FOLLOWUS
a.Institute for Preservation and Conservation of Chinese Ancient Books, Fudan University Library, Fudan University, Shanghai 200433, China
b.State key laboratory of Molecular Engineering of polymers, Department of Macromolecular Science, Fudan University, Shanghai 200433, China
wangsn@fudan.edu.cn (S.N.W.)
yuliangyang@fudan.edu.cn (Y.L.Y.)
Published:1 June 2024,
Published Online:3 April 2024,
Received:16 January 2024,
Revised:17 February 2024,
Accepted:19 February 2024
Scan for full text
Jin, S. S.; Wang, S. N.; Huang, Y. Y.; Zhang, J. Y.; Liu, P.; Yu, H.; Zhang, H. D.; Yang, Y. L. Research on bast fiber extracted from the white bark of three species in the genus Broussonetia. Chinese J. Polym. Sci. 2024, 42, 729–738
Shan-Shan Jin, Si-Nong Wang, Yan-Yan Huang, et al. Research on Bast Fiber Extracted from the White Bark of Three Species in the Genus
Jin, S. S.; Wang, S. N.; Huang, Y. Y.; Zhang, J. Y.; Liu, P.; Yu, H.; Zhang, H. D.; Yang, Y. L. Research on bast fiber extracted from the white bark of three species in the genus Broussonetia. Chinese J. Polym. Sci. 2024, 42, 729–738 DOI: 10.1007/s10118-024-3102-z.
Shan-Shan Jin, Si-Nong Wang, Yan-Yan Huang, et al. Research on Bast Fiber Extracted from the White Bark of Three Species in the Genus
Polymer-feature properties were focused to explain the characteristics of three
Broussonetia
species for the pulping processing
while the fiber rigidity method based on the Kratky-Porod chain model was improved and further reveals the influencing factors of fiber rigidity.
Against the backdrop of a global paper resource shortage
there is a growing need to identify fast-growing tree species capable of producing long-lasting paper. Three plant species namely
Broussonetia kazinoki
Broussonetia papyrifera
and hybrid paper mulberry
belong to the
Broussonetia
genus
were collected from China to study their white bark suitability for pulp and papermaking. Their chemical composition revealed that the holocellulose content in
Broussonetia kazinoki
and
Broussonetia papyrifera
was more than 80%. The molecular weight distribution of several holocellulose/
α
-cellulose is observed by GPC
which allows us to better observe the changes of various components on the molecular weight. The yield
lignin
whiteness
and molecular weight of the pulps obtained by NaOH treatment were determined. Optical microscope was used to characterize the fiber length-width ratio and rigidity. Finally
the improvement of the fiber rigidity method based on the Kratky-Porod chain model makes it more theoretical and further reveals the influencing factors of fiber rigidity. This study demonstrates the high potentiality of these three species for papermaking applications.
Broussonetia genusCelluloseAlkaline pulpingKratky-Porod chain modelFiber rigidity
Buchanan, S. A. The brittle book problem: approaches by research libraries in the United States.The Paper Conservator1987,11, 69−72..
Wouters, J. Chemistry: coming soon to a library near you.Science2008,322, 1196−1198..
Tsien, T. H. Raw materials for old papermaking in China.J. Am. Oriental. Soc.1973,93, 510−519..
Zou, X.; Uesaka, T.; Gurnagul, N. Prediction of paper permanence by accelerated aging I. Kinetic analysis of the aging process.Cellulose1996,3, 243−267..
Danielewicz, D.; Surma-Ślusarska, B. Properties and fibre characterisation of bleached hemp, birch and pine pulps: a comparison.Cellulose2017,24, 5173−5186..
Chen, Y.; Wang, L.; Liu, X.; Wang, F.; An, Y.; Zhao, W.; Tian, J.; Kong, D.; Zhang, W.; Xu, Y.; Ba, Y.; Zhou, H. The genusBroussonetia: an updated review of phytochemistry, pharmacology and applications.Molecules2022,27, 5344−5380..
Wang, F.; Su, Y.; Chen, N.; Shen, S. Genome-wide analysis of the UGT gene family and identification of flavonoids inBroussonetia papyrifera. Molecules 2021 ,26, 3449-3465..
Lee, Y.; Kwon, J.; Jeong, J. H.; Ryu, J. H.; Kim, K. I. Kazinol C fromBroussonetia kazinokistimulates autophagyviaendoplasmic reticulum stress-mediated signaling.Anim. Cells Syst.2022,26, 28−36..
Chung, K. F.; Kuo, W. H.; Hsu, Y. H.; Li, Y. H.; Rubite, R. R.; Xu, W. B. Molecular recircumscription ofBroussonetia(Moraceae) and the identity and taxonomic status of B. kaempferi var. australis.Bot. Stud.2017,58, 11−23..
Wang, G. W.; Huang, B. K.; Qin, L. P. The genusBroussonetia: a review of its phytochemistry and pharmacology.Phytotherapy Res.2012,26, 1−10..
Jeong, M. J.; Bogolitsyna, A.; Jo, B. M.; Kang, K. Y.; Rosenau, T.; Potthast, A., Deterioration of ancient Korean paper (Hanji), treated with beeswax: a mechanistic study.Carbohyd. Polym. 2014 ,101, 1249-1254..
Jeong, M. J.; Kang, K. Y.; Bacher, M.; Kim, H. J.; Jo, B. M.; Potthast, A. Deterioration of ancient cellulose paper, Hanji: evaluation of paper permanence.Cellulose2014,21, 4621−4632..
Lin, J.; Zou, J.; Zhang, B.; Que, Q.; Zhang, J.; Chen, X.; Zhou, W. An efficientin vitropropagation protocol for direct organogenesis from root explants of a multi-purpose plant, Broussonetia papyrifera (L.) L’Hér. ex Vent.Ind. Crop. Prod.2021,170, 113686−113695..
Whistler, W. A. Broussonetia papyrifera (paper mulberry).Traditional Tree Initiative.2006,9, 1−3..
Zhang, T. H.; Cheng, L.; Guo, M.; Zhang, Y. M. Studies on the microstructures and properties ofBroussonetia Papyriferafiber.Appl. Mech. Mater.2013,481, 86−91..
Li, F.; Li, Y. P.; Zen, Y.; Ma, Y. T.; Zhai, X. X. Fiber morphology and chemical component of Juvenile Wood in threeBroussonetia papyriferaclones.J. Henan Agricultural Sci.2011,40, 120−122..
Zhang, W. A. N.; Yang, G.; Zhao, Y.; Xu, Z.; Huimin, H.; Zhou, J. The chloroplast genome comparative characteristic of artificial breeding tree, a case aboutBroussonetia kazinoki×Broussonetia papyrifera.Biocell.2022,46, 803−819..
Peng, X.; Teng, L.; Wang, X.; Wang, Y.; Shen, S.De Novoassembly of expressed transcripts and global transcriptomic analysis from seedlings of the paper mulberry (Broussonetia kazinoki×Broussonetia papyifera).PLoS One2014,9, 1−13..
Wang, F.; Chen, N.; Shen, S. iTRAQ-based quantitative proteomics analysis reveals the mechanism of golden-yellow leaf mutant in hybrid paper mulberry.Int. J. Mol. Sci.2021,23, 127−145..
Pi, Z.; Zhao, M. L.; Peng, X. J.; Shen, S. H. Phosphoproteomic analysis of paper mulberry reveals phosphorylation functions in chilling tolerance.J. Proteome Res.2017,16, 1944−1961..
Yan, D.; Li, K. Measurement of wet fiber flexibility by confocal laser scanning microscopy.J. Mater. Sci.2008,43, 2869−2878..
Pettersson, T.; Hellwig, J.; Gustafsson, P. J.; Stenström, S. Measurement of the flexibility of wet cellulose fibres using atomic force microscopy.Cellulose2017,24, 4139−4149..
Jin, C.; Yu, H.; Wu, C. F.; Zhao, H. B.; Jin, S. S.; Yang, Y. L.; Zhang, H. D. Fiber bending flexibility evaluation by worm-like chain model.Chinese J. Polym. Sci.2022,40, 526−531..
Hiromi, Y.; Takenao, Y. inHelical Wormlike Chains in Polymer Solutions. Springer, Berlin/Heidelberg, New York, 2016 , Vol. 2E, p21..
Kim, S.; Seo, A. Y.; Lee, T. G. Functionalized cellulose to remove surfactants from cosmetic products in wastewater.Carbohyd. Polym.2020,236, 116010−116017..
Kes, M.; Christensen, B. E. A re-investigation of the Mark-Houwink-Sakurada parameters for cellulose in Cuen: a study based on size-exclusion chromatography combined with multi-angle light scattering and viscometry.J. Chromatogr. A2013,1281, 32−37..
Łojewska, J.; Lubańska, A.; Mikowiec. P.; Iśkowiec. P.; Proniewicz, L. M. FTIRin situtransmission studies on the kinetics of paper degradationviahydrolytic and oxidative reaction paths.Appl. Phys. A2006,83, 597−603..
Marques, G.; Rencoret, J.; Gutiérrez, A.; Río, J. C. Evaluation of the chemical composition of different non-woody plant fibers used for pulp and paper manufacturing.The Open Agriculture J.2010,4, 93−101..
Jiménez, L.; Sanchez, I.; Lopez, F. Characterization of Spanish agricultural residues with a view to obtaining cellulose pulp.Tappi J.1990,73, 173−176..
Ashori, A.; Harun, J.; Raverty, D. W.; Yusoff, M. N. M. Chemical and morphological characteristics of Malaysian Cultivated Kenaf (Hibiscus cannabinus) fiber.Polym. Plast. Technol. Eng.2006,45, 131−134..
Miranda, I.; Lima, L.; Quilhó, T.; Knapic, S.; Pereira, H. The bark of Eucalyptus sideroxylon as a source of phenolic extracts with anti-oxidant properties.Ind. Crop. Prod.2016,82, 81−87..
Schult, T.; Hjerde, T.; Odd Inge Optun ; Kleppe, P. J.; Moe, S. Characterization of cellulose by SEC-MALLS.Cellulose2002,9, 149−158..
Ono, Y.; Funahashi, R.; Saito, T.; Isogai, A. Investigation of stability of branched structures in softwood cellulose using SEC/MALLS/RI/UV and sugar composition analyses.Cellulose2018,25, 2667−2679..
Yanagisawa, M.; Isogai, A. Size exclusion chromatographic and UV-Vis absorption analyses of unbleached and bleached softwood kraft pulps using LiCl/1,3-dimethyl-2-imidazolidinone as a solvent.Holzforschung2007,61, 236−241..
Ono, Y.; Isogai, A. Analysis of celluloses, plant holocelluloses, and wood pulps by size-exclusion chromatography/multi-angle laser-light scattering.Carbohyd. Polym.2021,251, 117045−117059..
Ono, Y.; Nakamura, Y.; Zhou, Y.; Horikawa, Y.; Isogai, A. Linear and branched structures present in high-molar-mass fractions in holocelluloses prepared from chara, haircap moss, adiantum, ginkgo, Japanese cedar, and eucalyptus.Cellulose2021,28, 3935−3949..
Nomura, S.; Kugo, Y.; Erata, T.13C NMR and XRD studies on the enhancement of cellulose II crystallinity with low concentration NaOH post-treatments.Cellulose2020,27, 3553−3563..
Okano, T.; Sarko, A. Mercerization of Cellulose. I. X-ray diffraction evidence for intermediate structures.J. Appl. Polym. Sci.1984,29, 4175−4182..
Okano T.; Sarko, A. Mercerization of cellulose 2. Alkali-cellulose intermediates and a possible mercerization mechanism.J. Appl. Polym. Sci.1985,30, 325−332..
Mwaikambo, L. Y.; Ansell, M. P. Chemical modification of hemp, sisal, jute, and kapok fibers by alkalization.J. Appl. Polym. Sci.2002,84, 2222−2234..
Zhan, H.; Xie, D.; Li, M.B.; Li, J.; Yu, L.; Wang, C.; Wang, S. Fiber properties and chemical compositions of sheaths from three selected sympodial bamboo species as raw materials for papermaking in Yunnan of China.Eur. J. Wood. Wood. Prod.2022,81, 815−818..
Lavoine, N.; Desloges, I.; Dufresne, A.; Bras, J. Microfibrillated cellulose – Its barrier properties and applications in cellulosic materials: a review.Carbohyd. Polym.2012,90, 735−764..
Yuan, L.; Wan, J.; Ma, Y.; Wang, Y.; Huang, M.; Chen, Y. The content of different hydrogen bond models and crystal structure ofEucalyptusfibers during beating.Bioresources2013,8, 717−737..
0
Views
13
Downloads
0
CSCD
Publicity Resources
Related Articles
Related Author
Related Institution