundla N, et al. Restructuring the crystalline cellulose hydrogen bond network enhances its depolymerization rate. Journal of the American Chemical Society, 2011, 133(29): 11163-11174.
    [66]
    Hosoya T, Sakaki S. Levoglucosan formation from crystalline cellulose: Importance of a hydrogen bonding network in the reaction. Chemsuschem, 2013, 6(12): 2356-2368.
    [67]
    Sinko R, Keten S. Traction-separation laws and stick-slip shear phenomenon of interfaces between cellulose nanocrystals. Journal of the Mechanics and Physics of Solids, 2015, 78: 526-539.
    [68]
    何泽洲. 非共价界面层状纳米复合材料的多尺度力学与设计[D] . 合肥: 中国科学技术大学, 2021.
    [69]
    He Z Z, Zhu Y B, Xia J, et al. Optimization design on simultaneously strengthening and toughening graphene-based nacre-like materials through noncovalent interaction. Journal of the Mechanics and Physics of Solids, 2019, 133: 103706.
    [70]
    Zhu H L, Zhu S Z, Jia Z, et al. Anomalous scaling law of strength and toughness of cellulose nanopaper. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112(29): 8971-8976.
    [71]
    Barthelat F, Yin Z, Buehler M J. Structure and mechanics of interfaces in biological materials. Nature Reviews Materials, 2016, 1(4): 1-16.
    [72]
    Dastjerdi A K, Rabiei R, Barthelat F. The weak interfaces within tough natural composites: Experiments on three types of nacre. Journal of the Mechanical Behavior of Biomedical Materials, 2013, 19: 50-60.
    [73]
    Cox H L. The elasticity and strength of paper and other fibrous materials British Journal of Applied Physics. British Journal of Applied Physics, 1952, 3(3): 72-79.
    [74]
    He Z Z, Zhu Y B, Wu H G. Edge effect on interlayer shear in multilayer two-dimensional material assemblies. International Journal of Solids and Structures, 2020, 204: 128-137.
    [75]
    He Z Z, Zhu Y B, Wu H A. A universal mechanical framework for noncovalent interface in laminated nanocomposites. Journal of the Mechanics and Physics of Solids, 2022, 158: 104560.
    [76]
    Meng Q H, Shi X H. A microstructure-based constitutive model of anisotropic cellulose nanopaper with aligned nanofibers. Extreme Mechanics Letters, 2021, 43: 101158.
    [77]
    Mittal N, Ansari F, Gowda V K, et al. Multiscale control of nanocellulose assembly: Transferring remarkable nanoscale fibril mechanics to macroscale fibers. ACS Nano, 2018, 12(7): 6378-6388.
    [78]
    Meng Q H, Li B, Li T, et al. A multiscale crack-bridging model of cellulose nanopaper. Journal of the Mechanics and Physics of Solids, 2017, 103: 22-39.
    [79]
    Meng Q H, Li B, Li T, et al. Effects of nanofiber orientations on the fracture toughness of cellulose nanopaper. Engineering Fracture Mechanics, 2018, 194: 350-361.
    [80]
    Suksangpanya N, Yaraghi N A, Kisailus D, et al. Twisting cracks in Bouligand structures. Journal of the Mechanical Behavior of Biomedical Materials, 2017, 76: 38-57.
    [81]
    Song Z Q, Ni Y, Cai S Q. Fracture modes and hybrid toughening mechanisms in oscillated/twisted plywood structure. Acta Biomaterialia, 2019, 91: 284-293.
    [82]
    Hou Y Z, Guan Q F, Xia J, et al. Strengthening and toughening hierarchical nanocellulose via humidity-mediated interface. ACS Nano, 2021, 15(1): 1310-1320.
    [83]
    Wang S, Jiang F, Xu X, et al. Super-strong, super-stiff macrofibers with aligned, long bacterial cellulose nanofibers. Advanced Materials, 2017, 29(35): 1702498.
    [84]
    Jia C, Chen C, Kuang Y, et al. From wood to textiles: Top-down assembly of aligned cellulose nanofibers. Advanced Materials, 2018, 30(30): e1801347.
    [85]
    Gao H-L, Zhao R, Cui C, et al. Bioinspired hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers. National Science Review, 2020, 7(1): 73-83.
    [86]
    Mittal N, Benselfelt T, Ansari F, et al. Ion-specific assembly of strong, tough, and stiff biofibers. Angewandte Chemie, 2019, 58(51): 18562-18569.
    [87]
    Wang S, Li T, Chen C, et al. Transparent, anisotropic biofilm with aligned bacterial cellulose nanofibers. Advanced Functional Materials, 2018, 28(24): 1707491.
    [88]
    Ye D, Lei X, Li T, et al. Ultrahigh tough, super clear, and highly anisotropic nanofiber-structured regenerated cellulose films. ACS Nano, 2019, 13(4): 4843-4853.
    [89]
    Chen F, Xiang W, Sawada D, et al. Exploring large ductility in cellulose nanopaper combining high toughness and strength. ACS Nano, 2020, 14(9): 11150-11159.
    [90]
    Zhou Y, Chen C, Zhu S, et al. A printed, recyclable, ultra-strong, and ultra-tough graphite structural material. Materials Today, 2019, 30: 17-25.
    [91]
    Song J, Chen C, Zhu S, et al. Processing bulk natural wood into a high-performance structural material. Nature, 2018, 554(7691): 224-228.
    [92]
    Guan Q F, Yang H B, Han Z M, et al. Lightweight, tough, and sustainable cellulose nanofiber-derived bulk structural materials with low thermal expansion coefficient. Science Advances, 2020, 6(18): eaaz1114.
    [93]
    Guan Q F, Han Z-M, Yang H-B, et al. Regenerated isotropic wood. National Science Review, 2021, 8(7): 132-140.
    [94]
    Guan Q F, Yang H B, Han Z M, et al. An all-natural bioinspired structural material for plastic replacement. Nature Communications, 2020, 11(1): 5401.
    [95]
    Xiao S, Chen C, Xia Q, et al. Lightweight, strong, moldable wood via cell wall engineering as a sustainable structural material. Science, 2021, 374(6566): 465-471.
    [96]
    Yang C, Wu Q, Xie W, et al. Copper-coordinated cellulose ion conductors for solid-state batteries. Nature, 2021, 598(7882): 590-596.
    [97]
    Chen C, Song J, Cheng J, et al. Highly elastic hydrated cellulosic materials with durable compressibility and tunable conductivity. ACS nano, 2020, 14(12): 16723-16734.
    [98]
    Li T, Zhai Y, He S M, et al. A radiative cooling structural material. Science, 2019, 364(6442): 760-763.
    [99]
    Kuang Y, Chen C, He S, et al. A high-performance self-regenerating solar evaporator for continuous water desalination. Advanced Materials, 2019, 31(23): e1900498.
    [100]
    Zhu M, Song J, Li T, et al. Highly anisotropic, highly transparent wood composites. Advanced Materials, 2016, 28(26): 5181-5187.
    [101]
    Mi R, Chen C, Keplinger T, et al. Scalable aesthetic transparent wood for energy efficient buildings. Nature Communications, 2020, 11(1): 1-9.
    [102]
    Ray U, Zhu S Z, Pang Z Q, et al. Mechanics design in cellulose-enabled high-performance functional materials. Advanced Materials, 2021, 33(28): 2002504.
    [103]
    Paakko M, Ankerfors M, Kosonen H, et al. Enzymatic hydrolysis combined with mechanical shearing and high-pressure homogenization for nanoscale cellulose fibrils and strong gels. Biomacromolecules, 2007, 8(6): 1934-1941.
    [104]
    Fang Z Q, Li B, Liu Y, et al. Critical role of degree of polymerization of cellulose in super-strong nanocellulose films. Matter, 2020, 2(4): 1000-1014.
    [105]
    Henriksson M, Berglund L A, Isaksson P, et al. Cellulose nanopaper structures of high toughness. Biomacromolecules, 2008, 9(6): 1579-1585.
    [106]
    Galland S, Berthold F, Prakobna K, et al. Holocellulose nanofibers of high molar mass and small diameter for high-strength nanopaper. Biomacromolecules, 2015, 16(8): 2427-2435.
    [107]
    Ozkan M, Borghei M, Karakoc A, et al. Films based on crosslinked TEMPO-oxidized cellulose and predictive analysis via machine learning. Scientific Reports, 2018, 8(1): 1-9.
    [108]
    Ozkan M, Karakoc A, Borghei M, et al. Machine learning assisted design of Tailor-made nanocellulose films: A combination of experimental and computational studies. Polymer Composites, 2019, 40(10): 4013-4022.
    [109]
    Lamm M E, Li K, Qian J, et al. Recent advances in functional materials through cellulose nanofiber templating. Advanced Materials, 2021, 33(12) : 2005538.

    Article Metrics

    Article views (452) PDF downloads(630)
    Proportional views

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return