Pulp and Paper Making Characteristics of Fibers from Plantation-grown Oxythenantera Abyssinica and Beema Bamboo (A Tissue Cultured Clone from Bambusa Balcooa)

References

• Abdulrahaman, A. A., B. O. Saka, S. O. Kolawole, C. O. Ogunkunle, and F. A. Oladele. 2013. Effects of wood fibers of Ficus exasperate on pvc, sugar level live weight of albino rats and lab – Baked breads. EJBS 7 (1):1–9.
   Google Scholar
• Aderounmu, A. F., and E. A. Adelusi. 2019. Axial and radial variation of fibre characteristics of Bambusa vulgaris. Journal of Scientific Research & Reports 24 (4):1–8.
   Google Scholar
• Agnihotri, S., D. Dutt, and C. H. Tyagi. 2010. Complete characterization of bagasse of early species of saccharum officinerum – CO 89003 for pulp and papermaking. Bioresources 5 (2):1197–214.
   Web of Science ®Google Scholar
• Ates, S., Y. Ni, M. Akgul, and A. Tozluoglu. 2008. Characterization and evaluation of Paulownia elongata as a raw material for paper production. African Journal of Biotechnology 7 (22):4153–58.
   Google Scholar
• Bajpai, P. 2014. Recycling and deinking of recovered paper. Accessed October 18, 2019. https://sciencedirect.com/topics/earth-and-planetary-sciences/pulp-and-paper-industry.
   Google Scholar
• Barathi, N. 2018. Propagation, commercial plantation and industrial utilization of bamboo. Accessed October 8, 2019. http://worldbamboo.net/wbw_india2019/Barathi%20N%20%20Propagation.
   Google Scholar
• Bhardwaj, K. N. 2019. Refining of bamboo long fiber fraction pulp: Effects on wet web and dry strength properties of paper. Cellulose Chemistry and Technology 53 (1–2):113–20. doi:10.35812/CelluloseChemTechnol.2019.53.13.
   Web of Science ®Google Scholar
• Chang, F. J., E. I. C. Wang, Y. S. Perng, and C. C. Chen. 2013. Effect of bamboo age on the pulping properties of Bambusa stenostachya Hackle. Cellulose Chemistry and Technology 47 (3–4):285–93.
   Web of Science ®Google Scholar
• Chen, Z., H. Zhang, Z. He, L. Zhang, and X. Yue. 2019. Bamboo for pulp & paper. BioResources 14 (1):3–5. doi:10.15376/biores.14.1.3-5.
   Google Scholar
• Crevel, V. R. 2016. Challenges and opportunities to utilize biomass residues from agriculture and forestry as a feedstock for bio-based food packaging. Accessed October 7, 2019. http://fao.org/forestry/45849-023667e93ce5f79f4df3c74688c2067cc.pdf.
   Google Scholar
• Dasappa, S., and N. Bharti. 2016. Well to wheel – A case study of usage of Beema bamboo as a sustainable energy source. 24th European Biomass Conference and Exhibition, Amsterdam, the Netherlands, June 6–9.
   Google Scholar
• David-Sarogoro, N., and E. A. Emerhi. 2016. Runkel, flexibility and slenderness ratios of Anthocleista djalonensis (A) wood for pulp and paper production. African Journal of Agriculture, Technology and Environment 5 (2):27–32.
   Google Scholar
• Dutt, D., and C. H. Tyagi. 2011. Comparison of various eucalyptus species for their morphological, chemical, pulp and papermaking charcteristics. Indian Journal of Chemical Technology 18:148–51.
   Google Scholar
• Egbewole, Z. T., O. J. Rotowa, and P. O. Omoake. 2015. Evaluation of fibre quality of Bambusa vulgaris (bamboo) as a raw material for pulp and paper production. Production Agriculture and Technology Journal 11 (2):188–02.
   Google Scholar
• Ekhuemelo, D. O., S. A. Oluwalana, and A. C. Adetogun. 2012. Potentials of agricultural waste and grass in pulp and paper making. Journal of Research in Forestry, Wildlife and Environment 4 (2):1–15.
   Google Scholar
• Enayati, A. A., Y. Hamzeh, S. A. Mirshokraiei, and M. Molaii. 2009. Papermaking potential of canola stalks. Bioresources 4 (1):245–56.
   Web of Science ®Google Scholar
• Environmental Paper Network. 2018. The state of the paper industry 2018. Accessed October 7, 2019. https://environmentalpaper.org/wpcontent/uploads/2018/04/StateOfTheGlobalPaperIndustry2018_FullReport-Final-1.pdf.
   Google Scholar
• Fagbemigun, T. K., O. D. Fagbemi, F. Buhari, E. Mgbachiuzo, and C. C. Igwe. 2016. Fibre characteristics and strength properties of Nigerian pineapple leaf, Banana peduncle and banana leaf – Potential green resources for pulp and paper production. Journal of Scientific Research and Reports 12 (2):1–13. doi:10.9734/JSRR/2016/29248.
   Google Scholar
• Inada, T., and J. B. Hall. 2008. Oxytenanthera abyssinica (A.Rich.) Munro. In PROTA (Plant Resources of Tropical Africa/Ressources végétales de l’Afrique tropicale), ed. D. Louppe, A. A. Oteng-Amoako, and M. Brink. Wageningen: PROTA. Accessed November 11, 2019. https://uses.plantnet-project.org/en/Oxytenanthera_abyssinica_(PROTA)
   Google Scholar
• Ivanković, A., K. Zeljko, S. Talić, A. M. Bevanda, and M. Lasić. 2017. Biodegradable packaging in the food industry. Accessed May 19, 2019. https://researchgate.net.
   Google Scholar
• Johansson, A. 2011. Correlations between fibre properties and paper properties. MSc Dissertation, KTH, School of Chemical Science and Engineering (CHE).
   Google Scholar
• Kiaei, M., M. Tajik, and R. Vaysi. 2014. Chemical and biometrical properties of plum wood and its application in pulp and paper production. Maderas, Cienc. tecnol 16 (3):313–22.
   Google Scholar
• Lewis, D., and A. C. Miles. 2007. Farming bamboo. Accessed March 10, 2019. https://Lulu.com.
   Google Scholar
• Liu, Z., H. Wang, and L. Hui. 2018. Pulping and papermaking of non-wood fibres. Accessed June 5, 2020. https://intechopen.com.doi:10.5772/intechopen.79017.
   Google Scholar
• Mahatme, S. S., N. G. Kanse, and A. K. Bandsode. 2018. Pulp and paper production from pineapple leaves as a substitute to wood source: A review. International Journal of Creative Research Thoughts 6 (2):20–26.
   Google Scholar
• Munro, R. A. 2017. Oxythenanthera abyssinica (prota). Accessed December 20, 2018. https://planetproject.org.
   Google Scholar
• Musau, Z. 2016. Bamboo: Africa’s untapped potential. Africa Renewal 30 (1):22–25. doi:10.18356/d3c16c7c-en.
   Google Scholar
• Nasser, R. A., S. Hiziroglu, M. A. Abdel-Aal, H. A. Al-Mefarrej, N. D. Shetta, and I. M. Aref. 2015. Measurement of some properties of pulp and paper made from date palm midribs and wheat straw by soda-AQ pulping process. Measurement 62:179–86. Assessed May 20, 2019.
   Google Scholar
• Noah, A. S., M. B. Ogunleye, J. K. Abiola, and F. N. Nnate. 2015. Fiber characteristics of Gerdenia ternifolia (Linn C.) schumach for its pulping potential. American Scientific Research Journal of Engineering, Technology and Sciences 14 (2):322–32.
   Google Scholar
• Ofosu, S., K. B. Boadu, and K. A. Afrifah. 2020. Suitability of Chrysophyllum albidum from moist semi-deciduous forest in Ghana as a raw material for manufacturing paper-based products. Journal of Sustainable Forestry 39 (2):153–66. doi:10.1080/10549811.2019.1623052.
   Web of Science ®Google Scholar
• Ogunjobi, K. M., A. C. Adetogun, and S. A. Shofidiya. 2014. Investigation of pulping potentials of waste from conversion of Anogeissus leiocarpus. IOSR Journal of Polymer and Textile Engineering 1 (2):26–20. doi:10.9790/019X-0122630.
   Google Scholar
• Ogunleye, M. B., J. A. Fuwape, A. O. Oluyege, B. Ajayi, and J. S. Fabiyi. 2017. Evaluation of fiber characteristics of Ricinodedron heudelotti for pulp and papermaking. International Journal of Science and Technology 6 (1):634–41.
   Google Scholar
• Olotuah, O. F. 2006. Suitability of some local bast fibre plants in pulp and paper making. Journal of Biological Sciences 6 (3):635–37. doi:10.3923/jbs.2006.635.637.
   Google Scholar
• Oluwadare, A. O., and O. A. Sotannde. 2007. The relationship between fibre characteristics and pulp-sheet properties of Leucaena leucocephala (Lam.) De wit. Middle-East Journal of Scientific Research 2 (2):63–68.
   Google Scholar
• Omobowale, M. O., and K. Ogedengbe. 2008. Trends in fiber characteristics of Nigerian grown bamboo and its effect on its impact and tensile strengths - bamboo science and culture. The Journal of the American Bamboo Society 21 (1):9–13.
   Google Scholar
• Panda, H. 2011. Bamboo plantation and utilization handbook. New Delhi: Asia Pacific Business Press Inc.
   Google Scholar
• Randy, V. 2018. Beema bamboo; health enhancer and clean energy producer. Assessed October 8, 2019. https://Pressreader.com/Philippines/agriculture-9ggr/20180601/282535839056496.
   Google Scholar
• Riki, J. T. B., O. A. Sotannde, and A. O. Oluwadare. 2019. Anatomical and chemical properties of wood and their practical implications in pulp and paper production: A review. Journal of Research in Forestry, Wildlife and Environment 10 (3):358–68.
   Google Scholar
• Rusch, F., G. B. Ceolin, and E. Hillig. 2019. Morphology, density and dimensions of bamboo fibers: A bibliographical compilation. Accessed September 15, 2020. http://scielo.br.
   Google Scholar
• Sadiku, N. A., A. O. Oluyege, and B. Ajayi. 2016. Fibre dimension and chemical characterisation of naturally grown Bambusa vulgaris for pulp and paper production. Journal of Bamboo and Rattan 15 (1–4):33–43.
   Google Scholar
• San, H. P., L. K. Long, C. Z. Zhang, T. C. Hui, W. Y. Seng, F. S. Lin, A. T. Hun, and W. K. Fong. 2016. Anatomical features, fiber morphological, physical and mechanical properties of three years old new hybrid Paulownia: Green Paulownia. Research Journal of Forestry 10 (1):30–35. doi:10.3923/rjf.2016.30.35.
   Google Scholar
• Sekyere, D. 1994. Potential of bamboo (bambusa vulgaris) as a source of raw material for pulp and paper in Ghana. Ghana Journal of Forestry 1:49–56.
   Google Scholar
• Sharma, M., C. L. Sharma, and D. D. Lama. 2015. Anatomical and fibre characteristics of some agro waste materials for pulp and paper making. International Journal of Agricultural Science and Research 5 (6):155–62.
   Google Scholar
• Sharma, P. K., S. K. Nath, and N. Murthy. 2014. Investigation on fibre characteristics of Dendrocalmus strictus and Bambusa bambos. International Journal of Engineering Innovation & Research 3 (3):254–58.
   Google Scholar
• Sugesty, S., T. Kardiansyah, and H. Hardiani. 2015. Bamboo as raw materials for dissolving pulp with environmental friendly technology for rayon fiber. Procedia Chemistry 17:194–99. doi:10.1016/j.proche.2015.12.122.
   Google Scholar
• Syed, N. F. N., M. H. Zakaria, and J. S. Bujang. 2016. Fibre characteristics and papermaking of seagrass using Hand-beaten and blended pulp. Bioresources 11 (2):5358–80. doi:10.15376/biores.11.2.5358-5380.
   Web of Science ®Google Scholar
• Tripathi, K. S., P. O. M. Mishra, K. N. Bhardwaj, and R. Varadhan. 2018. Pulp and papermaking properties of bamboo species Melocanna baccifera. Cellulose Chemistry and Technology 52 (1–2):81–88.
   Web of Science ®Google Scholar
• Tutuş, A., Y. Kazaskeroğlu, and M. Çiçekler. 2015. Evaluation of tea wastes in usage pulp and paper production. BioResources 10 (3):5407–16. doi:10.15376/biores.10.3.5407-5416.
   Web of Science ®Google Scholar
• Vijayan, S., and C. M. Joy. 2018. Properties of natural fibers separated from Chromolaena odorata and Mikania micrantha. Journal of Natural Fibers 15 (3):396–405. doi:10.1080/15440478.2017.1330720.
   Web of Science ®Google Scholar
• Wahab, R., A. Mohamed, A. Hassan, I. Khalid, M. T. Mustapa, and O. Sulaiman. 2010. Anatomical and physical properties of cultivated two and four-year-old Bambusa Vulgaris. Sains Malaysiana 39 (4):571–79.
   Web of Science ®Google Scholar
• Wang, G., and F. Chen. 2017. Development of bamboo fiber-based composites. In Advanced high strength natural fibre composites in construction, ed. M. Fan and F. Fu, 235–55. Amsterdam, The Netherlands: Elsevier B.V.
   Google Scholar
• Zakikhani, P., R. Zahari, M. T. B. H. H. Sultan, and D. L. A. A. Majid. 2017. Morphological, mechanical, and physical properties of four bamboo species. BioResources 12 (2):2479–95. doi:10.15376/biores.12.2.2479-2495.
   Web of Science ®Google Scholar